NetEngine 8000 F1A Hardware Guide (V800R012C10 to V800R023C00) (pdf)
HUAWEI NetEngine 8000 F1A Series
V800R012C10 to V800R023C00
Hardware Guide
Issue 04
Date 2025-04-30
HUAWEI TECHNOLOGIES CO., LTD.
Copyright © Huawei Technologies Co., Ltd. 2025. All rights reserved.
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Huawei Technologies Co., Ltd.
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Hardware Guide Contents
Contents
1 Document Declaration........................................................................................................... 1
2 Using the Hardware Tool.......................................................................................................4
3 Hardware Description.............................................................................................................5
3.1 Chassis......................................................................................................................................................................................... 5
3.1.1 NetEngine 8000 F1A-8H20Q........................................................................................................................................... 5
3.2 Power........................................................................................................................................................................................ 53
3.2.1 NetEngine 8000 F1A-8H20Q Power Module........................................................................................................... 53
3.2.1.1 PAC1K2S12-DB (1200W AC Power Module(Back to Front, Power panel side exhaust))..................... 53
3.2.1.2 PAC1K2S12-DF (1200W AC Power Module(Front to Back,Power panel side intake)).......................... 55
3.2.1.3 PAC600S12-CB (600W AC Power Module(Back to Front, Power panel side exhaust))........................ 58
3.2.1.4 PAC600S12-CF (600W AC Power Module(Front to Back,Power panel side intake))............................. 60
3.2.1.5 PAC600S12-EB (600W AC Power Module(Back to Front, Power panel side exhaust)).........................63
3.2.1.6 PAC600S12-EF (600W AC Power Module(Front to Back,Power panel side intake))..............................65
3.2.1.7 PDC1000S12-CB (1000W DC Power Module(Back to Front,Power panel side exhaust)).................... 67
3.2.1.8 PDC1000S12-CF (1000W DC Power Module(Front to Back,Power panel side intake))........................70
3.3 Fan............................................................................................................................................................................................. 72
3.3.1 NetEngine 8000 F1A-8H20Q Fan Module................................................................................................................ 72
3.3.1.1 FAN-031A-B (Fan box(B,FAN panel side exhaust))........................................................................................... 72
3.3.1.2 FAN-031A-F (Fan Box(F,FAN panel side intake )).............................................................................................. 74
3.4 Optical Module...................................................................................................................................................................... 76
3.4.1 Understanding Pluggable Optical Modules............................................................................................................. 76
3.4.1.1 Appearance and Structure.......................................................................................................................................... 77
3.4.1.2 Types of Optical Modules............................................................................................................................................77
3.4.1.3 Instruction.........................................................................................................................................................................79
3.4.1.4 Instructions on How to Use an Optical Module..................................................................................................84
3.4.1.5 Configuring an Optical Attenuator.......................................................................................................................... 95
3.4.2 155Mbps eSFP Optical Module.................................................................................................................................... 96
3.4.2.1 155Mbps-eSFP-SMF-1550nm-80km-commercial............................................................................................... 96
3.4.2.2 155Mbps-eSFP-SMF-1310nm-15km-industry...................................................................................................... 98
3.4.2.3 155Mbps-eSFP-SMF-1310nm-40km-industry...................................................................................................... 99
3.4.2.4 155Mbps-eSFP-SMF-1550nm-80km-industry....................................................................................................100
3.4.2.5 155Mbps-eSFP-SMF-1310nm-40km-commercial.............................................................................................101
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3.4.2.6 155Mbps-eSFP-MMF-1310nm-2km-commercial............................................................................................. 103
3.4.2.7 155Mbps-eSFP-SMF-1310nm-15km-commercial.............................................................................................104
3.4.3 155Mbps eSFP BIDI Optical Module........................................................................................................................ 105
3.4.3.1 155Mbps-eSFP-SM-1310nm(Tx)/1550nm(Rx)-15km-commercial.............................................................105
3.4.3.2 155Mbps-eSFP-SM-1550nm(Tx)/1310nm(Rx)-15km-commercial.............................................................107
3.4.4 1Gbps Electrical Module............................................................................................................................................... 108
3.4.4.1 1Gbps-SFP-100m-industry (02310RAV).............................................................................................................. 108
3.4.4.2 1Gbps-SFP-100m-industry (02310VPT)............................................................................................................... 109
3.4.4.3 1Gbps-SFP-100m-industry (02314FNP)...............................................................................................................109
3.4.5 1.25Gbps eSFP Optical Module.................................................................................................................................. 110
3.4.5.1 1.25Gbps-eSFP-MMF-850nm-500m-extended.................................................................................................. 110
3.4.5.2 1.25Gbps-eSFP-SMF-1310nm-10km-industry....................................................................................................111
3.4.5.3 1.25Gbps-eSFP-SMF-1310nm-40km-industry....................................................................................................113
3.4.5.4 1.25Gbps-eSFP-MMF-850nm-500m-industry.................................................................................................... 114
3.4.5.5 1.25Gbps-eSFP-SMF-1550nm-80km-commercial.............................................................................................115
3.4.5.6 1.25Gbps-eSFP-SMF-1310nm-10km-commercial.............................................................................................116
3.4.5.7 1.25Gbps-eSFP-SMF-1310nm-40km-commercial.............................................................................................118
3.4.5.8 1.25Gbps-eSFP-SMF-1550nm-100km-commercial.......................................................................................... 119
3.4.6 1.25Gbps eSFP BIDI Optical Module........................................................................................................................ 120
3.4.6.1 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-10km-commercial(34060470)....................................120
3.4.6.2 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-10km-commercial...........................................................122
3.4.6.3 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-40km-commercial...........................................................123
3.4.6.4 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-40km-commercial...........................................................124
3.4.6.5 1.25Gbps-eSFP-SMF-1570nm(Tx)/1490nm(Rx)-80km-commercial...........................................................126
3.4.6.6 1.25Gbps-eSFP-SMF-1490nm(Tx)/1570nm(Rx)-80km-commercial...........................................................127
3.4.6.7 0.1~1.25Gbps-eSFP-SMF-1310nm(Tx)/1550nm(Rx)-40km-commercial.................................................. 128
3.4.6.8 0.1~1.25Gbps-eSFP-SMF-1550nm(Tx)/1310nm(Rx)-40km-commercial.................................................. 130
3.4.6.9 1.25Gbps-eSFP-SMF-1550nm(Tx)/1490nm(Rx)-80km-commercial...........................................................131
3.4.6.10 1.25Gbps-eSFP-SMF-1490nm(Tx)/1550nm(Rx)-80km-commercial........................................................ 133
3.4.7 1.25Gbps eSFP CWDM Optical Module.................................................................................................................. 134
3.4.7.1 1.25Gbps-eSFP-SMF-1571nm-80km-commercial.............................................................................................134
3.4.7.2 1.25Gbps-eSFP-SMF-1591nm-80km-commercial.............................................................................................135
3.4.7.3 1.25Gbps-eSFP-SMF-1551nm-80km-commercial.............................................................................................137
3.4.7.4 1.25Gbps-eSFP-SMF-1511nm-80km-commercial.............................................................................................138
3.4.7.5 1.25Gbps-eSFP-SMF-1611nm-80km-commercial.............................................................................................139
3.4.7.6 1.25Gbps-eSFP-SMF-1491nm-80km-commercial.............................................................................................140
3.4.7.7 1.25Gbps-eSFP-SMF-1531nm-80km-commercial.............................................................................................142
3.4.7.8 1.25Gbps-eSFP-SMF-1471nm-80km-commercial.............................................................................................143
3.4.8 125M~2.67Gbps eSFP DWDM Optical Module.................................................................................................... 144
3.4.8.1 125M~2.67Gbps-eSFP-SMF-1560.61nm-120km-commercial...................................................................... 144
3.4.8.2 125M~2.67Gbps-eSFP-SMF-1559.79nm-120km-commercial...................................................................... 145
3.4.8.3 125M~2.67Gbps-eSFP-SMF-1558.98nm-120km-commercial...................................................................... 147
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3.4.8.4 125M~2.67Gbps-eSFP-SMF-1558.17nm-120km-commercial...................................................................... 148
3.4.8.5 125M~2.67Gbps-eSFP-SMF-1557.36nm-120km-commercial...................................................................... 149
3.4.8.6 125M~2.67Gbps-eSFP-SMF-1556.55nm-120km-commercial...................................................................... 151
3.4.8.7 125M~2.67Gbps-eSFP-SMF-1555.75nm-120km-commercial...................................................................... 152
3.4.8.8 125M~2.67Gbps-eSFP-SMF-1554.94nm-120km-commercial...................................................................... 153
3.4.8.9 125M~2.67Gbps-eSFP-SMF-1554.13nm-120km-commercial...................................................................... 154
3.4.8.10 125M~2.67Gbps-eSFP-SMF-1553.33nm-120km-commercial.................................................................... 156
3.4.8.11 125M~2.67Gbps-eSFP-SMF-1552.52nm-120km-commercial.................................................................... 157
3.4.8.12 125M~2.67Gbps-eSFP-SMF-1551.72nm-120km-commercial.................................................................... 158
3.4.8.13 125M~2.67Gbps-eSFP-SMF-1550.92nm-120km-commercial.................................................................... 159
3.4.8.14 125M~2.67Gbps-eSFP-SMF-1550.12nm-120km-commercial.................................................................... 161
3.4.8.15 125M~2.67Gbps-eSFP-SMF-1549.32nm-120km-commercial.................................................................... 162
3.4.8.16 125M~2.67Gbps-eSFP-SMF-1548.51nm-120km-commercial.................................................................... 163
3.4.8.17 125M~2.67Gbps-eSFP-SMF-1547.72nm-120km-commercial.................................................................... 164
3.4.8.18 125M~2.67Gbps-eSFP-SMF-1546.92nm-120km-commercial.................................................................... 166
3.4.8.19 125M~2.67Gbps-eSFP-SMF-1546.12nm-120km-commercial.................................................................... 167
3.4.8.20 125M~2.67Gbps-eSFP-SMF-1545.32nm-120km-commercial.................................................................... 168
3.4.8.21 125M~2.67Gbps-eSFP-SMF-1544.53nm-120km-commercial.................................................................... 169
3.4.8.22 125M~2.67Gbps-eSFP-SMF-1543.73nm-120km-commercial.................................................................... 171
3.4.8.23 125M~2.67Gbps-eSFP-SMF-1542.94nm-120km-commercial.................................................................... 172
3.4.8.24 125M~2.67Gbps-eSFP-SMF-1542.14nm-120km-commercial.................................................................... 173
3.4.8.25 125M~2.67Gbps-eSFP-SMF-1541.35nm-120km-commercial.................................................................... 174
3.4.8.26 125M~2.67Gbps-eSFP-SMF-1540.56nm-120km-commercial.................................................................... 176
3.4.8.27 125M~2.67Gbps-eSFP-SMF-1539.77nm-120km-commercial.................................................................... 177
3.4.8.28 125M~2.67Gbps-eSFP-SMF-1538.98nm-120km-commercial.................................................................... 178
3.4.8.29 125M~2.67Gbps-eSFP-SMF-1538.19nm-120km-commercial.................................................................... 179
3.4.8.30 125M~2.67Gbps-eSFP-SMF-1537.40nm-120km-commercial.................................................................... 181
3.4.8.31 125M~2.67Gbps-eSFP-SMF-1536.61nm-120km-commercial.................................................................... 182
3.4.8.32 125M~2.67Gbps-eSFP-SMF-1535.82nm-120km-commercial.................................................................... 183
3.4.8.33 125M~2.67Gbps-eSFP-SMF-1535.04nm-120km-commercial.................................................................... 184
3.4.8.34 125M~2.67Gbps-eSFP-SMF-1534.25nm-120km-commercial.................................................................... 186
3.4.8.35 125M~2.67Gbps-eSFP-SMF-1533.47nm-120km-commercial.................................................................... 187
3.4.8.36 125M~2.67Gbps-eSFP-SMF-1532.68nm-120km-commercial.................................................................... 188
3.4.8.37 125M~2.67Gbps-eSFP-SMF-1531.90nm-120km-commercial.................................................................... 189
3.4.8.38 125M~2.67Gbps-eSFP-SMF-1531.12nm-120km-commercial.................................................................... 191
3.4.8.39 125M~2.67Gbps-eSFP-SMF-1530.33nm-120km-commercial.................................................................... 192
3.4.8.40 125M~2.67Gbps-eSFP-SMF-1529.55nm-120km-commercial.................................................................... 193
3.4.9 10Gbps SFP+ Optical Module..................................................................................................................................... 194
3.4.9.1 10Gbps-SFP+-SMF-1550nm-80km-commercial................................................................................................194
3.4.9.2 10Gbps-SFP+-SMF-1310nm-10km-industry.......................................................................................................196
3.4.9.3 10Gbps-SFP+-SMF-1550nm-40km-industry.......................................................................................................197
3.4.9.4 10Gbps-SFP+-MMF-850nm-0.3km-commercial............................................................................................... 198
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3.4.9.5 10Gbps-SFP+-SMF-1310nm-10km-commercial................................................................................................200
3.4.9.6 10Gbps-SFP+-SMF-1550nm-40km-commercial................................................................................................201
3.4.10 1.25/9.953/10.3125Gbps SFP+ Optical Module..................................................................................................202
3.4.10.1 1.25/9.953/10.3125Gbps-SFP+-SMF-1310nm-10km-commercial............................................................ 203
3.4.10.2 1.25/9.953/10.3125Gbps-SFP+-SMF-1550nm-40km-commercial............................................................ 204
3.4.11 10Gbps SFP+ CWDM Optical Module................................................................................................................... 205
3.4.11.1 10Gbps-SFP+-SMF-1511nm-70km-commercial............................................................................................. 206
3.4.11.2 10Gbps-SFP+-SMF-1471nm-70km-commercial............................................................................................. 207
3.4.11.3 10Gbps-SFP+-SMF-1491nm-70km-commercial............................................................................................. 208
3.4.11.4 10Gbps-SFP+-SMF-1531nm-70km-commercial............................................................................................. 209
3.4.11.5 10Gbps-SFP+-SMF-1551nm-70km-commercial............................................................................................. 211
3.4.11.6 10Gbps-SFP+-SMF-1571nm-70km-commercial............................................................................................. 212
3.4.11.7 10Gbps-SFP+-SMF-1591nm-70km-commercial............................................................................................. 213
3.4.11.8 10Gbps-SFP+-SMF-1611nm-70km-commercial............................................................................................. 215
3.4.12 10Gbps SFP+ BIDI Optical Module......................................................................................................................... 216
3.4.12.1 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-40km-commercial........................................................... 216
3.4.12.2 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-40km-commercial........................................................... 217
3.4.12.3 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-10km-industry.................................................................. 219
3.4.12.4 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-10km-industry.................................................................. 220
3.4.13 10Gbps SFP+ OTN Optical Module........................................................................................................................ 221
3.4.13.1 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial...........................................................................221
3.4.14 10Gbps SFP+ DWDM Optical Module...................................................................................................................223
3.4.14.1 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial...........................................................................223
3.4.15 25Gbps SFP28 Optical Module................................................................................................................................ 224
3.4.15.1 25Gbps-SFP28-MMF-850nm-0.1km-commercial (02312PDK)................................................................. 225
3.4.15.2 25Gbps-SFP28-SMF-1310nm-10km-industry (02312PDL)......................................................................... 226
3.4.15.3 25Gbps-SFP28-MMF-850nm-0.1km-commercial (34061254).................................................................. 227
3.4.15.4 25Gbps-SFP28-SMF-1310nm-10km-industry (34061618)..........................................................................228
3.4.15.5 25Gbps-SFP28-MMF-850nm-0.1km-extended............................................................................................... 230
3.4.16 25Gbps SFP28 BIDI Optical Module.......................................................................................................................231
3.4.16.1 25Gbps-SFP28-SMF-1270nm(Tx)/1330nm(Rx)-10km-commercial.........................................................231
3.4.16.2 25Gbps-SFP28-SMF-1330nm(Tx)/1270nm(Rx)-10km-commercial.........................................................233
3.4.17 40Gbps QSFP+ Optical Module............................................................................................................................... 234
3.4.17.1 40Gbps(4*10.3)-QSFP+-SMF-1271~1331nm-10km-commercial..............................................................234
3.4.17.2 40Gbps(4*10.3)-QSFP+-MMF-850nm-0.1km-commercial..........................................................................236
3.4.17.3 40Gbps(4*10.3)-QSFP+-SMF-1310nm-10km-commercial.......................................................................... 237
3.4.17.4 QSFP-40G-LX4-MM.................................................................................................................................................. 238
3.4.18 50Gbps QSFP28 Optical Module............................................................................................................................. 239
3.4.18.1 50Gbps-QSFP28-SMF-1311nm-10km-commercial....................................................................................... 239
3.4.18.2 50Gbps-QSFP28-SMF-1311nm-40km-commercial....................................................................................... 241
3.4.18.3 50Gbps-QSFP28-SMF-1295.56~1300.05nm-80km-commercial............................................................... 242
3.4.19 50Gbps QSFP28 BIDI Optical Module................................................................................................................... 244
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3.4.19.1 50Gbps-QSFP28-SMF-1331nm(Tx)/1271nm(Rx)-10km-commercial..................................................... 244
3.4.19.2 50Gbps-QSFP28-SMF-1271nm(Tx)/1331nm(Rx)-10km-commercial..................................................... 246
3.4.19.3 50Gbps-QSFP28-SMF-1295nm(Tx)/1309nm(Rx)-40km-commercial..................................................... 247
3.4.19.4 50Gbps-QSFP28-SMF-1309nm(Tx)/1295nm(Rx)-40km-commercial..................................................... 249
3.4.20 100Gbps QSFP28 Optical Module.......................................................................................................................... 251
3.4.20.1 100Gbps(4*25.7)-QSFP28-MMF-850nm-0.1km-commercial.....................................................................251
3.4.20.2 100Gbps(4*25.7)-QSFP28-SMF-1271~1331nm-2km-commercial........................................................... 253
3.4.20.3 100Gbps(4*25.7)-QSFP28-SMF-1310nm-30km(NO FEC)-40km(FEC)-commercial...........................254
3.4.20.4 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-commercial (02312BSS).....................256
3.4.20.5 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-80km-commercial............................................. 258
3.4.20.6 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-40km-commercial............................................. 259
3.4.20.7 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-commercial (02313SWA)...................261
3.4.20.8 100Gbps-QSFP28-1310nm-10km-commercial............................................................................................... 263
3.5 Cables..................................................................................................................................................................................... 264
3.5.1 NetEngine 8000 F1A-8H20Q Power Cable.............................................................................................................264
3.5.1.1 DC Power Cable........................................................................................................................................................... 264
3.5.1.2 AC Power Cable.......................................................................................................................................................... 269
3.5.2 Chassis Ground Cable.................................................................................................................................................... 273
3.5.3 Standard Serial Cable.................................................................................................................................................... 274
3.5.4 USB-to-Serial Cable........................................................................................................................................................ 276
3.5.5 Clock Cable (External Clock Mode, Delivery-Ready).......................................................................................... 277
3.5.6 Clock Cable (External Clock/External Time Mode, Prepared Onsite)........................................................... 279
3.5.7 Clock Bridging Cable...................................................................................................................................................... 281
3.5.8 Ethernet Cable..................................................................................................................................................................283
3.5.9 Fiber Jumpers................................................................................................................................................................... 286
3.6 Fiber Breakout..................................................................................................................................................................... 292
3.6.1 Breakout Fibers................................................................................................................................................................ 292
3.6.2 Breakout Boxes................................................................................................................................................................ 298
3.6.2.1 Product Overview........................................................................................................................................................ 298
3.6.2.2 10-Port-MPO-12-40-Port-LC-Breakout Box(single-mode)............................................................................299
4 Hardware Installation and Parts Replacement............................................................303
4.1 Hardware Installation and Maintenance Guide of NetEngine 8000 F1A-8H20Q........................................303
4.1.1 Hardware Installation and Usage Precautions..................................................................................................... 303
4.1.2 Introduction to the A66E Cabinet..............................................................................................................................305
4.1.3 Cabinet Accessories........................................................................................................................................................ 309
4.1.3.1 (Optional) Cabinet Stand......................................................................................................................................... 309
4.1.4 A66E Cabinet Installation.............................................................................................................................................311
4.1.4.1 Installing the Cabinet on the Concrete Floor.....................................................................................................311
4.1.4.1.1 Removing the Ground Cables and Cabinet Doors........................................................................................ 311
4.1.4.1.2 Determining the Installation Position of the Cabinets................................................................................311
4.1.4.1.3 Installing Expansion Bolts..................................................................................................................................... 313
4.1.4.1.4 Installing the Cabinet..............................................................................................................................................314
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4.1.4.1.5 Leveling the cabinet and testing the insulation............................................................................................ 315
4.1.4.1.6 Attaching the cabinets........................................................................................................................................... 316
4.1.4.1.7 Installing cabinet doors..........................................................................................................................................317
4.1.4.2 Installing the Cabinet on the ESD Floor.............................................................................................................. 318
4.1.4.2.1 Removing the Ground Cables and Cabinet Doors........................................................................................ 318
4.1.4.2.2 Determining the Installation Position of the Supports............................................................................... 319
4.1.4.2.3 Installing Expansion Bolts..................................................................................................................................... 320
4.1.4.2.4 Installing Supports................................................................................................................................................... 321
4.1.4.2.5 Installing the Cabinet..............................................................................................................................................324
4.1.4.2.6 Testing the Insulation and Installing the Front Pallet................................................................................. 326
4.1.4.2.7 Attaching the Cabinets and Restoring the ESD Floor..................................................................................328
4.1.4.2.8 Installing Cabinet Doors........................................................................................................................................ 329
4.1.5 Device Installation Process.......................................................................................................................................... 330
4.1.6 Preparation before installation...................................................................................................................................332
4.1.6.1 Reading Carefully the Safety Precautions........................................................................................................... 332
4.1.6.2 Checking the Installation Site..................................................................................................................................334
4.1.6.3 Checking the Cabinet................................................................................................................................................. 335
4.1.6.4 Preparing Installation Tools and Accessories..................................................................................................... 337
4.1.6.5 Inspecting and Cleaning Optical Fiber Connectors and Adapters.............................................................. 342
4.1.6.5.1 Overview..................................................................................................................................................................... 342
4.1.6.5.2 Protection of Optical Fiber Connectors............................................................................................................ 343
4.1.6.5.3 Tools, Equipment, and Materials........................................................................................................................ 344
4.1.6.5.4 Inspecting Optical Fiber Connectors..................................................................................................................345
4.1.6.5.5 Inspecting the Optical Fiber Link........................................................................................................................348
4.1.6.5.6 Cleaning Optical Fiber Connectors Using the Cassette Cleaner.............................................................. 350
4.1.6.5.7 Cleaning Optical Fiber Connectors Using Lens Tissue................................................................................ 351
4.1.6.5.8 Cleaning Optical Fiber Adapters Using Dustfree Absorbent Swabs....................................................... 354
4.1.6.6 Inspection of power distribution environment.................................................................................................. 356
4.1.6.6.1 Introduction to the Power Distribution System.............................................................................................356
4.1.6.6.2 DC Power Distribution Guide............................................................................................................................... 357
4.1.6.6.3 AC Power Distribution Guide............................................................................................................................... 358
4.1.6.7 Unpacking a Device.................................................................................................................................................... 361
4.1.6.7.1 Unpacking a Carton................................................................................................................................................ 361
4.1.7 Installing a Chassis in Cabinet.................................................................................................................................... 362
4.1.8 Cable Routing Planning................................................................................................................................................ 369
4.1.8.1 DC Power Cable Routing Planning........................................................................................................................ 369
4.1.8.2 AC Power Cable Routing Planning........................................................................................................................ 370
4.1.9 Installation of cables......................................................................................................................................................371
4.1.9.1 Installing Optical Fibers.............................................................................................................................................372
4.1.9.2 Installing Network Cables.........................................................................................................................................374
4.1.9.3 Installing a Cabinet Ground Cable.........................................................................................................................375
4.1.10 Post-Installation Check............................................................................................................................................... 377
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Hardware Guide Contents
4.1.11 Power-on Check............................................................................................................................................................ 380
4.1.12 (Optional) Checking Optical Power....................................................................................................................... 382
4.1.13 Maintenance of the device........................................................................................................................................ 384
4.1.13.1 Basic Operation Process and Precautions......................................................................................................... 384
4.1.13.2 Replacing a power module.................................................................................................................................... 386
4.1.13.2.1 Replacing the DC Power Module..................................................................................................................... 386
4.1.13.2.2 Replacing the AC Power Module......................................................................................................................388
4.1.13.3 Replacing the Fan Module..................................................................................................................................... 389
4.1.13.4 Replacing an Optical Module............................................................................................................................... 391
4.1.13.5 Replacing an Optical Cable................................................................................................................................... 396
4.1.13.6 Replacing a Network Cable................................................................................................................................... 398
4.1.14 Appendix.......................................................................................................................................................................... 399
4.1.14.1 On-site Cable Assembly and Installation.......................................................................................................... 399
4.1.14.1.1 Cable Assembly Precautions.............................................................................................................................. 399
4.1.14.1.2 Assembling Power Cables................................................................................................................................... 401
4.1.14.1.3 Assembling Ethernet Cables.............................................................................................................................. 413
4.1.14.1.4 Installing Cable Accessories............................................................................................................................... 427
4.1.14.1.5 Installing Ethernet Adapters.............................................................................................................................. 431
4.1.14.1.6 Installing Fiber Connectors.................................................................................................................................434
4.1.14.1.7 Replacing the Mold of the Crimping Tool..................................................................................................... 441
4.1.14.2 Environmental Requirements for Device Operation..................................................................................... 444
4.1.14.2.1 Environmental Requirements for Equipment Room..................................................................................444
4.1.14.2.2 Requirements for Power Supply....................................................................................................................... 452
4.1.14.3 Equipment Grounding Specifications................................................................................................................. 455
4.1.14.3.1 General Grounding Specifications....................................................................................................................455
4.1.14.3.2 Grounding Specifications for Equipment Room.......................................................................................... 455
4.1.14.3.3 Grounding Specifications for Devices............................................................................................................. 455
4.1.14.3.4 Grounding Specifications for Communications Power Supply............................................................... 456
4.1.14.3.5 Grounding Specifications for Signal Cables.................................................................................................. 457
4.1.14.3.6 Specifications for Laying Out Grounding Cables........................................................................................ 457
4.1.14.4 Engineering Labels for Cables...............................................................................................................................458
4.1.14.4.1 Introduction to Labels.......................................................................................................................................... 458
4.1.14.4.2 Engineering Labels for Optical Fibers.............................................................................................................466
4.1.14.4.3 Engineering Labels for Network Cables.........................................................................................................468
4.1.14.4.4 Engineering Labels for User Cables................................................................................................................. 470
4.1.14.4.5 Engineering Labels for Power Cables..............................................................................................................471
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. viii
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 1 Document Declaration
1 Document Declaration
Purpose
This document describes hardware features of the NetEngine 8000 F1A. It helps
intended readers obtain detailed information about each chassis, board, and cable,
and learn how to install and maintain devices.
NO TICE
The Hardware Guide includes hardware data of multiple versions. Before using this
document, check the first version supported by the hardware.
Related Version
NO TICE
The following table lists the product versions involved in this document. Before
reading this document, confirm whether your versions are included in this
document.
Product Name Version
HUAWEI NetEngine 8000 F1A Applicable to:
● V800R012C10SPC300
● V800R013C00SPC100
● V800R021C00SPC100
● V800R021C10SPC600
● V800R022C00SPC600
● V800R022C10SPC500
● V800R023C00SPC500
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 1
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 1 Document Declaration
Intended Audience
This document is intended for:
● Network planning engineers
● Hardware installation engineers
● Commissioning engineers
● On-site maintenance engineers
● System maintenance engineers
Special Declaration
● The pictures of hardware in this document are for reference only.
● The supported boards are described in the document. Whether a
customization requirement can be met is subject to the information provided
at the pre-sales interface.
● All device dimensions described in this document are designed dimensions
and do not include dimension tolerances. In the process of component
manufacturing, the actual size is deviated due to factors such as processing or
measurement.
Symbol Conventions
The symbols that may be found in this document are defined as follows.
Symbol Description
Indicates a hazard with a high level of risk which, if
not avoided, will result in death or serious injury.
Indicates a hazard with a medium level of risk
which, if not avoided, could result in death or
serious injury.
Indicates a hazard with a low level of risk which, if
not avoided, could result in minor or moderate
injury.
Indicates a potentially hazardous situation which, if
not avoided, could result in equipment damage,
data loss, performance deterioration, or
unanticipated results.
NOTICE is used to address practices not related to
personal injury.
Supplements the important information in the main
text.
NOTE is used to address information not related to
personal injury, equipment damage, and
environment deterioration.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 2
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 1 Document Declaration
Change History
● Changes in Issue 04 (2025-04-30)
This is the fourth official release.
● Changes in Issue 03 (2024-12-31)
This is the third official release.
● Changes in Issue 02 (2024-08-30)
This is the second official release.
● Changes in Issue 01 (2024-06-30)
This is the first official release.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 3
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 2 Using the Hardware Tool
2 Using the Hardware Tool
Enterprise:
In the enterprise network market, Info-Finder is a tool platform, It allows you to
search for key product information by product series and model. The key product
information includes basic information such as the software specifications, life
cycles, and hardware information, and operation and maintenance information
such as the licenses, alarms, logs, commands, and MIBs. The hardware-related
tools are as follows:
● Product image gallery: provides product photos, and network element icons
for you to produce design drawings and networking diagrams.
● Hardware configuration: automatically generates hardware configuration
diagrams after you select components are required and calculates the weight,
power consumption, and heat consumption.
● Hardware center: provides the technical specifications of devices and
components, as well as the mapping between devices, components, and
versions.
● 3D model: Using this function, you can query product images, product
overview, and component insertion/removal videos, enabling you to quickly
obtain product information in one-stop mode.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 4
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
3 Hardware Description
3.1 Chassis
3.2 Power
3.3 Fan
3.4 Optical Module
3.5 Cables
3.6 Fiber Breakout
3.1 Chassis
3.1.1 NetEngine 8000 F1A-8H20Q
Overview
Table 3-1 Basic information about the NetEngine 8000 F1A-8H20Q
Description Part Number Model First Integrated
supported fixed device
version
NetEngine 02353AES CR8B0BKP03C V800R012C00 Y
8000 0 SPC300
F1A-8H20Q
Integrated
Chassis
Components
(Port-side
Intake)
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 5
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Description Part Number Model First Integrated
supported fixed device
version
NetEngine 02353AES-00 CR8B0BKP03C V800R021C10 Y
8000 1 0 SPC600
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Intake)
NetEngine 02353AES-00 CR8B0BKP03C V800R022C10 Y
8000 6 0 SPC500
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Intake)
NetEngine 02353AGV CR8B0BKP03C V800R012C00 Y
8000 2 SPC300
F1A-8H20Q
Integrated
Chassis
Components
(Port-side
Exhaust)
NetEngine 02353AGV-00 CR8B0BKP03C V800R021C10 Y
8000 1 2 SPC600
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Exhaust)
NetEngine 02353AGV-00 CR8B0BKP03C V800R022C10 Y
8000 2 2 SPC500
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Exhaust)
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 6
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Description Part Number Model First Integrated
supported fixed device
version
NetEngine 02355KVX CR8B0BKP03 V800R022C10 Y
8000 D0 SPC500
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Intake)
NetEngine 02355KVY CR8B0BKP03 V800R022C10 Y
8000 D2 SPC500
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Exhaust)
NO TE
In specific areas, as the auxiliary materials are different, the sales BOM numbers may be
different. Different sales BOM numbers may correspond to the same description in the
device attribute table. The actual sales BOM number in an area prevails.
Appearance
Figure 3-1 Appearance of the NetEngine 8000 F1A-8H20Q (port side)
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 7
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Figure 3-2 Appearance of the NetEngine 8000 F1A-8H20Q (power side)
NO TE
Figures in the document are for reference only, and the actual appearance of the devices
may vary depending on the exact device model.
A chassis that adopts port-side air intake can house only power modules and fan modules
with the same air intake mode.
Similarly, a chassis that adopts port-side air exhaust can house only power modules and fan
modules with the same air exhaust mode.
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 8
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
desired information and filter the mapping data for more fine-grained data
display.
Slot Layout
Figure 3-3 Slot Layout of the NetEngine 8000 F1A-8H20Q
Table 3-2 Slots on the NetEngine 8000 F1A-8H20Q
Slot Type Slot ID Slot Direction Remarks
IPU 1 - Fixed ports
POWER 2 - Power supply
POWER 3 - Power supply
FAN 4 - Fan
FAN 5 - Fan
FAN 6 - Fan
FAN 7 - Fan
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 9
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Panel
Figure 3-4 Panel on the NetEngine 8000 F1A-8H20Q
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 10
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
1. Status indicator(STAT) 2. Port status 3. Breakout channel
indicator(0~55) indicator(BREAKOUT(0~
3))
4. Port status 5. Management port 6. Reset button(RST)
indicator(GE0,GE1) status indicator(L/A)
Table 3-3 Indicators on the NetEngine 8000 F1A-8H20Q
Silkscreen Name Color Status Description
STAT Status Green Steady on The device is
indicator working
properly.
Green Blinking The device is
starting up.
Red Steady on An alarm is
generated.
Orange Blinking Status in
which the
passwords
and
configurations
on the card
are being
cleared
NOTE
This indicator
status is
supported
since
V800R013C00.
- Off The system is
not powered
on or
registered.
L/A (MGMT- Management Green Steady on The link is up.
ETH) port status
indicator Green Blinking Data is being
transmitted or
received.
- Off The link is
down.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 11
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Silkscreen Name Color Status Description
BREAKOUT Breakout Green Blink Each
(0–3) channel BREAKOUT
indicator indicator for
channels 0 to
3 is on for 5s
in sequence
to indicate
the status of
the
corresponding
channel, and
this process
repeats.
- Off No data is
transmitting
or receiving in
this channel.
GE0, GE1 Port status Green Steady on The link is up.
indicator
Green Blinking Data is being
transmitted or
received.
- Off The link is
down.
0 to 55 Green Steady on The link is up.
Green Blinking Data is being
transmitted or
received.
0~55 - Off The link is
down.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 12
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Table 3-4 Buttons on the NetEngine 8000 F1A-8H20Q
Silkscreen Name Description
RST Reset button You can press the RST
button to reset the NE or
restore the factory
settings of the NE.
The procedure is as
follows:
To reset the NE, press
the RST button and
release it.
From V8R13C00, to
restore factory settings,
press and hold the RST
button. This operation
will clear the NE
database and system
parameter configurations
and cannot be restored.
Exercise caution when
you perform the
following operations:
1. Press and release the
RST button to restart the
NE.
2.When the STAT
indicator blinks as green
(the blinking frequency
is about 250 ms and the
time window is about 15
seconds), press and hold
the RST button.
3.Wait for no longer
than 2 minutes till the
STAT indicators blink as
orange(the time window
is 5 seconds). Then
release the RST button
immediately.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 13
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Silkscreen Name Description
NOTE
In V800R013C00 and later
versions, the RST button
can be used to clear
configurations. If the
software version is lower
than V800R013C00, pay
attention to upgrade the
CPU EPLD version from
V800R013C00 manually
before using this function.
For the detailed operation
description, see the
corresponding chapter in
the upgrade guide
document.
1. When you press the RST
button to clear the
configuration file, the
original configuration file
will be cleared. You are
advised to periodically
back up the configuration
file.
2. When pressing the RST
button to clear the
configuration file, you only
need to pay attention to
the STAT indicators. Other
indicators may vary
depending on the product
model.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 14
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Table 3-5 Ports on the NetEngine 8000 F1A-8H20Q
Port Connector Type Description Available
Components
0~27 SFP+ Inputs and 10Gbps SFP+
outputs 10GE/GE Optical Module
optical signals. 10Gbps SFP+
1. Interfaces 0 to DWDM Optical
27 support 10GE Module
WAN, and other 10Gbps SFP+
interfaces do not CWDM Optical
support 10GE Module
WAN.
10Gbps SFP+
2. Ports 0-3, 4-7, BIDI Optical
8-11, 12-15, Module
16-19, 20-23 and
24-27 form a port 1Gbps Electrical
group, Module
respectively. The 1.25Gbps eSFP
four ports in each BIDI Optical
port group must Module
work in 10GE 1.25Gbps eSFP
WAN or 10GE CWDM Optical
LAN mode at the Module
same time. 10GE
WAN and 10GE 1.25Gbps eSFP
LAN cannot Optical Module
coexist. 125M~2.67Gbps
3. 10GE WAN eSFP DWDM
interfaces support Optical Module
only the master 155Mbps eSFP
clock. BIDI Optical
4. The following Module
models support 155Mbps eSFP
the AE 905M Optical Module
module:
CR8B0BKP03D0
and
CR8B0BKP03D2.
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Port Connector Type Description Available
Components
28~35 SFP28 Port for inputting 25Gbps SFP28
and outputting Optical Module
25GE/10GE/GE 25Gbps SFP28
optical signals BIDI Optical
NOTE Module
Ports 28–31 belong
to a port group, 10Gbps SFP+
and ports 32–35 Optical Module
belong to another 10Gbps SFP+
one. These ports
DWDM Optical
work in 25GE/
10GE auto-sensing Module
mode by default. 10Gbps SFP+
You can run the CWDM Optical
port-mode group-
id command in the Module
slot view to switch 10Gbps SFP+
the working mode BIDI Optical
to 10GE/GE auto- Module
sensing for ports in
a port group. 1Gbps Electrical
Module
1.25Gbps eSFP
BIDI Optical
Module
1.25Gbps eSFP
CWDM Optical
Module
1.25Gbps eSFP
Optical Module
125M~2.67Gbps
eSFP DWDM
Optical Module
155Mbps eSFP
BIDI Optical
Module
155Mbps eSFP
Optical Module
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 16
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Port Connector Type Description Available
Components
36~47 SFP28 Port for inputting 25Gbps SFP28
and outputting Optical Module
25GE/10GE 25Gbps SFP28
optical signals BIDI Optical
Module
10Gbps SFP+
Optical Module
10Gbps SFP+
DWDM Optical
Module
10Gbps SFP+
CWDM Optical
Module
10Gbps SFP+
BIDI Optical
Module
48~55 QSFP28 Port for inputting 100Gbps QSFP28
and outputting Optical Module
100GE/50GE/ 50Gbps QSFP28
40GE/breakout Optical Module
4x25GE/breakout
4x10GE optical 50Gbps QSFP28
signals BIDI Optical
Module
40Gbps QSFP+
Optical Module
GE0/GE1 SFP Cascading port Reserved
used for control
panel expansion
in scenarios like
virtual cluster
(reserved)
MGMT-ETH RJ45 Port for Category 5
connecting to the enhanced
NMS workstation shielded twisted
pairs
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Port Connector Type Description Available
Components
Console/AUX RJ45 Port for 8-core shielded
hybrid interface connecting to the cables
console for onsite
system
configuration. The
default baud rate
is 9600 bit/s.
(AUX hybrid
interface
reserved)
TOD clock RJ45 Port for inputting 120-ohm clock
interface and outputting cable
one-channel 1PPS
+TOD time signals
or one-channel
DCLS signals
CLK interface RJ45 Port for inputting 120-ohm clock
and outputting 2 cable
Mbit/s or 2 MHz
clock signals
USB Type A USB port NA
(reserved)
Interface Numbering Rules
On the NetEngine 8000 F1A-8H20Q, an interface is numbered in the format of
"slot number/subcard number/port number". The following part describes the
details:
● Slot number
The slot number of NetEngine 8000 F1A-8H20Q is always 0.
● Subcard number
The NetEngine 8000 F1A-8H20Q does not support subcards. Therefore, the
subcard number of the NetEngine 8000 F1A-8H20Q is fixed as 1.
● Port number
The port numbers of service interfaces on the NetEngine 8000 F1A-8H20Q
begin with 0. Port numbering depends on the number of interfaces on the
NetEngine 8000 F1A-8H20Q.
Figure 3-5 Port number
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Labels
Figure 3-6 Label position
Table 3-6 Label description
Figure Label Name Description
Chassis bar The bar code will be retrieved by the device as
code label the equipment serial number (ESN).
Multi-power This device has more than one power input.
input caution Disconnect all power inputs to power off this
device.
Product The label suggests the product name,
nameplate certification and qualification.
label
Power Supply System
The system supports DC and AC power supply in 1+1 backup mode.
The power supply system provides the fault monitoring and alarming function.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 19
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
The two power modules work in 1+1 backup mode. The two power supply
channels in backup mode are converted by two independent power supply
modules and then provided for Control board and fans.
Figure 3-7 Power supply architecture
Heat Dissipation System
The system air channel allows air to flow from front to back or from back to front.
Figure 3-8 Front to back (NetEngine 8000 F1A-8H20Q)
Figure 3-9 Back to front (NetEngine 8000 F1A-8H20Q)
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 20
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Technical Specifications
Table 3-7 Technical specifications of the CR8B0BKP03C0 (02353AES)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Weight without packaging [kg(lb)] 6.3 kg (13.89 lb)
Weight with packaging [kg(lb)] 11.2 kg (24.69 lb)
Weight without packaging (full DC: 8.4 kg (18.52 lb)
configuration) [kg(lb)] AC: 8.75 kg (19.29 lb)
Weight with packaging (full DC: 13.58 kg(29.94 lb)
configuration) [kg(lb)] AC: 13.75 kg(30.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 20-core 2.0 GHz
Memory 16 GB
Flash memory 64 MB
Storage 4G NAND FLASH
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100 V to 240 V AC, support 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Maximum input current [A] DC: 30 A
600 W AC: 8 A
1200 W AC: 10 A
Rated output power [W] DC: 1000 W
600 W AC: 600 W
1200 W AC: 1200 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC:≥32A
AC:≥10A
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Front to back: port-side intake
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36 (V800R012C00: 28, V800R012C10
and later versions: 36)
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Front-to-rear model: –5°C to +45°C
[°C(°F)] (23°F to 113°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 23
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-8 Technical specifications of the CR8B0BKP03C0 (02353AES-001)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 24
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 6.8 kg (14.99 lb)
Weight with packaging [kg(lb)] 11.7 kg (25.79 lb)
Weight without packaging (full DC: 8.9 kg (19.62 lb)
configuration) [kg(lb)] AC: 9.2 kg (20.28 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 8-core 2.3 GHz
Memory 16 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 25
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Front to back: port-side intake
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Front-to-rear model: –5°C to +45°C
[°C(°F)] (23°F to 113°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 26
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 27
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-9 Technical specifications of the CR8B0BKP03C0 (02353AES-006)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 28
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 7 kg (15.43 lb)
Weight with packaging [kg(lb)] 11.9 kg (26.23 lb)
Weight without packaging (full DC: 8.8 kg (19.4 lb)
configuration) [kg(lb)] AC: 9.45 kg (20.83 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 16-core, 2.0 GHz
Memory 32 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 29
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Front to back: port-side intake
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Front-to-rear model: –5°C to +45°C
[°C(°F)] (23°F to 113°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 30
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 31
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-10 Technical specifications of the CR8B0BKP03C2 (02353AGV)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 32
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 6.3 kg (13.89 lb)
Weight with packaging [kg(lb)] 11.2 kg (24.69 lb)
Weight without packaging (full DC: 8.4 kg (18.52 lb)
configuration) [kg(lb)] AC: 8.75 kg (19.29 lb)
Weight with packaging (full DC: 13.58 kg(29.94 lb)
configuration) [kg(lb)] AC: 13.75 kg(30.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 20-core 2.0 GHz
Memory 16 GB
Flash memory 64 MB
Storage 4G NAND FLASH
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100 V to 240 V AC, support 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
600 W AC: 8 A
1200 W AC: 10 A
Rated output power [W] DC: 1000 W
600 W AC: 600 W
1200 W AC: 1200 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 33
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Front-end circuit breaker/fuse [A] DC:≥32A
AC:≥10A
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Back to front: port-side exhaust
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36 (V800R012C00: 28, V800R012C10
and later versions: 36)
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Rear-in front-out model: –5°C to +40°C
[°C(°F)] (23°F to 104°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 34
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 35
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-11 Technical specifications of the CR8B0BKP03C2 (02353AGV-001)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 36
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 6.8 kg (14.99 lb)
Weight with packaging [kg(lb)] 11.7 kg (25.79 lb)
Weight without packaging (full DC: 8.9 kg (19.62 lb)
configuration) [kg(lb)] AC: 9.2 kg (20.28 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 8-core 2.3 GHz
Memory 16 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 37
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Back to front: port-side exhaust
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Rear-in front-out model: –5°C to +40°C
[°C(°F)] (23°F to 104°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 38
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 39
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-12 Technical specifications of the CR8B0BKP03C2 (02353AGV-002)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 40
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 7 kg (15.43 lb)
Weight with packaging [kg(lb)] 11.9 kg (26.23 lb)
Weight without packaging (full DC: 8.8 kg (19.4 lb)
configuration) [kg(lb)] AC: 9.45 kg (20.83 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 16-core, 2.0 GHz
Memory 32 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 41
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Back to front: port-side exhaust
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Rear-in front-out model: –5°C to +40°C
[°C(°F)] (23°F to 104°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 42
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 43
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-13 Technical specifications of the CR8B0BKP03D0
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 44
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 7 kg (15.43 lb)
Weight with packaging [kg(lb)] 11.9 kg (26.23 lb)
Weight without packaging (full DC: 8.8 kg (19.4 lb)
configuration) [kg(lb)] AC: 9.45 kg (20.83 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 16-core, 2.0 GHz
Memory 32 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 45
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Front to back: port-side intake
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Front-to-rear model: –5°C to +45°C
[°C(°F)] (23°F to 113°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 46
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported Yes
Physical port 48, 49, 50, and 51 can be
added to the same FlexE group. port-id
ranges from 56 to 95 and from 1000
to 3000. Such a FlexE group supports a
maximum of 40 FlexE clients.
Physical port 52, 53, 54, and 55 can be
added to the same FlexE group. port-id
ranges from 96 to 135 and from 1000
to 3000. Such a FlexE group supports a
maximum of 40 FlexE clients.
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 47
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-14 Technical specifications of the CR8B0BKP03D2
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 48
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 7 kg (15.43 lb)
Weight with packaging [kg(lb)] 11.9 kg (26.23 lb)
Weight without packaging (full DC: 8.8 kg (19.4 lb)
configuration) [kg(lb)] AC: 9.45 kg (20.83 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 16-core, 2.0 GHz
Memory 32 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 49
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Back to front: port-side exhaust
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Rear-in front-out model: –5°C to +40°C
[°C(°F)] (23°F to 104°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 50
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported Yes
Physical port 48, 49, 50, and 51 can be
added to the same FlexE group. port-id
ranges from 56 to 95 and from 1000
to 3000. Such a FlexE group supports a
maximum of 40 FlexE clients.
Physical port 52, 53, 54, and 55 can be
added to the same FlexE group. port-id
ranges from 96 to 135 and from 1000
to 3000. Such a FlexE group supports a
maximum of 40 FlexE clients.
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 51
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 52
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
NO TE
● About condensation
The ability of air to contain moisture reduces as the temperature decreases. There is a
relationship between temperature and relative humidity. As the temperature decreases,
the air becomes more saturated with moisture, meaning the relative humidity increases.
But at a low enough temperature (called the dew point), the air can no longer contain
moisture, which is then precipitated as liquid water. Such water on the surface of
relevant equipment is called condensation.
● Hazards of condensation
When condensation mixes with dust inside the equipment, it forms conductive channels
that affect the electrical insulation of the equipment. As a result, a non-conductive area
of the equipment can become conductive, causing the equipment to malfunction.
● Conditions that cause condensation
Condensation is related to temperature changes and humidity. It occurs when the
temperature continues to decrease below the dew point at a given humidity. For
example, given that the relative humidity is 50% RH and the temperature is 25°C (77°F),
condensation occurs when the temperature decreases below 13.9°C (57.02°F).
3.2 Power
3.2.1 NetEngine 8000 F1A-8H20Q Power Module
3.2.1.1 PAC1K2S12-DB (1200W AC Power Module(Back to Front, Power panel
side exhaust))
Overview
Table 3-15 Basic information about the PAC1K2S12-DB
Item Details
Description 1200W AC Power Module(Back to
Front, Power panel side exhaust)
Part Number 02131672
Model PAC1K2S12-DB
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 53
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Appearance
Figure 3-10 Appearance of the PAC1K2S12-DB
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02131672&productModel=PAC1K2S12-DB#matchRelation
Panel
Table 3-16 Indicators on the PAC1K2S12-DB
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 54
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Table 3-17 Ports on the PAC1K2S12-DB
Port Description
AC power cable connector Connects to the AC power cable
Technical Specifications
Table 3-18 Technical specifications of the PAC1K2S12-DB
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.87 kg(1.92 lb)
Number of inputs 1
Rated input voltage [V] 100 V to 240 V AC, support 240 V
HVDC
Input voltage range [V] 90 V to 290 V AC
Maximum input current [A] 10 A
Rated output voltage [V] 12 V
Rated output current [A] 100 A (input >176V AC)
67 A (input <176V AC)
Rated output power [W] 1200 W (input >176V AC)
800 W (input <176V AC)
Power supply efficiency 0.9
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.2 PAC1K2S12-DF (1200W AC Power Module(Front to Back,Power panel
side intake))
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 55
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Overview
Table 3-19 Basic information about the PAC1K2S12-DF
Item Details
Description 1200W AC Power Module(Front to
Back,Power panel side intake)
Part Number 02131674
Model PAC1K2S12-DF
Appearance
Figure 3-11 Appearance of the PAC1K2S12-DF
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02131674&productModel=PAC1K2S12-DF#matchRelation
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 56
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Panel
Table 3-20 Indicators on the PAC1K2S12-DF
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-21 Ports on the PAC1K2S12-DF
Port Description
AC power cable connector Connects to the AC power cable
Technical Specifications
Table 3-22 Technical specifications of the PAC1K2S12-DF
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.87 kg(1.92 lb)
Number of inputs 1
Rated input voltage [V] 100 V to 240 V AC, support 240 V
HVDC
Input voltage range [V] 90 V to 290 V AC
Maximum input current [A] 10 A
Rated output voltage [V] 12 V
Rated output current [A] 100 A (input >176V AC)
67 A (input <176V AC)
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 57
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Rated output power [W] 1200 W (input >176V AC)
800 W (input <176V AC)
Power supply efficiency 0.9
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.3 PAC600S12-CB (600W AC Power Module(Back to Front, Power panel
side exhaust))
Overview
Table 3-23 Basic information about the PAC600S12-CB
Item Details
Description 600W AC Power Module(Back to
Front, Power panel side exhaust)
Part Number 02312FFU
Model PAC600S12-CB
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 58
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Appearance
Figure 3-12 Appearance of the PAC600S12-CB
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02312FFU&productModel=PAC600S12-CB#matchRelation
Panel
Table 3-24 Indicators on the PAC600S12-CB
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 59
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Silkscreen Name Color Status Description
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-25 Ports on the PAC600S12-CB
Port Description
AC power cable connector Connects to the AC power cable.
Technical Specifications
Table 3-26 Technical specifications of the PAC600S12-CB
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.95 kg (2.09 lb)
Rated input voltage [V] 100V to 240V AC, support 240V HVDC
Input voltage range [V] 90 V to 290 V
Maximum input current [A] 8 A
Rated output voltage [V] 12 V
Rated output current [A] 50 A
Rated output power [W] 600 W
Power supply efficiency 0.91
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.4 PAC600S12-CF (600W AC Power Module(Front to Back,Power panel
side intake))
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 60
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Overview
Table 3-27 Basic information about the PAC600S12-CF
Item Details
Description 600W AC Power Module(Front to
Back,Power panel side intake)
Part Number 02312KNA
Model PAC600S12-CF
Appearance
Figure 3-13 Appearance of the PAC600S12-CF
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 61
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02312KNA&productModel=PAC600S12-CF#matchRelation
Panel
Table 3-28 Indicators on the PAC600S12-CF
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-29 Ports on the PAC600S12-CF
Port Description
AC power cable connector Connects to the AC power cable.
Technical Specifications
Table 3-30 Technical specifications of the PAC600S12-CF
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.95 kg (2.09 lb)
Rated input voltage [V] 100V to 240V AC, support 240V HVDC
Input voltage range [V] 90 V to 290 V
Maximum input current [A] 8 A
Rated output voltage [V] 12 V
Rated output current [A] 50 A
Rated output power [W] 600 W
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 62
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Power supply efficiency 0.91
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.5 PAC600S12-EB (600W AC Power Module(Back to Front, Power panel
side exhaust))
Overview
Table 3-31 Basic information about the PAC600S12-EB
Item Details
Description 600W AC Power Module(Back to
Front, Power panel side exhaust)
Part Number 02312FFU-002
Model PAC600S12-EB
Appearance
Figure 3-14 Appearance of the PAC600S12-EB
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 63
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
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enterprise: https://info.support.huawei.com/info-finder/search-center/en/
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keyword=02312FFU-002&productModel=PAC600S12-EB#matchRelation
Panel
Table 3-32 Indicators on the PAC600S12-EB
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-33 Ports on the PAC600S12-EB
Port Description
AC power cable connector Connects to the AC power cable.
Technical Specifications
Table 3-34 Technical specifications of the PAC600S12-EB
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.985 kg (2.17 lb)
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Item Specification
Rated input voltage [V] 100V to 240V AC, support 240V HVDC
Input voltage range [V] 90 V to 290 V
Maximum input current [A] 8 A
Rated output voltage [V] 12 V
Rated output current [A] 50 A
Rated output power [W] 600 W
Power supply efficiency 0.91
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.6 PAC600S12-EF (600W AC Power Module(Front to Back,Power panel
side intake))
Overview
Table 3-35 Basic information about the PAC600S12-EF
Item Details
Description 600W AC Power Module(Front to
Back,Power panel side intake)
Part Number 02313RMT
Model PAC600S12-EF
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Appearance
Figure 3-15 Appearance of the PAC600S12-EF
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The Info-Finder hardware center incorporates comprehensive hardware
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Panel
Table 3-36 Indicators on the PAC600S12-EF
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
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Silkscreen Name Color Status Description
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-37 Ports on the PAC600S12-EF
Port Description
AC power cable connector Connects to the AC power cable.
Technical Specifications
Table 3-38 Technical specifications of the PAC600S12-EF
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.985 kg (2.17 lb)
Rated input voltage [V] 100V to 240V AC, support 240V HVDC
Input voltage range [V] 90 V to 290 V
Maximum input current [A] 8 A
Rated output voltage [V] 12 V
Rated output current [A] 50 A
Rated output power [W] 600 W
Power supply efficiency 0.91
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.7 PDC1000S12-CB (1000W DC Power Module(Back to Front,Power
panel side exhaust))
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Overview
Table 3-39 Basic information about the PDC1000S12-CB
Item Details
Description 1000W DC Power Module(Back to
Front,Power panel side exhaust)
Part Number 02312JVG
Model PDC1000S12-CB
Appearance
Figure 3-16 Appearance of the PDC1000S12-CB
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Panel
Table 3-40 Indicators on the PDC1000S12-CB
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-41 Ports on the PDC1000S12-CB
Port Description
NEG(-) Connects to the negative pole of the
DC power cable.
RTN(+) Connects to the positive pole of the
DC power cable.
Technical Specifications
Table 3-42 Technical specifications of the PDC1000S12-CB
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.87 kg(1.92 lb)
Rated input voltage [V] –48 V/–60 V
Input voltage range [V] –40 V to –72 V
Maximum input current [A] 30 A
Rated output voltage [V] 12 V
Rated output current [A] 83.3 A
Rated output power [W] 1000 W
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Item Specification
Power supply efficiency 0.88
Power dissipation Mode Built-in fan
3.2.1.8 PDC1000S12-CF (1000W DC Power Module(Front to Back,Power
panel side intake))
Overview
Table 3-43 Basic information about the PDC1000S12-CF
Item Details
Description 1000W DC Power Module(Front to
Back,Power panel side intake)
Part Number 02312KAB
Model PDC1000S12-CF
Appearance
Figure 3-17 Appearance of the PDC1000S12-CF
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The Info-Finder hardware center incorporates comprehensive hardware
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enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
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Panel
Table 3-44 Indicators on the PDC1000S12-CF
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-45 Ports on the PDC1000S12-CF
Port Description
NEG(-) Connects to the negative pole of the
DC power cable.
RTN(+) Connects to the positive pole of the
DC power cable.
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Technical Specifications
Table 3-46 Technical specifications of the PDC1000S12-CF
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.87 kg(1.92 lb)
Rated input voltage [V] –48 V/–60 V
Input voltage range [V] –40 V to –72 V
Maximum input current [A] 30 A
Rated output voltage [V] 12 V
Rated output current [A] 83.3 A
Rated output power [W] 1000 W
Power supply efficiency 0.88
Power dissipation Mode Built-in fan
3.3 Fan
3.3.1 NetEngine 8000 F1A-8H20Q Fan Module
3.3.1.1 FAN-031A-B (Fan box(B,FAN panel side exhaust))
Overview
Table 3-47 Basic information about the FAN-031A-B
Item Details
Description Fan box(B,FAN panel side exhaust)
Part Number 02352CAB
Model FAN-031A-B
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Appearance
Figure 3-18 Appearance of the FAN-031A-B
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keyword=02352CAB&productModel=FAN-031A-B#matchRelation
Panel
Table 3-48 Indicators on the FAN-031A-B
Silkscreen Name Color Status Description
FAN Fan status Green steady The board is
indicator working
properly
Red steady The fan
module is
faulty
Green off The fan
module is not
powered on
or encounters
a hardware
error
Technical Specifications
Table 3-49 Technical specifications of the FAN-031A-B
Item Specification
Dimensions without packaging (H x W 40 mm x 40 mm x 100.3 mm (1.57 in.
x D) [mm(in.)] x 1.57 in. x 3.95 in.)
Weight without packaging [kg(lb)] 0.15 kg (0.33 lb)
Number of fans 1
Typical power consumption [W] 4.8 W
3.3.1.2 FAN-031A-F (Fan Box(F,FAN panel side intake ))
Overview
Table 3-50 Basic information about the FAN-031A-F
Item Details
Description Fan Box(F,FAN panel side intake )
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Item Details
Part Number 02352CAA
Model FAN-031A-F
Appearance
Figure 3-19 Appearance of the FAN-031A-F
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The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
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display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02352CAA&productModel=FAN-031A-F#matchRelation
Panel
Table 3-51 Indicators on the FAN-031A-F
Silkscreen Name Color Status Description
FAN Fan status Green steady The board is
indicator working
properly
Red steady The fan
module is
faulty
Green off The fan
module is not
powered on
or encounters
a hardware
error
Technical Specifications
Table 3-52 Technical specifications of the FAN-031A-F
Item Specification
Dimensions without packaging (H x W 40 mm x 40 mm x 100.3 mm (1.57 in.
x D) [mm(in.)] x 1.57 in. x 3.95 in.)
Weight without packaging [kg(lb)] 0.15 kg (0.33 lb)
Number of fans 1
Typical power consumption [W] 4.8 W
3.4 Optical Module
3.4.1 Understanding Pluggable Optical Modules
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3.4.1.1 Appearance and Structure
Figure1 shows the structure of an optical module.
Figure 3-20 Optical module structure
1. Handle 2. Receiver 3. Transmitter 4. Shell
5. Label 6. Dust cap 7. Spring 8. Module
connector
3.4.1.2 Types of Optical Modules
Optical modules are available in various types to meet diversified requirements.
● Classified by transmission rates
Currently, the transmission rates of optical modules cover a wide range.
According to different transmission rates, optical modules can be classified
into 400 Gbit/s optical modules, 200 Gbit/s optical modules, 100 Gbit/s optical
modules, 40 Gbit/s optical modules, 25 Gbit/s optical modules, and 10 Gbit/s
optical modules, 2.5 Gbit/s optical modules, 1.25 Gbit/s optical modules, 1000
Mbit/s optical modules, 155 Mbit/s optical modules, and 100 Mbit/s optical
modules.
● Classified by encapsulation types
The higher transmission rate an optical module provides, the more complex
structure it has. According to the encapsulation type, optical modules are
classified into SFP, eSFP, SFP+, XFP, SFP28, QSFP28, QSFP+, CXP, CFP, CSFP, and
QSFP-DD.
– SFP: small form-factor pluggable.
– eSFP: enhanced small form-factor pluggable. An eSFP module is an SFP
module that supports monitoring of voltage, temperature, bias current,
transmit optical power, and receive optical power. Currently, SFP modules
also have the preceding functions. Therefore, eSFP and SFP optical
modules are both called SFP optical modules.
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– SFP+: small form-factor pluggable plus. An SPF+ optical module is an SFP
module with a higher rate. SFP+ modules are more sensitive to
electromagnetic interference (EMI) because they have a higher rate.
Compared with SFP modules, SFP+ optical modules use more springs and
tighter SFP+ optical module cages.
– XFP: 10G small form-factor pluggable. X is the Roman numeral 10,
meaning that all XFP optical modules provide a transmission rate of 10
Gbit/s. XFP optical modules are wider and longer than SFP+ optical
modules.
– SFP28: small form-factor pluggable 28. The size of an SFP28 optical
module is the same as that of an SFP+ optical module. An SFP28 port can
use a 25G SFP28 optical module or 10G SFP+ optical module.
– QSFP28: quad small form-factor pluggable 28. The size of a QSFP28
optical module is the same as that of a QSFP+ optical module. A QSFP28
port can use either a 100G QSFP28 optical module or a 40G QSFP+
optical module.
– QSFP+: quad small form-factor pluggable plus. A QSFP+ optical module
supports the MPO connector and is larger than an SFP+ optical module.
– QSFP-DD: quad small form factor pluggable-double density. A QSFP-DD
optical module is a high-speed pluggable module defined by the QSFP-
DD MSA group.
– CXP: extended-capability form-factor pluggable. A CXP optical module is
a hot-pluggable high-density parallel optical module, which provides 12
channels of traffic in each of the Tx and Rx directions. It applies only to
short-distance multimode links.
– CFP: centum form-factor pluggable, a new standard for high-speed, hot-
pluggable optical transceivers that support data communication and
telecommunication applications. The dimensions of a CFP optical module
are 13.6 mm x 144.75 mm x 82 mm (0.54 in. x 5.70 in. x 3.23 in.).
– CSFP: compact small form-factor pluggable. A CSFP optical module is a
compact SFP transceiver with two 100 Mbit/s or 1 Gbit/s single-fiber
bidirectional transceivers inside a standard SFP form factor. Its compact
and low-power design allows the system supplier to double port density
and access channel quantity for the LPU. This type of optical module is
mainly used in scenarios where one CSFP optical module connects to two
BIDI SFP optical modules. It is essential to ensure that the transmit and
receive wavelengths are consistent and the transmission distances are the
same.
● Classified by physical layer standards
Different physical layer standards are defined to allow data transmission in
different modes. Therefore, different types of optical modules are produced to
comply with these standards. For details, see Standards compliance of the
specific optical module.
● Classified by modes
Optical fibers are classified into single-mode and multimode fibers. Therefore,
optical modules are also classified into single-mode and multimode modules
to support different optical fibers.
– Single-mode optical modules are used with single-mode fibers. Single-
mode fibers support a wide band and large transmission capacity, and are
used for long-distance transmission.
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– Multimode optical modules are used with multimode fibers. Multimode
fibers have lower transmission performance than single-mode fibers
because of modal dispersion, but their costs are also lower. They are used
for small-capacity, short-distance transmission.
Wavelength division multiplexing modules differ from other optical modules in
center wavelengths. A common optical module has a center wavelength of 850
nm, 1310 nm, or 1550 nm, whereas a wavelength division multiplexing module
transmits lights with different center wavelengths. Wavelength division
multiplexing modules are classified into two types: coarse wavelength division
multiplexing (CWDM) and dense wavelength division multiplexing (DWDM).
Within the same band, DWDM modules are available in more types and use
wavelength resources more efficiently than CWDM modules. DWDM and CWDM
modules allow lights with different center wavelengths to be transmitted on one
fiber without interfering each other. Therefore, a passive multiplexer can be used
to combine the lights into one channel, which is then split into multiple channels
by a demultiplexer on the remote end. This reduces the optical fibers required.
DWDM and CWDM modules are used for long-distance transmission.
The transmit power of a long-distance optical module is often larger than its
overload power. Therefore, when using such optical modules, select optical fibers
of an appropriate length to ensure that the actual receive power is smaller than
the overload power. If the optical fibers connected to a long-distance optical
module are too short, use an optical attenuator to reduce the receive power on
the remote optical module. Otherwise, the remote optical module may be burnt.
3.4.1.3 Instruction
The following lists some common optical modules, which may not be supported
by this product. The figures are for reference only.
Table 3-53 Commonly used optical modules
Encaps Interface Appearance
ulatio type
n type
SFP LC Single-fiber-bidirectional transceiver
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Encaps Interface Appearance
ulatio type
n type
eSFP LC Two-fiber bidirectional
Single-fiber-bidirectional transceiver
SFP+ LC Two-fiber bidirectional
Single-fiber-bidirectional transceiver
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Encaps Interface Appearance
ulatio type
n type
XFP LC Two-fiber bidirectional
Single-fiber-bidirectional transceiver
SFP28 LC Two-fiber bidirectional
Single-fiber-bidirectional transceiver
QSFP2 LC/MPO Two-fiber bidirectional
8
Single-fiber-bidirectional transceiver
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Encaps Interface Appearance
ulatio type
n type
QSFP+ LC/MPO
CXP MPO
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Encaps Interface Appearance
ulatio type
n type
CFP LC/MPO CFP
CFP2
CFP4
CFP8
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Encaps Interface Appearance
ulatio type
n type
CSFP LC
QSFP- LC
DD
3.4.1.4 Instructions on How to Use an Optical Module
This section describes instructions on how to use an optical module.
NO TE
Only optical modules matching Huawei products can be used. These optical modules are
strictly tested by Huawei. If non-matching optical modules are used, device requirements
may fail to be met, and services may fail to run properly. To replace optical modules, see
Parts Replacement-Replacing an Optical Module.
ESD Measures
Before touching any optical module, wear an ESD wrist strap or ESD gloves. Take
full ESD measures when installing optical apparatus such as optical modules
indoors or outdoors.
Figure 3-21 Methods of wearing ESD gloves
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Figure 3-22 Methods of wearing an ESD wrist strap
Placing Optical Apparatus and Fibers
Do not touch pins or connecting fingers with bare hands. Handle the optical fibers
gently. Use two fingers to hold the fiber connector instead of grasping the fiber or
the fiber cover.
Do not apply axial or lateral fiber wallop bumps on the fiber. Do not fold, twist, or
crush the tail fiber. Do not drag the tail fiber or press the coupling point of the tail
fiber. Figure 3-23 shows how to properly place optical apparatus and fibers.
Figure 3-23 Methods of placing optical apparatus and fibers
NO TE
During installation, ensure that an optical fiber is coiled into a loop with a diameter of at
least 6 cm (0.20 ft).
Uninstalling Optical Apparatus
● Release the latch and slowly take out the optical apparatus. Do not drag the
optical fiber to forcibly take out the optical module. Ensure that the optical
fiber is connected to and removed from the optical interface horizontally.
Before taking out an optical module, remove its optical fiber and release its
latch first.
Figure 3-24 Closed latch
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Figure 3-25 Open latch
● The black plastic latch shown by (1) in Figure 3-26 is the unlocking device for
the 155 Mbit/s electrical interface optical module. Hold the two sides of the
optical module to remove it, as shown by (2) in Figure 3-26.
Figure 3-26 Removing a 155 Mbit/s electrical interface optical module
Do not remove the black plastic latch when removing the 155 Mbit/s
electrical interface optical module.
If the black plastic latch falls off, use an auxiliary tool, such as a pair of
tweezers, to press the cage buckle, as shown in the following figure. Then,
hold the two sides of the electrical interface optical module to remove it.
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● If the CFP2 optical module is used, its unlocking device is a spring clip, as
shown by (1) in Figure 3-27. Before removing such an optical module, release
the latch first.
Figure 3-27 Removing a CFP2 optical module
● When removing a CFP optical module, loosen the two screw rods of the
module and then remove the module slowly. Do not directly drag the optical
fiber to pull out the optical module or forcibly pull out the optical module.
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CA UTION
The QSFP28 and QSFP-DD modules will get very hot during operation. To
prevent injuries, do not touch the module shells when removing the modules.
Precautions for Loosened Optical Modules
● When installing an optical module, force it into position. If a crack sound is
heard or a slight tremor is felt, it indicates that the latch boss is secured.
When the latch boss is not secured, the connecting finger is unstably
connected to the connector on the board, and the link may become up. On
the condition that the optical module tremors or collides with another object,
however, the optical module will be loosened or the optical signals will be
temporarily cut off.
● When inserting the optical module, make sure that the tab is closed. (At this
time, the latch boss locks the optical module.) After the optical module is
inserted, try pulling it out to see if it is installed in position. If the optical
module cannot be pulled out, it is secured.
● If you cannot push the optical module into an optical module cage any
longer, the optical module is in good contact with the board connector.
● When installing a CFP optical module, push the module panel horizontally
into the connector using even force with both thumbs. After the module is
inserted, push the module slightly to ensure that it has reached the stop
position.
● After the CFP optical module is securely inserted, tighten the two screw rods
of the module alternately. To prevent the module from getting loosened due
to vibration or collision, you are advised to use a screwdriver to tighten the
screw rods.
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Precautions for Receptacle Contamination
● Clean tissues must be prepared for deployment on site. You need to clean the
optical connector before inserting it in the receptacle. This protects the
receptacle against the contamination.
NO TE
Use at least three cleaning tissues. Wipe the end of an optical connector horizontally
in one direction, and then move the connector end to the unused part of the cleaning
tissue to continue. Generally, one cleaning tissue is used for cleaning an optical
connector.
● To prevent contamination, the optical module should be covered with either a
dust cap or an optical connector.
Cover an optical module with a dust cap.
Cover an optical module with an optical connector
● Lay the optical fibers on the optical distribution frame (ODF) or coil them up
in a fiber management tray. Make sure that the optical fibers are not
squeezed.
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● If a receptacle or an optical connector has not been used for a long time and
has not been covered with a dust cap, you should clean it before using it. A
cotton swab is used to clean a receptacle, and a cleaning tissue is used to
clean an optical connector.
NO TE
During the cleaning process, insert the cotton swab and turn it slowly in the
receptacle. Do not use too much force, because the receptacle may be damaged.
● If, for no apparent reason, optical signals are lost during the operation of a
device, use the preceding method to clean the receptacle or the optical
connector. This will eliminate contamination as the cause of the signal loss.
Precautions for Overload-caused Burnt Optical Modules
● When using an OTDR to test the connectivity or the attenuation of optical
signals, disconnect the optical connector from the optical module. Otherwise,
the optical module may be burnt.
● When performing a self-loop test, use an optical attenuator. Do not loosen
the optical connector.
● It is required that a long-distance optical module have an input optical power
of less than -7 dBm. If the input optical power is larger than -7 dBm, you
need to add an optical attenuator. For example, if the transmitting optical
power is X dBm and the optical attenuation is Y dB, the receiving optical
power is X-Y, which must be smaller than -7dBm (X-Y<-7 dBm).
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Inspecting Optical Fiber Connectors
The Ethernet port rate is increasing and the quality requirement for optical fibers
and optical cables is higher. Table 3-54 describes requirements for the loss of
optical fiber connectors according to the national standard (GBT50312-2016).
Table 3-54 Maximum attenuation of the optical fiber connector
Type Maximum attenuation of an optical fiber
connector (dB)
Fiber splicing connector 0.3
Optical mechanical connector 0.3
Optical connector 0.75
NO TE
Fiber cores are connected through connectors, such as the ODF, optical attenuator, and
flange, in splicing and mechanical modes.
Table 3-55 describes requirements for the reflection of the optical fiber connector
when Ethernet ports (such as 200G and 50G) use PAM4 encoding to double the
rate. More connectors bring lower requirements for the reflection.
Table 3-55 Maximum reflection of connectors
Number of Optical Fiber Maximum Reflection of Each Connector
Connectors (dB)
1 -22
2 -29
4 -33
6 -35
8 -37
10 -39
The loss and reflection values of optical fiber connectors are tested and processed
as follows:
1. After the optical fiber at the peer end is disconnected, use the OTDR meter to
test the local end. Check whether the loss and reflection of each link and
node are normal. (The loss of a fiber splicing connector should be less than
0.3 dB, the loss of a connector should be less than 0.75 dB, and the reflection
of a connector should be less than -30 dB.) If the test result is not within the
required range, process the abnormal port.
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2. Locate the equipment room where the port resides based on the distance
between abnormal points in the OTDR test result. Preliminarily determine the
port location, disconnect the port, and perform an OTDR test on the port that
reports alarms. Check whether the distance is consistent with that in the
previous test. If not, continue to test other ports.
3. After the abnormal port is found, test the port using a fiber microscope. If the
port is dirty, clean it.
4. After the port is cleaned, restore the port, and ensure that the connector is
tightened. Perform an OTDR test on the port to check whether loss and
reflection of each link and node are normal.
5. If the fault persists, replace the flange and perform an OTDR test on the port
that reports alarms to check whether loss and reflection of each link and
node are normal.
6. If the fault persists, replace the optical fiber and perform an OTDR test on the
port that reports alarms to check whether loss and reflection of each link and
node are normal.
7. If multiple abnormal points exist on the link, repeat steps 2 to 6.
Other Precautions
● The optical connector should be horizontally inserted in the receptacle to
avoid damages to the receptacle.
● Mixed use of multi-mode and single-mode optical fibers is prohibited.
Otherwise, faults such as signal loss may occur.
Method of distinguishing optical modules in single mode and multi-mode.
Table 3-56 Method of distinguishing optical modules in single mode and
multi-mode
Item Single Mode Multi-mode
Transmission distance 10 km or longer Below 0.5 km
Wavelength Non-850 nm 850 nm
Information on the SM MM
label
50G Optical Module Installation Guide
1. Precautions for optical module installation
(1) If a cabinet with a door is used, a sufficient distance must be reserved between
the optical module and the cabinet door to prevent the puller or patch cord from
bumping on the door.
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(2) Long-distance optical modules must be equipped with optical attenuators for
self-loops. For a 50GBase-ER (40 km) long-distance optical module, the receive
optical power damage threshold is lower than the average minimum transmit
optical power, making the module prone to damage caused by self-loops.
Therefore, the module must be equipped with an optical attenuator for self-loops.
(3) When optical path quality is tested using an OTDR, optical fibers must be
removed from the associated optical module. This is because the OTDR's transmit
optical power is far greater than the optical power damage threshold at the
receive end of an optical module.
2. Method of checking an optical path
Figure 3-28 Method of checking an optical path
3. Method of cleaning the end faces of an optical fiber
Before cleaning the end faces of an optical fiber that is in use, ensure that the
optical fiber has no optical signals. To achieve this, shut down the ports at both
ends of the fiber. Then, clean the end faces and insert the optical fiber back into
the corresponding port.
To clean the end faces of an optical fiber that is not in use, remove the dust-proof
cap from the fiber connector (or the patch cord connector of the involved optical
component), and put the dust-proof cap into a dedicated cleaning kit. After the
cleaning is complete, re-install the dust-proof cap.
● Use the untouched part of a lint-free wipe to wipe the connector end face
along one direction.
● If the end face of an optical fiber cannot be cleaned due to serious
contamination, use a lint-free wipe dipped with cleanser to wipe the end face
along one direction. Then, use a dry lint-free wipe to clean the end face.
Ensure that the end face is dry before using the optical fiber.
● After the cleaning is complete, immediately install a dust-proof cap for any
optical fiber connector that is not in use.
4. Precautions for using a lint-free wipe to clean the end face of an optical
fiber
● Use a smooth surface of the lint-free wipe for cleaning.
● Ensure that the optical fiber connector is vertical to the lint-free wipe during
cleaning.
● Wipe the end face along the direction of the lint-free wipe's grain.
● Wipe the end face along one direction only.
● Any part of a lint-free wipe can be used only once, and a small piece of lint-
free wipe can be used to clean only one connector.
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5. Method of using lint-free swabs to clean the optical port of an optical
module
Remove the dust-proof cap from the optical port of the optical module, and put
the dust-proof cap into a dedicated cleaning kit.
● Select a proper lint-free swab based on the type of the optical port to be
cleaned. (For SC optical ports, use lint-free swabs with a diameter of 2.5 mm;
for LC and MTRJ optical ports, use lint-free swabs with a diameter of 1.25
mm.) Dip the lint-free swab into cleanser, insert it into the inside of the
optical port, and clean the optical port by rotating the swab 360 degrees in
one direction along the inner wall of the optical port.
● Insert a dry lint-free swab of the same type into the inside of the optical port
and clean the optical port by rotating the swab 360 degrees in one direction
along the inner wall of the optical port.
● Cap the optical port after the cleaning is complete.
6. Precautions for using lint-free swabs to clean the optical port of an optical
module
● When cleaning the optical port of an optical module, clean the end faces of
associated optical fibers to prevent the optical fibers from dirtying the optical
port.
● In general, each lint-free swab can be used for cleaning only once. If a used
lint-free swab is confirmed clean and can be reused, it can be used for a
maximum of three times. For example, a lint-free swab that is ever used to
dry an optical port can be used for a maximum of three times.
7. Safety precautions
● Electrostatic protection: Active optical and electrical components are
extremely sensitive to electrostatic. Therefore, take strict measures to protect
against electrostatic. For example, wear ESD gloves during operations and
touch only the shell of the involved component.
● Laser protection: Do not look into optical ports without eye protection when
reseating a module.
8. Discrete reflectance
Focus on the reflection indicators of each node during link deployment. The
discrete reflection indicators must meet the IEEE standards.
Table 3-57 Maximum discrete reflectance of QSFP28 50G defined by IEEE
Number of QSFP28 50G-FR QSFP28 50G-LR QSFP28 50G-ER
discrete (Maximum value (Maximum value (Maximum value
reflectances of each discrete of each discrete of each discrete
greater than –55 reflectance) reflectance) reflectance)
dB
1 -25 dB -22 dB -19 dB
2 -31 dB -29 dB -27 dB
4 -35 dB -33 dB -32 dB
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Number of QSFP28 50G-FR QSFP28 50G-LR QSFP28 50G-ER
discrete (Maximum value (Maximum value (Maximum value
reflectances of each discrete of each discrete of each discrete
greater than –55 reflectance) reflectance) reflectance)
dB
6 -38 dB -35 dB -35 dB
8 -40 dB -37 dB -37 dB
10 -41 dB -39 dB -39 dB
3.4.1.5 Configuring an Optical Attenuator
This section describes how to configure an optical attenuator.
Calculating the Optical Attenuation
You can calculate the optical attenuation based on the actual optical power.
Table 3-58 Description of parameters for calculating optical attenuation
Name Description
P(in)min Worst sensitivity.
P(out)max Maximum transmit optical power.
S Transmission distance.
A Attenuation coefficient. Note that the
attenuation coefficient is related to
optical fiber types and wavelengths. By
default, the attenuation coefficient of
a 1310-nm wavelength in a G.652
fiber is 0.45 dBm/km or 0.4 dBm/km;
the attenuation coefficient of a 1550-
nm wavelength in a G.652 fiber is
0.235 dBm/km or 0.25 dBm/km.
P(in)max Maximum receive optical power, that
is, minimum overload point.
The principle for determining whether an attenuator needs to be configured at a
transmission point is as follows:
If P(out)max – S x Attenuation coefficient > P(in)max, an attenuator needs to be
configured. The optical attenuation is calculated in the following formula: T=
P(out)max - S x Attenuation coefficient - P(in)max.
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Table 3-59 Reference for configuring an attenuator
BOM Descriptio P(out) P(out) P(in) P(in)
Number n max min min max
34060276 eSFP,1310n -8 dBm -15 dBm -31 dBm -8 dBm
m,STM1,LC
,SM,15km
NO TE
● If P(in)max of an optical module equals P(out)max, you do not need to configure an
attenuator.
● You can choose the 5 dBm and 10 dBm attenuators for optical modules on the device.
BOM Number and Description of Attenuators
Table 3-60 BOM number and description of attenuators
BOM Number Description
45030021 Fixed Optical
Attenuator,1260nm~1620nm-5dB-LC/
PC-45dB
45030022 Fixed Optical
Attenuator,1260nm~1620nm-10dB-LC/
PC-45dB
NO TE
This table is for reference only. BOM numbers of attenuators vary with configuration
documents.
3.4.2 155Mbps eSFP Optical Module
3.4.2.1 155Mbps-eSFP-SMF-1550nm-80km-commercial
Table 3-61 155Mbps-eSFP-SMF-1550nm-80km-commercial specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1550nm-80km-
commercial
Part Number 34060282
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Item Value
Model eSFP-FE-LH80-SM1550
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1480 nm - 1580 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1263 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -34 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -10 dBm
Overload power (OMA) [dBm] -
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3.4.2.2 155Mbps-eSFP-SMF-1310nm-15km-industry
Table 3-62 155Mbps-eSFP-SMF-1310nm-15km-industry specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1310nm-15km-
industry
Part Number 34060307
Model eSFP-1310nm-I-1
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 15 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1261 nm - 1360 nm
Maximum Tx optical power (AVG) -8 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -15 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -31 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.2.3 155Mbps-eSFP-SMF-1310nm-40km-industry
Table 3-63 155Mbps-eSFP-SMF-1310nm-40km-industry specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1310nm-40km-
industry
Part Number 34060308
Model eSFP-1310nm-L-1.1
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1263 nm - 1360 nm
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Item Value
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1263 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -34 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -10 dBm
Overload power (OMA) [dBm] -
3.4.2.4 155Mbps-eSFP-SMF-1550nm-80km-industry
Table 3-64 155Mbps-eSFP-SMF-1550nm-80km-industry specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1550nm-80km-
industry
Part Number 34060309
Model eSFP-1550nm-L-1.2
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
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Item Value
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1480 nm - 1580 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1263 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -34 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -10 dBm
Overload power (OMA) [dBm] -
3.4.2.5 155Mbps-eSFP-SMF-1310nm-40km-commercial
Table 3-65 155Mbps-eSFP-SMF-1310nm-40km-commercial specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1310nm-40km-
commercial
Part Number S4015715
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Item Value
Model eSFP-FE-LH40-SM1310
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1263 nm - 1360 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1263 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -34 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -10 dBm
Overload power (OMA) [dBm] -10 dBm
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3.4.2.6 155Mbps-eSFP-MMF-1310nm-2km-commercial
Table 3-66 155Mbps-eSFP-MMF-1310nm-2km-commercial specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-MMF-1310nm-2km-
commercial
Part Number S4015731
Model SFP-FE-SX-MM1310
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options -
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 2 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1270 nm - 1380 nm
Maximum Tx optical power (AVG) -14 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -19 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1270 nm - 1380 nm
Rx sensitivity (AVG) [dBm] -30 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -14 dBm
Overload power (OMA) [dBm] -14 dBm
3.4.2.7 155Mbps-eSFP-SMF-1310nm-15km-commercial
Table 3-67 155Mbps-eSFP-SMF-1310nm-15km-commercial specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1310nm-15km-
commercial
Part Number S4015755
Model eSFP-FE-LX-SM1310
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 15 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1261 nm - 1360 nm
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Item Value
Maximum Tx optical power (AVG) -8 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -15 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -8 dBm
3.4.3 155Mbps eSFP BIDI Optical Module
3.4.3.1 155Mbps-eSFP-SM-1310nm(Tx)/1550nm(Rx)-15km-commercial
Table 3-68 155Mbps-eSFP-SM-1310nm(Tx)/1550nm(Rx)-15km-commercial
specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SM-1310nm(Tx)/
1550nm(Rx)-15km-commercial
Part Number 02310QNG
Model OSC015B01
Form factor eSFP
Application standard IEEE 802.3, 100BASE-BX10-U
Connector type LC
Optical fiber type SMF
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Item Value
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 15 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) -8 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -14 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -32 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.3.2 155Mbps-eSFP-SM-1550nm(Tx)/1310nm(Rx)-15km-commercial
Table 3-69 155Mbps-eSFP-SM-1550nm(Tx)/1310nm(Rx)-15km-commercial
specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SM-1550nm(Tx)/
1310nm(Rx)-15km-commercial
Part Number 02310QNH
Model OSC015B02
Form factor eSFP
Application standard IEEE 802.3, 100BASE-BX10-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 15 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1480 nm - 1580 nm
Maximum Tx optical power (AVG) -8 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -14 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
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Item Value
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -32 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.4 1Gbps Electrical Module
3.4.4.1 1Gbps-SFP-100m-industry (02310RAV)
Table 3-70 1Gbps-SFP-100m-industry specifications
Item Value
Basic Information
Module name 1Gbps-SFP-100m-industry
Part Number 02310RAV
Model OEGD01N01
Form factor SFP
Application standard IEEE 802.3, 1000Base-T
Connector type RJ45
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 10 Mbit/s
100 Mbit/s
1000 Mbit/s
Target transmission distance [km] 0.1 km
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3.4.4.2 1Gbps-SFP-100m-industry (02310VPT)
Table 3-71 1Gbps-SFP-100m-industry specifications
Item Value
Basic Information
Module name 1Gbps-SFP-100m-industry
Part Number 02310VPT
Model OEGD01N02
Form factor SFP
Application standard IEEE 802.3, 1000Base-T
Connector type RJ45
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 10 Mbit/s
100 Mbit/s
1000 Mbit/s
Target transmission distance [km] 0.1 km
3.4.4.3 1Gbps-SFP-100m-industry (02314FNP)
Table 3-72 1Gbps-SFP-100m-industry specifications
Item Value
Basic Information
Module name 1Gbps-SFP-100m-industry
Part Number 02314FNP
Model OEGD01N03
Form factor SFP
Application standard IEEE 802.3, 1000Base-T
Connector type RJ45
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Item Value
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 10 Mbit/s
100 Mbit/s
1000 Mbit/s
Target transmission distance [km] 0.1 km
3.4.5 1.25Gbps eSFP Optical Module
3.4.5.1 1.25Gbps-eSFP-MMF-850nm-500m-extended
Table 3-73 1.25Gbps-eSFP-MMF-850nm-500m-extended specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-MMF-850nm-500m-
extended
Part Number 34060286
Model eSFP-850nm-1000Base-Sx/FC200 MM
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-SX
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] -20°C to 85°C(-4°F to 185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 0.5 km(OM1)
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 770 nm - 860 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9.5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 760 nm - 860 nm
Rx sensitivity (AVG) [dBm] -17 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 0 dBm
Overload power (OMA) [dBm] -
3.4.5.2 1.25Gbps-eSFP-SMF-1310nm-10km-industry
Table 3-74 1.25Gbps-eSFP-SMF-1310nm-10km-industry specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm-10km-
industry
Part Number 34060290
Model eSFP(S)-1310nm-1000Base-Lx
Form factor eSFP
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Item Value
Application standard IEEE 802.3, 1000BASE-LX10
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) -3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -19 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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3.4.5.3 1.25Gbps-eSFP-SMF-1310nm-40km-industry
Table 3-75 1.25Gbps-eSFP-SMF-1310nm-40km-industry specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm-40km-
industry
Part Number 34060320
Model eSFP-1310nm-Lx-40Km
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-EX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1275 nm - 1350 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1275 nm - 1350 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
3.4.5.4 1.25Gbps-eSFP-MMF-850nm-500m-industry
Table 3-76 1.25Gbps-eSFP-MMF-850nm-500m-industry specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-MMF-850nm-500m-
industry
Part Number 34060321
Model eSFP-850nm-1000Base-Sx
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-SX
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 0.5 km
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 770 nm - 860 nm
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Item Value
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9.5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 760 nm - 860 nm
Rx sensitivity (AVG) [dBm] -17 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 0 dBm
Overload power (OMA) [dBm] -
3.4.5.5 1.25Gbps-eSFP-SMF-1550nm-80km-commercial
Table 3-77 1.25Gbps-eSFP-SMF-1550nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1550nm-80km-
commercial
Part Number 34060360
Model eSFP-1550nm-1000Base-Zx/FC100
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-ZX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
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Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1500 nm - 1580 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
The interface standard is Huawei-specific.
3.4.5.6 1.25Gbps-eSFP-SMF-1310nm-10km-commercial
Table 3-78 1.25Gbps-eSFP-SMF-1310nm-10km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm-10km-
commercial
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Item Value
Part Number S4016067
Model OSG010N05
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-LX10
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1270 nm - 1355 nm
Maximum Tx optical power (AVG) -3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1270 nm - 1355 nm
Rx sensitivity (AVG) [dBm] -20 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -3 dBm
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3.4.5.7 1.25Gbps-eSFP-SMF-1310nm-40km-commercial
Table 3-79 1.25Gbps-eSFP-SMF-1310nm-40km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm-40km-
commercial
Part Number S4016954
Model OSG040002
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-EX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1275 nm - 1350 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
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Item Value
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -3 dBm
3.4.5.8 1.25Gbps-eSFP-SMF-1550nm-100km-commercial
Table 3-80 1.25Gbps-eSFP-SMF-1550nm-100km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1550nm-100km-
commercial
Part Number 34060295
Model eSFP-GE-ZX100-SM1550
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-ZX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 100 km
Transmitter Optical Characteristics
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Item Value
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1500 nm - 1580 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -30 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
NOTE
The interface standard is Huawei-specific.
3.4.6 1.25Gbps eSFP BIDI Optical Module
3.4.6.1 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-10km-
commercial(34060470)
Table 3-81 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-10km-
commercial(34060470) specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm(Tx)/
1490nm(Rx)-10km-
commercial(34060470)
Part Number 34060470
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Item Value
Model SFP-GE-LX-SM1310-BIDI
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX10-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) -3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1500 nm
Rx sensitivity (AVG) [dBm] -19.5 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
Used in pair with 34060475.
3.4.6.2 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-10km-commercial
Table 3-82 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1490nm(Tx)/
1310nm(Rx)-10km-commercial
Part Number 34060475
Model SFP-GE-LX-SM1490-BIDI
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX10-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1490 nm
Tx operating wavelength range [nm] 1480 nm - 1500 nm
Maximum Tx optical power (AVG) -3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
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Item Value
Minimum Tx optical power (AVG) -9 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -19.5 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
Used in pair with 34060470.
3.4.6.3 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-40km-commercial
Table 3-83 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm(Tx)/
1490nm(Rx)-40km-commercial
Part Number 34060539
Model OGEBIDI41
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX40-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) 3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1500 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -23 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
Used in pair with 34060540.
3.4.6.4 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-40km-commercial
Table 3-84 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1490nm(Tx)/
1310nm(Rx)-40km-commercial
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Item Value
Part Number 34060540
Model OGEBIDI40
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX40-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1490 nm
Tx operating wavelength range [nm] 1480 nm - 1500 nm
Maximum Tx optical power (AVG) 3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -23 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
Used in pair with 34060539.
3.4.6.5 1.25Gbps-eSFP-SMF-1570nm(Tx)/1490nm(Rx)-80km-commercial
Table 3-85 1.25Gbps-eSFP-SMF-1570nm(Tx)/1490nm(Rx)-80km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1570nm(Tx)/
1490nm(Rx)-80km-commercial
Part Number 34060595
Model OGEBIDI80
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX80-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1570 nm
Tx operating wavelength range [nm] 1560 nm - 1580 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
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Item Value
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1500 nm
Rx sensitivity (AVG) [dBm] -26 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
Used in pair with 34060596.
3.4.6.6 1.25Gbps-eSFP-SMF-1490nm(Tx)/1570nm(Rx)-80km-commercial
Table 3-86 1.25Gbps-eSFP-SMF-1490nm(Tx)/1570nm(Rx)-80km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1490nm(Tx)/
1570nm(Rx)-80km-commercial
Part Number 34060596
Model OGEBIDI81
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX80-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1490 nm
Tx operating wavelength range [nm] 1480 nm - 1500 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1560 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -26 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
Used in pair with 34060595.
3.4.6.7 0.1~1.25Gbps-eSFP-SMF-1310nm(Tx)/1550nm(Rx)-40km-commercial
Table 3-87 0.1~1.25Gbps-eSFP-SMF-1310nm(Tx)/1550nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 0.1~1.25Gbps-eSFP-SMF-1310nm(Tx)/
1550nm(Rx)-40km-commercial
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Item Value
Part Number 34060638
Model eSFP-1310/1550-L1.1-BIDI
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX40-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] -5°C to 70°C(23°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 0.1~1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -3 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -25 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
When an optical module is used on the OptiX PTN equipment, the rate of the optical
module cannot exceed 155 Mbit/s.
3.4.6.8 0.1~1.25Gbps-eSFP-SMF-1550nm(Tx)/1310nm(Rx)-40km-commercial
Table 3-88 0.1~1.25Gbps-eSFP-SMF-1550nm(Tx)/1310nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 0.1~1.25Gbps-eSFP-SMF-1550nm(Tx)/
1310nm(Rx)-40km-commercial
Part Number 34060639
Model eSFP-1550/1310-L1.1-BIDI
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX40-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] -5°C to 70°C(23°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 0.1~1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1580 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
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Item Value
Minimum Tx optical power (AVG) -3 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -25 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
When an optical module is used on the OptiX PTN equipment, the rate of the optical
module cannot exceed 155 Mbit/s.
3.4.6.9 1.25Gbps-eSFP-SMF-1550nm(Tx)/1490nm(Rx)-80km-commercial
Table 3-89 1.25Gbps-eSFP-SMF-1550nm(Tx)/1490nm(Rx)-80km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1550nm(Tx)/
1490nm(Rx)-80km-commercial
Part Number 02314RDH
Model SFP-GE-BIDI-80km-SM1550
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX80-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
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Security standard TUV; EN 60825-1, EN 62368-1;
NRTL: CAN/CSA C22.2 NO.62368-1-12
* UL 62368-1;
FDA: 21CFR 1040.10 and 1040.11,
Notice NO.56.
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1540 nm - 1560 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1500 nm
Rx sensitivity (AVG) [dBm] -26 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
It is used with 02314RDK in pairs.
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3.4.6.10 1.25Gbps-eSFP-SMF-1490nm(Tx)/1550nm(Rx)-80km-commercial
Table 3-90 1.25Gbps-eSFP-SMF-1490nm(Tx)/1550nm(Rx)-80km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1490nm(Tx)/
1550nm(Rx)-80km-commercial
Part Number 02314RDK
Model SFP-GE-BIDI-80km-SM1490
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX80-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C (32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard TUV; EN 60825-1, EN 62368-1;
NRTL: CAN/CSA C22.2 NO.62368-1-12
* UL 62368-1;
FDA: 21CFR 1040.10 and 1040.11,
Notice NO.56.
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1490 nm
Tx operating wavelength range [nm] 1480 nm - 1500 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
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Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1540 nm - 1560 nm
Rx sensitivity (AVG) [dBm] -26 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
It is used with 02314RDH in pairs.
3.4.7 1.25Gbps eSFP CWDM Optical Module
3.4.7.1 1.25Gbps-eSFP-SMF-1571nm-80km-commercial
Table 3-91 1.25Gbps-eSFP-SMF-1571nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1571nm-80km-
commercial
Part Number 34060476
Model eSFP-LH80-SM1571
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1571 nm
Tx operating wavelength range [nm] 1564.5 nm - 1577.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.2 1.25Gbps-eSFP-SMF-1591nm-80km-commercial
Table 3-92 1.25Gbps-eSFP-SMF-1591nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1591nm-80km-
commercial
Part Number 34060477
Model eSFP-LH80-SM1591
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Item Value
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1591 nm
Tx operating wavelength range [nm] 1584.5 nm - 1597.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
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3.4.7.3 1.25Gbps-eSFP-SMF-1551nm-80km-commercial
Table 3-93 1.25Gbps-eSFP-SMF-1551nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1551nm-80km-
commercial
Part Number 34060478
Model eSFP-LH80-SM1551
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1551 nm
Tx operating wavelength range [nm] 1544.5 nm - 1557.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.4 1.25Gbps-eSFP-SMF-1511nm-80km-commercial
Table 3-94 1.25Gbps-eSFP-SMF-1511nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1511nm-80km-
commercial
Part Number 34060479
Model eSFP-LH80-SM1511
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1511 nm
Tx operating wavelength range [nm] 1504.5 nm - 1517.5 nm
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Item Value
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.5 1.25Gbps-eSFP-SMF-1611nm-80km-commercial
Table 3-95 1.25Gbps-eSFP-SMF-1611nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1611nm-80km-
commercial
Part Number 34060480
Model eSFP-LH80-SM1611
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
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Item Value
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1611 nm
Tx operating wavelength range [nm] 1604.5 nm - 1617.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.6 1.25Gbps-eSFP-SMF-1491nm-80km-commercial
Table 3-96 1.25Gbps-eSFP-SMF-1491nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1491nm-80km-
commercial
Part Number 34060481
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Hardware Guide 3 Hardware Description
Item Value
Model eSFP-LH80-SM1491
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1491 nm
Tx operating wavelength range [nm] 1484.5 nm - 1497.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
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3.4.7.7 1.25Gbps-eSFP-SMF-1531nm-80km-commercial
Table 3-97 1.25Gbps-eSFP-SMF-1531nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1531nm-80km-
commercial
Part Number 34060482
Model eSFP-LH80-SM1531
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1531 nm
Tx operating wavelength range [nm] 1524.5 nm - 1537.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.8 1.25Gbps-eSFP-SMF-1471nm-80km-commercial
Table 3-98 1.25Gbps-eSFP-SMF-1471nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1471nm-80km-
commercial
Part Number 34060483
Model eSFP-LH80-SM1471
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1471 nm
Tx operating wavelength range [nm] 1464.5 nm - 1477.5 nm
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Item Value
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.8 125M~2.67Gbps eSFP DWDM Optical Module
3.4.8.1 125M~2.67Gbps-eSFP-SMF-1560.61nm-120km-commercial
Table 3-99 125M~2.67Gbps-eSFP-SMF-1560.61nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1560.61nm-120km-commercial
Part Number 34060366
Model eSFP-LH120-SM192.10
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
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Item Value
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1560.61 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.2 125M~2.67Gbps-eSFP-SMF-1559.79nm-120km-commercial
Table 3-100 125M~2.67Gbps-eSFP-SMF-1559.79nm-120km-commercial
specifications
Item Value
Basic Information
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Hardware Guide 3 Hardware Description
Item Value
Module name 125M~2.67Gbps-eSFP-
SMF-1559.79nm-120km-commercial
Part Number 34060372
Model eSFP-LH120-SM192.20
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1559.79 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
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Item Value
Overload power (OMA) [dBm] -
3.4.8.3 125M~2.67Gbps-eSFP-SMF-1558.98nm-120km-commercial
Table 3-101 125M~2.67Gbps-eSFP-SMF-1558.98nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1558.98nm-120km-commercial
Part Number 34060373
Model eSFP-LH120-SM192.30
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1558.98 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
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Item Value
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.4 125M~2.67Gbps-eSFP-SMF-1558.17nm-120km-commercial
Table 3-102 125M~2.67Gbps-eSFP-SMF-1558.17nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1558.17nm-120km-commercial
Part Number 34060374
Model eSFP-LH120-SM192.40
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
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Hardware Guide 3 Hardware Description
Item Value
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1558.17 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.5 125M~2.67Gbps-eSFP-SMF-1557.36nm-120km-commercial
Table 3-103 125M~2.67Gbps-eSFP-SMF-1557.36nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1557.36nm-120km-commercial
Part Number 34060375
Model eSFP-LH120-SM192.50
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
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Hardware Guide 3 Hardware Description
Item Value
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1557.36 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.6 125M~2.67Gbps-eSFP-SMF-1556.55nm-120km-commercial
Table 3-104 125M~2.67Gbps-eSFP-SMF-1556.55nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1556.55nm-120km-commercial
Part Number 34060376
Model eSFP-LH120-SM192.60
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1556.55 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.7 125M~2.67Gbps-eSFP-SMF-1555.75nm-120km-commercial
Table 3-105 125M~2.67Gbps-eSFP-SMF-1555.75nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1555.75nm-120km-commercial
Part Number 34060377
Model eSFP-LH120-SM192.70
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1555.75 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.8 125M~2.67Gbps-eSFP-SMF-1554.94nm-120km-commercial
Table 3-106 125M~2.67Gbps-eSFP-SMF-1554.94nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1554.94nm-120km-commercial
Part Number 34060378
Model eSFP-LH120-SM192.80
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1554.94 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.9 125M~2.67Gbps-eSFP-SMF-1554.13nm-120km-commercial
Table 3-107 125M~2.67Gbps-eSFP-SMF-1554.13nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1554.13nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060379
Model eSFP-LH120-SM192.90
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1554.13 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.10 125M~2.67Gbps-eSFP-SMF-1553.33nm-120km-commercial
Table 3-108 125M~2.67Gbps-eSFP-SMF-1553.33nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1553.33nm-120km-commercial
Part Number 34060380
Model eSFP-LH120-SM193.00
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1553.33 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.11 125M~2.67Gbps-eSFP-SMF-1552.52nm-120km-commercial
Table 3-109 125M~2.67Gbps-eSFP-SMF-1552.52nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1552.52nm-120km-commercial
Part Number 34060381
Model eSFP-LH120-SM193.10
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1552.52 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.12 125M~2.67Gbps-eSFP-SMF-1551.72nm-120km-commercial
Table 3-110 125M~2.67Gbps-eSFP-SMF-1551.72nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1551.72nm-120km-commercial
Part Number 34060382
Model eSFP-LH120-SM193.20
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1551.72 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.13 125M~2.67Gbps-eSFP-SMF-1550.92nm-120km-commercial
Table 3-111 125M~2.67Gbps-eSFP-SMF-1550.92nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1550.92nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060383
Model eSFP-LH120-SM193.30
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550.92 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.14 125M~2.67Gbps-eSFP-SMF-1550.12nm-120km-commercial
Table 3-112 125M~2.67Gbps-eSFP-SMF-1550.12nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1550.12nm-120km-commercial
Part Number 34060384
Model eSFP-LH120-SM193.40
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550.12 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.15 125M~2.67Gbps-eSFP-SMF-1549.32nm-120km-commercial
Table 3-113 125M~2.67Gbps-eSFP-SMF-1549.32nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1549.32nm-120km-commercial
Part Number 34060385
Model eSFP-LH120-SM193.50
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1549.32 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.16 125M~2.67Gbps-eSFP-SMF-1548.51nm-120km-commercial
Table 3-114 125M~2.67Gbps-eSFP-SMF-1548.51nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1548.51nm-120km-commercial
Part Number 34060386
Model eSFP-LH120-SM193.60
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1548.51 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.17 125M~2.67Gbps-eSFP-SMF-1547.72nm-120km-commercial
Table 3-115 125M~2.67Gbps-eSFP-SMF-1547.72nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1547.72nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060387
Model eSFP-LH120-SM193.70
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1547.72 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.18 125M~2.67Gbps-eSFP-SMF-1546.92nm-120km-commercial
Table 3-116 125M~2.67Gbps-eSFP-SMF-1546.92nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1546.92nm-120km-commercial
Part Number 34060388
Model eSFP-LH120-SM193.80
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1546.92 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.19 125M~2.67Gbps-eSFP-SMF-1546.12nm-120km-commercial
Table 3-117 125M~2.67Gbps-eSFP-SMF-1546.12nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1546.12nm-120km-commercial
Part Number 34060389
Model eSFP-LH120-SM193.90
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1546.12 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.20 125M~2.67Gbps-eSFP-SMF-1545.32nm-120km-commercial
Table 3-118 125M~2.67Gbps-eSFP-SMF-1545.32nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1545.32nm-120km-commercial
Part Number 34060390
Model eSFP-LH120-SM194.00
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1545.32 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.21 125M~2.67Gbps-eSFP-SMF-1544.53nm-120km-commercial
Table 3-119 125M~2.67Gbps-eSFP-SMF-1544.53nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1544.53nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060391
Model eSFP-LH120-SM194.10
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1544.53 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.22 125M~2.67Gbps-eSFP-SMF-1543.73nm-120km-commercial
Table 3-120 125M~2.67Gbps-eSFP-SMF-1543.73nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1543.73nm-120km-commercial
Part Number 34060392
Model eSFP-LH120-SM194.20
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1543.73 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.23 125M~2.67Gbps-eSFP-SMF-1542.94nm-120km-commercial
Table 3-121 125M~2.67Gbps-eSFP-SMF-1542.94nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1542.94nm-120km-commercial
Part Number 34060393
Model eSFP-LH120-SM194.30
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1542.94 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.24 125M~2.67Gbps-eSFP-SMF-1542.14nm-120km-commercial
Table 3-122 125M~2.67Gbps-eSFP-SMF-1542.14nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1542.14nm-120km-commercial
Part Number 34060394
Model eSFP-LH120-SM194.40
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1542.14 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.25 125M~2.67Gbps-eSFP-SMF-1541.35nm-120km-commercial
Table 3-123 125M~2.67Gbps-eSFP-SMF-1541.35nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1541.35nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060395
Model eSFP-LH120-SM194.50
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1541.35 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.26 125M~2.67Gbps-eSFP-SMF-1540.56nm-120km-commercial
Table 3-124 125M~2.67Gbps-eSFP-SMF-1540.56nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1540.56nm-120km-commercial
Part Number 34060396
Model eSFP-LH120-SM194.60
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1540.56 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.27 125M~2.67Gbps-eSFP-SMF-1539.77nm-120km-commercial
Table 3-125 125M~2.67Gbps-eSFP-SMF-1539.77nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1539.77nm-120km-commercial
Part Number 34060397
Model eSFP-LH120-SM194.70
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1539.77 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.28 125M~2.67Gbps-eSFP-SMF-1538.98nm-120km-commercial
Table 3-126 125M~2.67Gbps-eSFP-SMF-1538.98nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1538.98nm-120km-commercial
Part Number 34060398
Model eSFP-LH120-SM194.80
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1538.98 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.29 125M~2.67Gbps-eSFP-SMF-1538.19nm-120km-commercial
Table 3-127 125M~2.67Gbps-eSFP-SMF-1538.19nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1538.19nm-120km-commercial
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Value
Part Number 34060399
Model eSFP-LH120-SM194.90
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1538.19 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.30 125M~2.67Gbps-eSFP-SMF-1537.40nm-120km-commercial
Table 3-128 125M~2.67Gbps-eSFP-SMF-1537.40nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1537.40nm-120km-commercial
Part Number 34060400
Model eSFP-LH120-SM195.00
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1537.4 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.31 125M~2.67Gbps-eSFP-SMF-1536.61nm-120km-commercial
Table 3-129 125M~2.67Gbps-eSFP-SMF-1536.61nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1536.61nm-120km-commercial
Part Number 34060401
Model eSFP-LH120-SM195.10
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1536.61 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.32 125M~2.67Gbps-eSFP-SMF-1535.82nm-120km-commercial
Table 3-130 125M~2.67Gbps-eSFP-SMF-1535.82nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1535.82nm-120km-commercial
Part Number 34060402
Model eSFP-LH120-SM195.20
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1535.82 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.33 125M~2.67Gbps-eSFP-SMF-1535.04nm-120km-commercial
Table 3-131 125M~2.67Gbps-eSFP-SMF-1535.04nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1535.04nm-120km-commercial
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Value
Part Number 34060403
Model eSFP-LH120-SM195.30
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1535.04 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.34 125M~2.67Gbps-eSFP-SMF-1534.25nm-120km-commercial
Table 3-132 125M~2.67Gbps-eSFP-SMF-1534.25nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1534.25nm-120km-commercial
Part Number 34060404
Model eSFP-LH120-SM195.40
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1534.25 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.35 125M~2.67Gbps-eSFP-SMF-1533.47nm-120km-commercial
Table 3-133 125M~2.67Gbps-eSFP-SMF-1533.47nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1533.47nm-120km-commercial
Part Number 34060405
Model eSFP-LH120-SM195.50
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1533.47 nm
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Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.36 125M~2.67Gbps-eSFP-SMF-1532.68nm-120km-commercial
Table 3-134 125M~2.67Gbps-eSFP-SMF-1532.68nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1532.68nm-120km-commercial
Part Number 34060406
Model eSFP-LH120-SM195.60
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1532.68 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.37 125M~2.67Gbps-eSFP-SMF-1531.90nm-120km-commercial
Table 3-135 125M~2.67Gbps-eSFP-SMF-1531.90nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1531.90nm-120km-commercial
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Item Value
Part Number 34060407
Model eSFP-LH120-SM195.70
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1531.9 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.38 125M~2.67Gbps-eSFP-SMF-1531.12nm-120km-commercial
Table 3-136 125M~2.67Gbps-eSFP-SMF-1531.12nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1531.12nm-120km-commercial
Part Number 34060408
Model eSFP-LH120-SM195.80
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1531.12 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.39 125M~2.67Gbps-eSFP-SMF-1530.33nm-120km-commercial
Table 3-137 125M~2.67Gbps-eSFP-SMF-1530.33nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1530.33nm-120km-commercial
Part Number 34060409
Model eSFP-LH120-SM195.90
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1530.33 nm
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Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.40 125M~2.67Gbps-eSFP-SMF-1529.55nm-120km-commercial
Table 3-138 125M~2.67Gbps-eSFP-SMF-1529.55nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1529.55nm-120km-commercial
Part Number 34060410
Model eSFP-LH120-SM196.00
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1529.55 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.9 10Gbps SFP+ Optical Module
3.4.9.1 10Gbps-SFP+-SMF-1550nm-80km-commercial
Table 3-139 10Gbps-SFP+-SMF-1550nm-80km-commercial specifications
Item Value
Basic Information
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Item Value
Module name 10Gbps-SFP+-SMF-1550nm-80km-
commercial
Part Number 02310PVU
Model OSX080N04
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ZR/ZW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1565 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1565 nm
Rx sensitivity (AVG) [dBm] -24 dBm
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Item Value
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
NOTE
The interface standard is Huawei-specific. Self-loop is not supported. An optical attenuator
must be added if self-loop is required.
3.4.9.2 10Gbps-SFP+-SMF-1310nm-10km-industry
Table 3-140 10Gbps-SFP+-SMF-1310nm-10km-industry specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1310nm-10km-
industry
Part Number 34060599
Model OSX010N05
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-LR/LW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1355 nm
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Item Value
Maximum Tx optical power (AVG) 0.5 dBm
[dBm]
Maximum Tx optical power (OMA) -5.2 dBm
[dBm]
Minimum Tx optical power (AVG) -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1355 nm
Rx sensitivity (AVG) [dBm] -14.4 dBm
Rx sensitivity (OMA) [dBm] -12.6 dBm
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] -
3.4.9.3 10Gbps-SFP+-SMF-1550nm-40km-industry
Table 3-141 10Gbps-SFP+-SMF-1550nm-40km-industry specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1550nm-40km-
industry
Part Number 34060684
Model OSX040N05
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
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Item Value
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1565 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -1.7 dBm
[dBm]
Minimum Tx optical power (AVG) -4.7 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1530 nm - 1565 nm
Rx sensitivity (AVG) [dBm] -15.8 dBm
Rx sensitivity (OMA) [dBm] -14.1 dBm
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -
NOTE
Self-loop is not supported. An optical attenuator must be added if self-loop is required.
3.4.9.4 10Gbps-SFP+-MMF-850nm-0.3km-commercial
Table 3-142 10Gbps-SFP+-MMF-850nm-0.3km-commercial specifications
Item Value
Basic Information
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Hardware Guide 3 Hardware Description
Item Value
Module name 10Gbps-SFP+-MMF-850nm-0.3km-
commercial
Part Number S4017482
Model OSX040N03
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-SR/SW
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 0.3 km(OM3)
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) -1 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -7.3 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -9.9 dBm
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Item Value
Rx sensitivity (OMA) [dBm] -11.1 dBm
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -1 dBm
3.4.9.5 10Gbps-SFP+-SMF-1310nm-10km-commercial
Table 3-143 10Gbps-SFP+-SMF-1310nm-10km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1310nm-10km-
commercial
Part Number S4017483
Model OSX001002
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-LR/LW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1355 nm
Maximum Tx optical power (AVG) 0.5 dBm
[dBm]
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Item Value
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1355 nm
Rx sensitivity (AVG) [dBm] -14.4 dBm
Rx sensitivity (OMA) [dBm] -12.6 dBm
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] 0.5 dBm
3.4.9.6 10Gbps-SFP+-SMF-1550nm-40km-commercial
Table 3-144 10Gbps-SFP+-SMF-1550nm-40km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1550nm-40km-
commercial
Part Number S4017484
Model OMXD30002
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1565 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -4.7 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1530 nm - 1565 nm
Rx sensitivity (AVG) [dBm] -15.8 dBm
Rx sensitivity (OMA) [dBm] -14.1 dBm
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -1 dBm
NOTE
Self-loop is not supported. An optical attenuator must be added if self-loop is required.
3.4.10 1.25/9.953/10.3125Gbps SFP+ Optical Module
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3.4.10.1 1.25/9.953/10.3125Gbps-SFP+-SMF-1310nm-10km-commercial
Table 3-145 1.25/9.953/10.3125Gbps-SFP+-SMF-1310nm-10km-commercial
specifications
Item Value
Basic Information
Module name 1.25/9.953/10.3125Gbps-SFP+-
SMF-1310nm-10km-commercial
Part Number 34061042
Model OSX010N13
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-LR/LW,
1000BASE-LX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] GE: 10 km
10GE: 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) GE: 0.5 dBm
[dBm] 10GE: 0.5 dBm
Maximum Tx optical power (OMA) -
[dBm]
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Item Value
Minimum Tx optical power (AVG) GE: -8.2 dBm
[dBm] 10GE: -8.2 dBm
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] GE: 9 dB
10GE: 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] GE: -19 dBm
10GE: -14.4 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] 0.5 dBm
3.4.10.2 1.25/9.953/10.3125Gbps-SFP+-SMF-1550nm-40km-commercial
Table 3-146 1.25/9.953/10.3125Gbps-SFP+-SMF-1550nm-40km-commercial
specifications
Item Value
Basic Information
Module name 1.25/9.953/10.3125Gbps-SFP+-
SMF-1550nm-40km-commercial
Part Number 34061043
Model OSX040N12
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW,
1000BASE-LX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
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Item Value
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] GE: 40 km
10GE: 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1565 nm
Maximum Tx optical power (AVG) GE: 4 dBm
[dBm] 10GE: 4 dBm
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) GE: -4.7 dBm
[dBm] 10GE: -4.7 dBm
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] GE: 9 dB
10GE: 3.0 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1530 nm - 1565 nm
Rx sensitivity (AVG) [dBm] GE: -15.8 dBm
10GE: -15.8 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -1 dBm
3.4.11 10Gbps SFP+ CWDM Optical Module
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3.4.11.1 10Gbps-SFP+-SMF-1511nm-70km-commercial
Table 3-147 10Gbps-SFP+-SMF-1511nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1511nm-70km-
commercial
Part Number 34060686
Model OSX070001
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1511 nm
Tx operating wavelength range [nm] 1504.5 nm - 1517.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
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Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.2 10Gbps-SFP+-SMF-1471nm-70km-commercial
Table 3-148 10Gbps-SFP+-SMF-1471nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1471nm-70km-
commercial
Part Number 34060687
Model OSX070002
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1471 nm
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Item Value
Tx operating wavelength range [nm] 1464.5 nm - 1477.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.3 10Gbps-SFP+-SMF-1491nm-70km-commercial
Table 3-149 10Gbps-SFP+-SMF-1491nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1491nm-70km-
commercial
Part Number 34060688
Model OSX070003
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1491 nm
Tx operating wavelength range [nm] 1484.5 nm - 1497.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.4 10Gbps-SFP+-SMF-1531nm-70km-commercial
Table 3-150 10Gbps-SFP+-SMF-1531nm-70km-commercial specifications
Item Value
Basic Information
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Item Value
Module name 10Gbps-SFP+-SMF-1531nm-70km-
commercial
Part Number 34060689
Model OSX070004
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1531 nm
Tx operating wavelength range [nm] 1524.5 nm - 1537.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
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Item Value
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.5 10Gbps-SFP+-SMF-1551nm-70km-commercial
Table 3-151 10Gbps-SFP+-SMF-1551nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1551nm-70km-
commercial
Part Number 34060690
Model OSX070005
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1551 nm
Tx operating wavelength range [nm] 1544.5 nm - 1557.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
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Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.6 10Gbps-SFP+-SMF-1571nm-70km-commercial
Table 3-152 10Gbps-SFP+-SMF-1571nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1571nm-70km-
commercial
Part Number 34060691
Model OSX070006
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1571 nm
Tx operating wavelength range [nm] 1564.5 nm - 1577.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.7 10Gbps-SFP+-SMF-1591nm-70km-commercial
Table 3-153 10Gbps-SFP+-SMF-1591nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1591nm-70km-
commercial
Part Number 34060692
Model OSX070007
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Item Value
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1591 nm
Tx operating wavelength range [nm] 1584.5 nm - 1597.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -21 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
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3.4.11.8 10Gbps-SFP+-SMF-1611nm-70km-commercial
Table 3-154 10Gbps-SFP+-SMF-1611nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1611nm-70km-
commercial
Part Number 34060693
Model OSX070008
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1611 nm
Tx operating wavelength range [nm] 1604.5 nm - 1617.4 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
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Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -21 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.12 10Gbps SFP+ BIDI Optical Module
3.4.12.1 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-40km-commercial
Table 3-155 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1270nm(Tx)/
1330nm(Rx)-40km-commercial
Part Number 02311JNF
Model OSX040B10
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-BX-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C (32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
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Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1270 nm
Tx operating wavelength range [nm] 1260 nm - 1280 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1320 nm - 1340 nm
Rx sensitivity (AVG) [dBm] -18 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
NOTE
1. Ensure that the optical power on the receive side is less than or equal to –5 dBm. If the
optical power does not meet the requirement, add an optical attenuator. Do not use short-
distance optical fibers for direct connection.
3.4.12.2 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-40km-commercial
Table 3-156 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1330nm(Tx)/
1270nm(Rx)-40km-commercial
Part Number 02311JNQ
Model OSX040B11
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Item Value
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-BX40-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1330 nm
Tx operating wavelength range [nm] 1320 nm - 1340 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1280 nm
Rx sensitivity (AVG) [dBm] -18 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
1. Ensure that the optical power on the receive side is less than or equal to –5 dBm. If the
optical power does not meet the requirement, add an optical attenuator. Do not use short-
distance optical fibers for direct connection.
3.4.12.3 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-10km-industry
Table 3-157 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-10km-industry
specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1270nm(Tx)/
1330nm(Rx)-10km-industry
Part Number 34060544-002
Model OSX010B10
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-BX10-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1270 nm
Tx operating wavelength range [nm] 1260 nm - 1280 nm
Maximum Tx optical power (AVG) 0.5 dBm
[dBm]
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Item Value
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -5.2 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1320 nm - 1340 nm
Rx sensitivity (AVG) [dBm] -14.4 dBm
Rx sensitivity (OMA) [dBm] -10.3 dBm
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] -
3.4.12.4 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-10km-industry
Table 3-158 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-10km-industry
specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1330nm(Tx)/
1270nm(Rx)-10km-industry
Part Number 34060546-002
Model OSX010B11
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-BX10-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1330 nm
Tx operating wavelength range [nm] 1320 nm - 1340 nm
Maximum Tx optical power (AVG) 0.5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -5.2 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1280 nm
Rx sensitivity (AVG) [dBm] -14.4 dBm
Rx sensitivity (OMA) [dBm] -12.6 dBm
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] -
3.4.13 10Gbps SFP+ OTN Optical Module
3.4.13.1 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial
Table 3-159 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial specifications
Item Value
Basic Information
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Item Value
Module name 10Gbps-SFP+-
SMF-1528nm~1568nm-40km-
commercial
Part Number 02314MED
Model OSX040C01
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW, ITUT
G.709
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(10GE)
<1x10E-4(OTU2, OTU2e)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-INF-8077i
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
11.1 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] -
Tx operating wavelength range [nm] 1529.163 nm - 1567.133 nm
Maximum Tx optical power (AVG) 3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -1 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1260 nm - 1600 nm
Rx sensitivity (AVG) [dBm] -16 dBm(EOL)(@ BER 1E-12,
9.95Gbps~10.7Gbps)
-19 dBm(EOL)(@ BER 2E-03, 11.3Gbps,
dispersion 800ps/nm, at room
temperature and OSNR > 31dB)
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -
3.4.14 10Gbps SFP+ DWDM Optical Module
3.4.14.1 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial
Table 3-160 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-
SMF-1528nm~1568nm-40km-
commercial
Part Number 02314MED
Model OSX040C01
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW, ITUT
G.709
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(10GE)
<1x10E-4(OTU2, OTU2e)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-INF-8077i
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
11.1 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] -
Tx operating wavelength range [nm] 1529.163 nm - 1567.133 nm
Maximum Tx optical power (AVG) 3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -1 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1600 nm
Rx sensitivity (AVG) [dBm] -16 dBm(EOL)(@ BER 1E-12,
9.95Gbps~10.7Gbps)
-19 dBm(EOL)(@ BER 2E-03, 11.3Gbps,
dispersion 800ps/nm, at room
temperature and OSNR > 31dB)
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -
3.4.15 25Gbps SFP28 Optical Module
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3.4.15.1 25Gbps-SFP28-MMF-850nm-0.1km-commercial (02312PDK)
Table 3-161 25Gbps-SFP28-MMF-850nm-0.1km-commercial specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-MMF-850nm-0.1km-
commercial
Part Number 02312PDK
Model SFP28-25G-850nm-0.1km-MM
Form factor SFP28
Application standard IEEE802.3-2012, 25GBASE-SR
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <5x10E-5
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 0.1 km
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) 2.4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.4 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 2 dB
Receiver Optical Characteristics
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Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -10.3 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 2.4 dBm
Overload power (OMA) [dBm] -
3.4.15.2 25Gbps-SFP28-SMF-1310nm-10km-industry (02312PDL)
Table 3-162 25Gbps-SFP28-SMF-1310nm-10km-industry specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-SMF-1310nm-10km-
industry
Part Number 02312PDL
Model SFP28-25G-1310nm-10km-SM
Form factor SFP28
Application standard IEEE 802.3 cc, 25GBASE-LR, 10GBASE-
LR
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
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Item Value
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1295 nm - 1325 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -7 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1295 nm - 1325 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -11.3 dBm
Overload power (AVG) [dBm] 2 dBm
Overload power (OMA) [dBm] -
3.4.15.3 25Gbps-SFP28-MMF-850nm-0.1km-commercial (34061254)
Table 3-163 25Gbps-SFP28-MMF-850nm-0.1km-commercial specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-MMF-850nm-0.1km-
commercial
Part Number 34061254
Model OMXD30011
Form factor SFP28
Application standard IEEE802.3-2012, 25GBASE-SR
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <5x10E-5
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Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 0.1 km
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) 2.4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.4 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -10.3 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 2.4 dBm
Overload power (OMA) [dBm] -
3.4.15.4 25Gbps-SFP28-SMF-1310nm-10km-industry (34061618)
Table 3-164 25Gbps-SFP28-SMF-1310nm-10km-industry specifications
Item Value
Basic Information
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Item Value
Module name 25Gbps-SFP28-SMF-1310nm-10km-
industry
Part Number 34061618
Model SFP28-25G-1310nm-10km-SM
Form factor SFP28
Application standard IEEE 802.3 by-2016, 25GBASE-LR,
10GBASE-LR
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1295 nm - 1325 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -7 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1295 nm - 1325 nm
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Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -11.3 dBm
Overload power (AVG) [dBm] 2 dBm
Overload power (OMA) [dBm] -
3.4.15.5 25Gbps-SFP28-MMF-850nm-0.1km-extended
Table 3-165 25Gbps-SFP28-MMF-850nm-0.1km-extended specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-MMF-850nm-0.1km-
extended
Part Number 34061631
Model SFP28-25G-850nm-0.1km-MM
Form factor SFP28
Application standard IEEE 802.3 by-2016, 25GBASE-SR,
10GBASE-SR
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] -20°C to 75°C(-4°F to 167°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 0.1 km
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
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Item Value
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) 2.4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.4 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -10.3 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 2.4 dBm
Overload power (OMA) [dBm] -
3.4.16 25Gbps SFP28 BIDI Optical Module
3.4.16.1 25Gbps-SFP28-SMF-1270nm(Tx)/1330nm(Rx)-10km-commercial
Table 3-166 25Gbps-SFP28-SMF-1270nm(Tx)/1330nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-SMF-1270nm(Tx)/
1330nm(Rx)-10km-commercial
Part Number 02312TVC
Model SFP28-25G-BIDI-10km-SM-3
Form factor SFP28
Application standard IEEE 802.3 by-2016, 25GBASE-LR,
10GBASE-LR
Connector type LC
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Optical fiber type SMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1270 nm
Tx operating wavelength range [nm] 1260 nm - 1280 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -4 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1320 nm - 1340 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -12 dBm
Overload power (AVG) [dBm] 2 dBm
Overload power (OMA) [dBm] -
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3.4.16.2 25Gbps-SFP28-SMF-1330nm(Tx)/1270nm(Rx)-10km-commercial
Table 3-167 25Gbps-SFP28-SMF-1330nm(Tx)/1270nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-SMF-1330nm(Tx)/
1270nm(Rx)-10km-commercial
Part Number 02312TXG
Model SFP28-25G-BIDI-10km-SM-4
Form factor SFP28
Application standard IEEE 802.3 by-2016, 25GBASE-LR,
10GBASE-LR
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1330 nm
Tx operating wavelength range [nm] 1320 nm - 1340 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -4 dBm
[dBm]
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Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1280 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -12 dBm
Overload power (AVG) [dBm] 2 dBm
Overload power (OMA) [dBm] -
3.4.17 40Gbps QSFP+ Optical Module
3.4.17.1 40Gbps(4*10.3)-QSFP+-SMF-1271~1331nm-10km-commercial
Table 3-168 40Gbps(4*10.3)-QSFP+-SMF-1271~1331nm-10km-commercial
specifications
Item Value
Basic Information
Module name 40Gbps(4*10.3)-QSFP+-
SMF-1271~1331nm-10km-commercial
Part Number 02310WUT
Model OMXD30009
Form factor QSFP+
Application standard IEEE 802.3ba, 40GBASE-LR4
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8436
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 41.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1271 nm
1291 nm
1311 nm
1331 nm
Tx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
1284.5 nm - 1297.5 nm
1304.5 nm - 1317.5 nm
1324.5 nm - 1337.5 nm
Maximum Tx optical power (AVG) per lane: 2.3 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 3.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -7 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -4 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
1284.5 nm - 1297.5 nm
1304.5 nm - 1317.5 nm
1324.5 nm - 1337.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -11.5 dBm
Overload power (AVG) [dBm] per lane: 2.3 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value.
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3.4.17.2 40Gbps(4*10.3)-QSFP+-MMF-850nm-0.1km-commercial
Table 3-169 40Gbps(4*10.3)-QSFP+-MMF-850nm-0.1km-commercial
specifications
Item Value
Basic Information
Module name 40Gbps(4*10.3)-QSFP+-
MMF-850nm-0.1km-commercial
Part Number 02310WUU
Model OMXD30010
Form factor QSFP+
Application standard IEEE 802.3ba, 40GBASE-SR4
Connector type MPO-12
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8436
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 41.25 Gbit/s
Target transmission distance [km] 0.1 km(OM3)
0.15 km(OM4)
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) per lane: 0.5 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 3 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -7.6 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -5.6 dBm
[dBm]
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Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -9.5 dBm
Overload power (AVG) [dBm] per lane: 0.5 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value.
3.4.17.3 40Gbps(4*10.3)-QSFP+-SMF-1310nm-10km-commercial
Table 3-170 40Gbps(4*10.3)-QSFP+-SMF-1310nm-10km-commercial
specifications
Item Value
Basic Information
Module name 40Gbps(4*10.3)-QSFP+-
SMF-1310nm-10km-commercial
Part Number 02311NUA
Model OSM010N11
Form factor QSFP+
Application standard IEEE 802.3ba, 40GBASE-LR4
Connector type MPO-12
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8436
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 4x9.95328 Gbit/s
4x10.3125 Gbit/s
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Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1355 nm
Maximum Tx optical power (AVG) per lane: 0.5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) per lane: -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1355 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -12.6 dBm
Overload power (AVG) [dBm] per lane: 0.5 dBm
Overload power (OMA) [dBm] -
3.4.17.4 QSFP-40G-LX4-MM
Table 3-171 QSFP-40G-LX4-MM specifications
Item Value
Basic Information
Module name QSFP-40G-LX4-MM
Part Number 02314MWG
Model OMMD15N01
Form factor QSFP+
Application standard 40GBASE-LX4
Connector type LC
Optical fiber type MMF
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Item Value
Working case temperature [°C(°F)] 0°C to 70°C (32°F to 158°F)
Transmission rate [bit/s] 40Gbit/s
Target transmission distance [km] 150m
Transmitter Optical Characteristics
Center wavelength [nm] 1271nm,1291nm,1311nm,1331nm
Maximum Tx optical power (AVG) 3.5 dBm
[dBm]
Minimum Tx optical power (OMA) -4.0 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx sensitivity (OMA) [dBm] -10.5 dBm
Overload power (AVG) [dBm] 3.5 dBm
NOTE
Application limitations:
- In actual applications, the number of conversion connectors for the optical fiber link
cannot exceed 4.
- This module is sensitive to fiber link contamination. During deployment, ensure that the
fiber endface meets the fiber application standard. For details, see the single-mode
connector requirements under the ceramic ferrule endface requirements of fibers in section
"Cable -Optical Jumper."
3.4.18 50Gbps QSFP28 Optical Module
3.4.18.1 50Gbps-QSFP28-SMF-1311nm-10km-commercial
Table 3-172 50Gbps-QSFP28-SMF-1311nm-10km-commercial specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1311nm-10km-
commercial
Part Number 02311YNR
Model OSL010N01
Form factor QSFP28
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Item Value
Application standard IEEE 802.3cd, 50GBASE-LR
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
CE Class B
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1311 nm
Tx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Maximum Tx optical power (AVG) 4.2 dBm
[dBm]
Maximum Tx optical power (OMA) 4 dBm
[dBm]
Minimum Tx optical power (AVG) -4.5 dBm
[dBm]
Minimum Tx optical power (OMA) -1.5 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Rx sensitivity (AVG) [dBm] -8.9 dBm
Rx sensitivity (OMA) [dBm] -8.9 dBm
Overload power (AVG) [dBm] 4.2 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
1. The optical power calculation is based on the OMA value. If the module needs to reach
the nominal data, the board FEC function must be enabled.
2. The optical power read by the device is the average optical power, not the OMA optical
power.
3. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.18.2 50Gbps-QSFP28-SMF-1311nm-40km-commercial
Table 3-173 50Gbps-QSFP28-SMF-1311nm-40km-commercial specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1311nm-40km-
commercial
Part Number 02312AXF
Model QSFP28-50G-1311nm-40km-SM
Form factor QSFP28
Application standard IEEE 802.3cd, 50GBASE-ER
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
CE Class B
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1311 nm
Tx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
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Item Value
Maximum Tx optical power (AVG) 8 dBm
[dBm]
Maximum Tx optical power (OMA) 9 dBm
[dBm]
Minimum Tx optical power (AVG) 1.5 dBm
[dBm]
Minimum Tx optical power (OMA) 4.5 dBm
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -15 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value.
If the module needs to reach the nominal data, the board FEC function must be enabled.
1. To keep the optical module running stably for a long time, set the receive optical power
less than -4 dBm. (According to IEEE 802.3, if the receive optical power exceeds -2.3 dBm,
the optical module may be permanently damaged.)
2. Before connecting the optical module, you are advised to use the optical power meter to
measure the receive optical power (P). If P is less than -4 dBm, the optical module can be
directly connected. If P is greater than -4 dBm, add an appropriate attenuator at the receive
end to ensure that P is less than -4 dBm. Alternatively, add an appropriate attenuator (the
recommended value is no less than 10 dB) before the optical module is connected, and
then adjust the attenuator according to the actual situation to prevent the module from
being damaged.
3. If the pigtail loopback or short-distance connection of the optical module is used, the
attenuator must be added. It is recommended that the attenuator be greater than or equal
to 10 dB.
4. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.18.3 50Gbps-QSFP28-SMF-1295.56~1300.05nm-80km-commercial
Table 3-174 50Gbps-QSFP28-SMF-1295.56~1300.05nm-80km-commercial
specifications
Item Value
Basic Information
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Item Value
Module name 50Gbps-QSFP28-
SMF-1295.56~1300.05nm-80km-
commercial
Part Number 02312MLF
Model QSFP28-50G-1310nm-80km-SM
Form factor QSFP28
Application standard Huawei Define
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 51.5625 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
Maximum Tx optical power (AVG) per lane: 6.5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) per lane: 2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
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Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
Rx sensitivity (AVG) [dBm] per lane: -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] per lane: -3.5 dBm
Overload power (OMA) [dBm] -
NOTE
1. The optical power is subject to the OMA. To achieve the nominal optical power, the FEC
function must be enabled on the board and G.652 fibers must be used.
2. The optical power of the optical module read on the device is the average optical power,
not the OMA optical power.
3. This module can be connected only to optical modules with the same BOM number.
3.4.19 50Gbps QSFP28 BIDI Optical Module
3.4.19.1 50Gbps-QSFP28-SMF-1331nm(Tx)/1271nm(Rx)-10km-commercial
Table 3-175 50Gbps-QSFP28-SMF-1331nm(Tx)/1271nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1331nm(Tx)/
1271nm(Rx)-10km-commercial
Part Number 02312EVV
Model QSFP28-50G-BIDI-10km-SM-1
Form factor QSFP28
Application standard IEEE 802.3bm-2015, 50GBASE-BR10
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(after FEC)
<2x10E-4(before FEC)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
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Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1331 nm
Tx operating wavelength range [nm] 1324.5 nm - 1337.5 nm
Maximum Tx optical power (AVG) 4.2 dBm
[dBm]
Maximum Tx optical power (OMA) 4 dBm
[dBm]
Minimum Tx optical power (AVG) -4.5 dBm
[dBm]
Minimum Tx optical power (OMA) -1.5 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -8.9 dBm
Overload power (AVG) [dBm] 4.2 dBm
Overload power (OMA) [dBm] -
NOTE
1. The optical power calculation is based on the OMA value. If the module needs to reach
the nominal data, the board FEC function must be enabled.
2. The optical power read by the device is the average optical power, not the OMA optical
power.
3. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
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3.4.19.2 50Gbps-QSFP28-SMF-1271nm(Tx)/1331nm(Rx)-10km-commercial
Table 3-176 50Gbps-QSFP28-SMF-1271nm(Tx)/1331nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1271nm(Tx)/
1331nm(Rx)-10km-commercial
Part Number 02312EVW
Model QSFP28-50G-BIDI-10km-SM-2
Form factor QSFP28
Application standard IEEE 802.3bm-2015, 50GBASE-BR10
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(after FEC)
<2x10E-4(before FEC)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1271 nm
Tx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
Maximum Tx optical power (AVG) 4.2 dBm
[dBm]
Maximum Tx optical power (OMA) 4 dBm
[dBm]
Minimum Tx optical power (AVG) -4.5 dBm
[dBm]
Minimum Tx optical power (OMA) -1.5 dBm
[dBm]
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Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1324.5 nm - 1337.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -8.9 dBm
Overload power (AVG) [dBm] 4.2 dBm
Overload power (OMA) [dBm] -
NOTE
1. The optical power calculation is based on the OMA value. If the module needs to reach
the nominal data, the board FEC function must be enabled.
2. The optical power read by the device is the average optical power, not the OMA optical
power.
3. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.19.3 50Gbps-QSFP28-SMF-1295nm(Tx)/1309nm(Rx)-40km-commercial
Table 3-177 50Gbps-QSFP28-SMF-1295nm(Tx)/1309nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1295nm(Tx)/
1309nm(Rx)-40km-commercial
Part Number 02312EVX
Model QSFP28-50G-BIDI-40km-SM-2
Form factor QSFP28
Application standard IEEE 802.3bm-2015, 50GBASE-BR40
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(after FEC)
<2x10E-4(before FEC)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
Maximum Tx optical power (AVG) 8 dBm
[dBm]
Maximum Tx optical power (OMA) 9 dBm
[dBm]
Minimum Tx optical power (AVG) 1.5 dBm
[dBm]
Minimum Tx optical power (OMA) 4.5 dBm
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] -15 dBm
Rx sensitivity (OMA) [dBm] -13.5 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
The optical power calculation is based on the OMA value. If the module needs to reach the
nominal data, the board FEC function must be enabled.
The optical power read by the device is the average optical power, not the OMA optical
power.
1. To keep the optical module running stably for a long time, set the receive optical power
less than -4 dBm. (According to IEEE 802.3, if the receive optical power exceeds -2.3 dBm,
the optical module may be permanently damaged.)
2. Before connecting the optical module, you are advised to use the optical power meter to
measure the receive optical power (P). If P is less than -4 dBm, the optical module can be
directly connected. If P is greater than -4 dBm, add an appropriate attenuator at the receive
end to ensure that P is less than -4 dBm. Alternatively, add an appropriate attenuator (the
recommended value is no less than 10 dB) before the optical module is connected, and
then adjust the attenuator according to the actual situation to prevent the module from
being damaged.
3. If the pigtail loopback or short-distance connection of the optical module is used, the
attenuator must be added. It is recommended that the attenuator be greater than or equal
to 10 dB.
4. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.19.4 50Gbps-QSFP28-SMF-1309nm(Tx)/1295nm(Rx)-40km-commercial
Table 3-178 50Gbps-QSFP28-SMF-1309nm(Tx)/1295nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1309nm(Tx)/
1295nm(Rx)-40km-commercial
Part Number 02312EVY
Model QSFP28-50G-BIDI-40km-SM-1
Form factor QSFP28
Application standard IEEE 802.3bm-2015, 50GBASE-BR40
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(after FEC)
<2x10E-4(before FEC)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1309 nm
Tx operating wavelength range [nm] 1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) 8 dBm
[dBm]
Maximum Tx optical power (OMA) 9 dBm
[dBm]
Minimum Tx optical power (AVG) 1.5 dBm
[dBm]
Minimum Tx optical power (OMA) 4.5 dBm
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
Rx sensitivity (AVG) [dBm] -15 dBm
Rx sensitivity (OMA) [dBm] -13.5 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
The optical power calculation is based on the OMA value. If the module needs to reach the
nominal data, the board FEC function must be enabled.
The optical power read by the device is the average optical power, not the OMA optical
power.
1. To keep the optical module running stably for a long time, set the receive optical power
less than -4 dBm. (According to IEEE 802.3, if the receive optical power exceeds -2.3 dBm,
the optical module may be permanently damaged.)
2. Before connecting the optical module, you are advised to use the optical power meter to
measure the receive optical power (P). If P is less than -4 dBm, the optical module can be
directly connected. If P is greater than -4 dBm, add an appropriate attenuator at the receive
end to ensure that P is less than -4 dBm. Alternatively, add an appropriate attenuator (the
recommended value is no less than 10 dB) before the optical module is connected, and
then adjust the attenuator according to the actual situation to prevent the module from
being damaged.
3. If the pigtail loopback or short-distance connection of the optical module is used, the
attenuator must be added. It is recommended that the attenuator be greater than or equal
to 10 dB.
4. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.20 100Gbps QSFP28 Optical Module
3.4.20.1 100Gbps(4*25.7)-QSFP28-MMF-850nm-0.1km-commercial
Table 3-179 100Gbps(4*25.7)-QSFP28-MMF-850nm-0.1km-commercial
specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
MMF-850nm-0.1km-commercial
Part Number 02311NTY
Model OMND10N13
Form factor QSFP28
Application standard IEEE 802.3bm, 100GBASE-SR4
Connector type MPO-12
Optical fiber type MMF
Bit error ratio (BER) <5x10E-5
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 0.07 km(OM3)
0.1 km(OM4)
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) per lane: 2.4 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 3 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -8.4 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -6.4 dBm
[dBm]
Minimum extinction ratio [dB] 2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -10.3 dBm
Overload power (AVG) [dBm] per lane: 2.4 dBm
Overload power (OMA) [dBm] -
NOTE
1. If the module needs to reach the nominal data, the board FEC function must be enabled.
2. The BER 5x10E - 5 is the data that is not enabled by FEC, so that 1x10E - 12 can be
reached after FEC .
3. The optical power calculation is based on the OMA value. The optical power read by the
device is the average optical power, not the OMA optical power.
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3.4.20.2 100Gbps(4*25.7)-QSFP28-SMF-1271~1331nm-2km-commercial
Table 3-180 100Gbps(4*25.7)-QSFP28-SMF-1271~1331nm-2km-commercial
specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1271~1331nm-2km-commercial
Part Number 02311QDH
Model OSN020N15
Form factor QSFP28
Application standard 100G CWDM4 MSA
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 2 km
Transmitter Optical Characteristics
Center wavelength [nm] 1271 nm
1291 nm
1311 nm
1331 nm
Tx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
1284.5 nm - 1297.5 nm
1304.5 nm - 1317.5 nm
1324.5 nm - 1337.5 nm
Maximum Tx optical power (AVG) per lane: 2.5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
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Minimum Tx optical power (AVG) per lane: -6.5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
1284.5 nm - 1297.5 nm
1304.5 nm - 1317.5 nm
1324.5 nm - 1337.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -10 dBm
Overload power (AVG) [dBm] per lane: 2.5 dBm
Overload power (OMA) [dBm] -
NOTE
1. If the module needs to reach the nominal data, the board FEC function must be enabled.
2. The BER 5x10E - 5 is the data that is not enabled by FEC, so that 1x10E - 12 can be
reached after FEC .
3.4.20.3 100Gbps(4*25.7)-QSFP28-SMF-1310nm-30km(NO FEC)-40km(FEC)-
commercial
Table 3-181 100Gbps(4*25.7)-QSFP28-SMF-1310nm-30km(NO FEC)-40km(FEC)-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1310nm-30km(NO
FEC)-40km(FEC)-commercial
Part Number 02312AUE
Model OSN030N05
Form factor QSFP28
Application standard IEEE 802.3ba, 100GBASE-ER4
Connector type LC
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Item Value
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 40 km(FEC)
30 km(NO FEC)
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 2.9 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 4.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -2.5 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: 0.1 dBm
[dBm]
Minimum extinction ratio [dB] 8 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] -
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Item Value
Rx sensitivity (OMA) [dBm] per lane: -21.4 dBm
Overload power (AVG) [dBm] per lane: -3.5 dBm
Overload power (OMA) [dBm] -
NOTE
1. If the module needs to reach 40 km, the board FEC function must be enabled. Otherwise,
it can reach only 30 km.
2. The BER 5x10E - 5 is the data obtained with FEC not enabled. After FEC is enabled, 1x10E
- 12 can be reached.
3. In 30 km application, the BER can reach 1x10E - 12.
4. The optical power calculation is based on the OMA value. The optical power read by the
device is the average value, not the OMA optical power.
3.4.20.4 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-
commercial (02312BSS)
Table 3-182 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1295.56~1309.14nm-10km-
commercial
Part Number 02312BSS
Model OSN010N24
Form factor QSFP28
Application standard IEEE 802.3ba, 100GBASE-LR4
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
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Item Value
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 4.5 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 4.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -4.3 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -1.3 dBm
[dBm]
Minimum extinction ratio [dB] 4 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -8.6 dBm
Overload power (AVG) [dBm] per lane: 4.5 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value. The optical power read by the
device is the average optical power, not the OMA optical power.
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3.4.20.5 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-80km-
commercial
Table 3-183 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-80km-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1295.56~1309.14nm-80km-
commercial
Part Number 02312NCX
Model QSFP28-100G-1310-80km-SM
Form factor QSFP28
Application standard Huawei Define
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 6.5 dBm
[dBm]
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Item Value
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) per lane: 2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] per lane: -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] per lane: -3.5 dBm
Overload power (OMA) [dBm] -
NOTE
1. To achieve the nominal value, the FEC function must be enabled on the board and G.652
fibers must be used.
2. The BER 5x10E-5 is the data when FEC is disabled. After FEC is enabled, the BER can
reach 1x10E-12.
3. When the optical module is used for 80 km transmission, it must be interconnected with
Huawei optical modules of the same model.
3.4.20.6 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-40km-
commercial
Table 3-184 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-40km-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1295.56~1309.14nm-40km-
commercial
Part Number 02312NVQ
Model QSFP28-100G-1310-40km-SM
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Item Value
Form factor QSFP28
Application standard IEEE 802.3 100GBASE-ER4
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 2.9 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 4.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -2.9 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: 0.1 dBm
[dBm]
Minimum extinction ratio [dB] 8 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] per lane: -20.9 dBm
Rx sensitivity (OMA) [dBm] per lane: -21.4 dBm
Overload power (AVG) [dBm] per lane: -3.5 dBm
Overload power (OMA) [dBm] -
NOTE
When an optical module is installed on an interface, the FEC function on the interface is
disabled by default. Pay attention to the FEC status of the peer interface during
interconnection.
3.4.20.7 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-
commercial (02313SWA)
Table 3-185 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1295.56~1309.14nm-10km-
commercial
Part Number 02313SWA
Model OSN010N24
Form factor QSFP28
Application standard IEEE 802.3ba, 100GBASE-LR4
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 4.5 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 4.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -4.3 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -1.3 dBm
[dBm]
Minimum extinction ratio [dB] 4 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -8.6 dBm
Overload power (AVG) [dBm] per lane: 4.5 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value. The optical power read by the
device is the average optical power, not the OMA optical power.
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3.4.20.8 100Gbps-QSFP28-1310nm-10km-commercial
Table 3-186 100Gbps-QSFP28-1310nm-10km-commercial specifications
Item Value
Basic Information
Module name 100Gbps-QSFP28-1310nm-10km-
commercial
Part Number 02314GYE
Model OSN010N22
Form factor QSFP28
Application standard IEEE 802.3cd, 100GBASE-LR1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-4
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
CE Class B
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 106.25 Gbit/s(PAM4)
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Maximum Tx optical power (AVG) 4.8 dBm
[dBm]
Maximum Tx optical power (OMA) 4.8 dBm
[dBm]
Minimum Tx optical power (AVG) -1.9 dBm
[dBm]
Minimum Tx optical power (OMA) -1.9 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
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Item Value
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Rx sensitivity (AVG) [dBm] -6.1 dBm
Rx sensitivity (OMA) [dBm] -6.1 dBm
Overload power (AVG) [dBm] 4.8 dBm
Overload power (OMA) [dBm] -
NOTE
1. The optical power is subject to the OMA optical power. To reach the nominal value, the
FEC function of the optical module must be enabled.
2. The optical power of an optical module displayed on the device is the average optical
power, not the OMA optical power.
3. When this type of optical module is used to interconnect with WDM equipment, the
WDM client-side 1+1 protection switching time is greater than 50 ms.
3.5 Cables
3.5.1 NetEngine 8000 F1A-8H20Q Power Cable
This section describes the structure and technical specifications of the power cable.
3.5.1.1 DC Power Cable
This section describes the structure and technical specifications of the DC power
cable.
NO TICE
Cables are delivered according to default configurations. If there are special
requirements, purchase cables locally.
If the power distribution frame (PDF) is more than 25 m away from a device,
install a PDF as close as possible to the device.
Overview
The DC power cable connects a device to the power module to supply power to
the device.
NO TE
The following cable colors are for reference only. The actual cable colors depend on the
requirements of the target country or customer.
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Appearance
Figure 3-29 DC power cable
Figure 3-30 DC power connector
Figure 3-31 OT terminal
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Figure 3-32 Heat-shrink tubing
Technical Specifications
Table 3-187 Specifications of the DC power cable
Dis Part Mo Description Co Co Ca Nu Fireproof
tan Num del nn nn bl mb Level
ce ber ect ec e er
fro or to Le of
m 1 r 2 ng Co
the th res
PD
F
to
the
De
vic
e
Sho 2503 - Electronic|Electric - - - - IEC
rter 0701 Cable,450V/750V,H07Z- 60332-1,
tha K VM-1, Dca-
n UL3386,4mm^2,Blue,45 s2a2d2
or A,LSZH Cable,VDE,UL
equ
al 2503 - Electronic|Electric - - - - IEC
to 0700 Cable,450V/750V,H07Z- 60332-1,
15 K VM-1, Dca-
m UL3386,4mm^2,Black,4 s2a2d2
5A,LSZH Cable,VDE,UL
2503 - Electronic|Electric - - - - IEC
0735 Cable,450V/750V,H07Z- 60332-1,
K VM-1, Dca-
UL3386,4mm^2,Gray,45 s2a2d2
A,LSZH Cable,VDE,UL
2503 - Electronic|Electric - - - - IEC
0730 Cable,450V/750V,H07Z- 60332-1,
K VM-1, Dca-
UL3386,4mm^2,Red,45 s2a2d2
A,LSZH Cable,VDE,UL
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Dis Part Mo Description Co Co Ca Nu Fireproof
tan Num del nn nn bl mb Level
ce ber ect ec e er
fro or to Le of
m 1 r 2 ng Co
the th res
PD
F
to
the
De
vic
e
2503 - Electronic|Electric - - - - IEC
2787 Cable,1100V,Y(FR- 60332-1,
-001 LSH),4mm^2,Blue,45A,F IEC
or India,BIS 60332-3-22
2503 - Electronic|Electric - - - - IEC
2787 Cable,1100V,Y(FR- 60332-1,
LSH),4mm^2,Black,45A, IEC
For India,BIS 60332-3-22
Lon 2503 - Electronic|Electric - - - - IEC
ger 0697 Cable,450V/750V,H07Z- 60332-1,
tha K VM-1, Dca-
n UL3386,6mm^2,Blue,58 s2a2d2
15 A,LSZH Cable,VDE,UL
m
but 2503 - Electronic|Electric - - - - IEC
sho 0703 Cable,450V/750V,H07Z- 60332-1,
rter K VM-1, Dca-
tha UL3386,6mm^2,Black,5 s2a2d2
n 8A,LSZH Cable,VDE,UL
or 2503 - Electronic|Electric - - - - IEC
equ 0717 Cable,450V/750V,H07Z- 60332-1,
al K VM-1, Dca-
to UL3386,6mm^2,Gray,58 s2a2d2
25 A,LSZH Cable,VDE,UL
m
2503 - Electronic|Electric - - - - IEC
0731 Cable,450V/750V,H07Z- 60332-1,
K VM-1, Dca-
UL3386,6mm^2,Red,58 s2a2d2
A,LSZH Cable,VDE,UL
2503 - Electronic|Electric - - - - IEC
2788 Cable,1100V,Y(FR- 60332-1,
-001 LSH),6mm^2,Blue,58A,F IEC
or India,BIS 60332-3-22
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Dis Part Mo Description Co Co Ca Nu Fireproof
tan Num del nn nn bl mb Level
ce ber ect ec e er
fro or to Le of
m 1 r 2 ng Co
the th res
PD
F
to
the
De
vic
e
2503 - Electronic|Electric - - - - IEC
2788 Cable,1100V,Y(FR- 60332-1,
LSH),6mm^2,Black,58A, IEC
For India,BIS 60332-3-22
Table 3-188 Specifications of the DC power connector
Part Mode Description Terminal Type
Nu l
mbe
r
1419 - Easy Power -
1175 Connector,2Pin,48V,40A,Straight
female,1.5mm^2~10mm^2,Small-
sized Easy Power,with pull ring
Table 3-189 Specifications of ground cables
Par Mod Description Conn Conn Cab Nu Fireproof
t el ector ector le m Level
Nu 1 2 Len be
mb gth r
er of
Co
res
250 - Electronic|Electric OT OT 15 - IEC
306 Cable,450V/750V,H07Z-K termi termi m 60332-1,
99 UL3386,6mm^2,Yellow/ nal nal VM-1,
Green,58A,LSZH Dca-
Cable,VDE,UL s2a2d2
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Par Mod Description Conn Conn Cab Nu Fireproof
t el ector ector le m Level
Nu 1 2 Len be
mb gth r
er of
Co
res
250 - Electronic|Electric OT OT 15 - IEC
327 Cable,1100V,Y(FR- termi termi m 60332-1,
88- LSH),6mm^2,Yellow/ nal nal IEC
002 Green,58A,For India,BIS 60332-3-
22
Table 3-190 Specifications of ground cable terminals
Part Mode Description Terminal Type
Nu l
mbe
r
0223 - Package of Terminal for Naked Crimping
2UD Single Input 6mm^2 Terminal,OT,6mm^2,M4,Tin
U Grounding Cable(Include Plating,Insulated Ring
Backup) Terminal,12~10AWG,yellow
Naked Crimping
Connector,OT2,6mm^2,M4,Tin
Plating
Naked Crimping
Terminal,OT,6mm^2,M8,Tin
Plating,Insulated Ring
Terminal,12~10AWG,yellow
Naked Crimping
Terminal,OT,6mm^2,M6,Tin
Plating,Insulated Ring
Terminal,12~10AWG,yellow
3.5.1.2 AC Power Cable
This section describes the structure and technical specifications of the AC-input
power cable.
NO TICE
If no special requirements are imposed on power cables, power cables are
delivered according to default configurations. Otherwise, power cables need to be
purchased locally.
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Hardware Guide 3 Hardware Description
Overview
An AC power cable is used to connect to the AC power module of a device to
supply power to the device.
NO TE
Cables must be in compliance with standards of the destination country or region. The
actual cable type depends on the requirements of the target country or customer.
Appearance
Figure 3-33 Connector C13 (PDU)
Figure 3-34 Connector C13 (wall-mounted)
Figure 3-35 Heat shrink tubing
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Technical Specifications
Table 3-191 Technical specifications of AC power cables in different countries or
regions (PDU)
Part Description Connecto Conne Leng Numb
Num r X1 ctor th er of
ber X2 Cores
0405 Power Cords Cable,China AC C14SM C13SF 1.5 m 3
0188 Power cores
250V10A,1.5m,C14SM,227IEC53(
RVV)1.0mm2(3C),C13SF,PDU
Cable
0405 Power Cords Cable,Europe AC C14SM C13SF 1.8 m 3
G019 250V10A,1.8m,C14SM,H05VV-F- cores
3*1.00mm2,C13SF,PDU Cable
0405 Power cord,Europe AC C14SM C13SF 3 m 3
G019 250V10A,3.0m,C14SM,H05VV-F- cores
-002 3*1.00^2,C13SF,250V,10A,PDU
Cable
0405 Power Cords Cable,North C14SM C13SF 1.8 m 3
G029 America AC Power cores
250V10A,1.8m,C14SM,SJT
18AWG(3C),C13SF,PDU Cable
0405 Power Cords Cable,Japan AC C14SM C13SF 1.8 m 3
G02D Power cores
250V12A,1.8m,C14SM,HVCTF
1.25mm2(3C),C13SF,PDU Cable
0405 Power Cords Cable,Australia AC C14SM C13SF 1.8 m 3
G02F Power cores
250V10A,1.8m,C14SM,H05VV-
F-1.0mm2(3C),C13SF,PDU Cable
0405 Power Cords Cable,Korea AC C14SM C13SF 1.8 m 3
G02H Power cores
250V10A,1.8m,C14SM,H05VV-
F-1.0mm2(3C),C13SF,PDU Cable
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Table 3-192 Technical specifications of AC power cables in different countries or
regions (wall-mounted)
Part Description Connecto Conne Leng Numb
Num r X1 ctor th er of
ber X2 Cores
0404 Power Cords Cable,China AC PISM C13SF 3m 3
1104 Power cores
250V10A,3.0m,PISM,227IEC53-1.0
mm2(3C),C13SF,Black
0402 Power Cable,America AC Power PBSM C13SF 3m 3
0728 Cable,125V10A,3.0m,PBSM,18SJ cores
T(3C),C13SF,Black
0404 Power cord,Europe AC Power PFSM C13SF 3m 3
1056 Cable,250V10A,3.0m,PFSM, cores
(H05VVF
1.0mm2(3C)),C13SF,250V,10A,BLa
ck
0404 Power Cable,Britain AC Power PGAM C13SF 3m 3
0890 Cable cores
250V10A,3.0m,PGAM ,H05VV-
F-1.0mm2(3C),C13SF,Black
0404 Power Cable,Japan AC Power PBSM C13SF 3m 3
0887 Cable cores
125V12A,3.0m,PBSM,HVCTF-1.25
mm2(3C),C13SF,Black
0404 Power cord,BS546 PM-IAM C13SF 3m 3
0889 250V10A,3.0m,PM-IAM,H05VV- cores
F-1.5mm2(3C),C13SF,250V,10A,Bl
ack
0404 Power Cords Cable,Australia AC PISM C13SF 3m 3
0888 Power Cable,250V cores
10A,3.0m,PISM,H05VV-
F-1.0mm2(3C),C13SF,Black
0404 Power Cable,Switzerland AC PJSM C13SF 3m 3
1119 Power Cable cores
250V10A,3.0m,PJSM ,H05VV-
F-1.0mm2(3C),C13SF,Black
0404 Power Cable,Italy AC Power PLSM C13SF 3m 3
1120 Cable cores
250V10A,3.0m,PLSM,H05VV-
F-1.0mm2(3C),C13SF,Black
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Part Description Connecto Conne Leng Numb
Num r X1 ctor th er of
ber X2 Cores
0404 Power Cords Cable,Argentina AC PISM C13SF 3m 3
7785 Power cores
250V10A,3.0m,PISM,H05VV-
F-1.0mm2(3C),C13SF,Black
0415 Power Cable,Brazil AC Power PNSM C13SF 3m 3
0258 Cable cores
250V10A,3.0m,PNSM ,H05VV-
F-1.0mm2(3C),C13SF,Black
0405 Power Cords Cable,Korea AC PFSM C13SF 3m 3
G028 Power cores
250V10A,3m,PFSM,H05VV-F
3*1.0mm2(3C),C13SF,Black
0405 Power Cords Cable,Denmark AC PKSM C13SF 3m 3
G02K Power cores
250V10A,3m,PKSM,H05VV-
F-3*1.0mm2(3C),C13SF,Black
0405 Power Cords Cable,India AC PM-IIAM C13SF 3m 3
1035 Power 250V10A,3.0m,PM-IIAM,IS cores
694-1.0mm2(3C), C13
SF,250V,10A,Black
0405 Power cord,South Africa AC PMAM C13SF 3m 3
1080 Power cores
250V10A,3m,PMAM,H05VV-
F-1.0mm2(3C),C13SF,250V,10A,Bl
ack
0405 Power cord,Taiwan, China AC PBSM C13SF 3m 3
2137 125V11A,3.0m,PBSM,HVCTF cores
3*1.25mm2,C13SF,125V,11A,Black,
BSMI
3.5.2 Chassis Ground Cable
Overview
One end of a chassis ground cable is connected to the ground screw on the right-
side cabinet column, and the other end is connected to the ground screw on the
chassis.
Appearance
Figure1 shows the appearance of chassis ground cable.
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Figure 3-36 Appearance of chassis ground cable.
1. OT one-hole naked crimping connector
Connection
A ground cable grounds a device to protect it from lightning and electromagnetic
interference. A ground cable is connected to a chassis in the following way:
● The OT bare crimp terminal X1 connects to the ground point on the chassis.
● The OT bare crimp terminal X2 connects to the ground bar of the cabinet.
Technical Specifications
Table 3-193 Technical specifications of chassis ground cable
Dev Part Mo Description Con Connec Le Fire
ice Nu del nec tor X2 ngt Rating
Mo mb tor h
del er X1
Net 250 - Electronic|Electric OT OT 15 IEC
Engi 306 Cable,450V/750V,H07Z-K Ter Termina m 60332-
ne 99 UL3386,6mm^2,Yellow/ min l 1,
800 Green,58A,LSZH al VM-1
0 Cable,VDE,UL
F1A
-8H
20Q
3.5.3 Standard Serial Cable
This section describes the structure and technical specifications of the standard
serial cable.
Introduction
One end of the standard serial cable is a DB9 connector that is connected to the
serial port of a computer, and the other end is an RJ45 connector that is
connected to the standard console port of a router.
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Appearance
Figure 3-37 shows the structure of a standard serial cable, and Table 3-194
describes the cable connections.
Figure 3-37 Standard serial cable (04040838 - Single Cable,Serial
Cable,3m,D9F,CC2P0.32PWG1U,MP8-VI,S3026V)
1 DB9 female 2 Network interface RJ45 W communication cable
Table 3-194 Connections of the standard serial cable
Start Point End Point Color
X1.2 X2.3 Black
X1.3 X2.6 Brown
X1.5 X2.5 Red
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Technical Specifications
Table 3-195 Technical specifications of a standard serial cable and a serial adapter
cable
Par Mod Description Connect Connector Cable Le Nu Fir
t el or X1 X2 Type ng mb e
Nu th er Rat
mb of ing
er Co
res
040 - Single D9F MP8-VI Twiste 3m 2 -
408 Cable,Serial d-Pair cor
38 Cable,3m,D9 Cable, es/
F,CC2P0.32P UL246 pai
WG1U,MP8- 4,0.32 r
VI,S3026V mm,28
AWG,2
Pairs,P
ANTO
NE
WARM
GRAY
1U
3.5.4 USB-to-Serial Cable
This section describes the structure and technical specifications of the USB-to-
serial cable.
Overview
The USB-to-serial cable uses a USB port to connect to a client device at one end
and uses two RJ45 connector-based serial ports (one standard and one non-
standard) to connect to a router at the other end. The pin assignments of the two
serial ports are different. For details, see Table 3-196.
Structure
Figure 3-38 Structure of the USB-to-serial cable
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Pin Assignments
Table 3-196 Pin assignments of the USB-to-serial cable
Wire Rela Core Cabl Start Conv End Cabl Core Rela Wire
No. tions Wire e Pin erter Pin e Wire tions No.
hip Colo Desc Desc Colo hip
r ripti ripti r
on on
W3- Twist Whit +5 V X1.1 USB- X2.6 RS23 Blue Twist W1-
Main ed e DC to- 2_RX ed Labe
Labe RS23 l 1
l Blue Data X1.2 2 X2.3 RS23 Whit (RS2
- conv 2_TX e 32)
Twist Oran Data X1.3 erter X2.5 GND Oran -
ed ge + ge
Whit GND X1.4 X3.5 RS23 Blue Twist W2-
e 2_RX ed Labe
l 2
- - - - - X3.8 RS23 Whit (Spe
2_TX e cial
- - - - - X3.4 GND Oran - RS23
ge 2)
Technical Specifications
Table 3-197 Technical specifications of the USB-to-serial cable
Part Description Connect Connect Cable
Number or X1 or X2 Length
0407185 Traditional Signal Cable,USB-to- USB-A MP8-II 1.5 m
1 Ethernet cable,1.5m,USB- (Male)
A(Male),CC2P0.48B(S),2*MP8-II
NO TICE
To use the USB-to-serial cable, you need to download the corresponding driver at
https://www.wch-ic.com/products/CH340.html? and configure the driver as
required.
3.5.5 Clock Cable (External Clock Mode, Delivery-Ready)
This section describes the structure and technical specifications of the clock cable.
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Introduction
The external clock cables can be connected to the CLK, and CLK/TOD interfaces on
a device.
Structure
The 120-ohm trunk cable adopts the RJ45 connector. Figure 3-39 shows the
structure of the 120-ohm trunk cable.
Figure 3-39 120-ohm trunk cable
Pin Assignment
Table 3-198 Pin assignments of the 120-ohm trunk cable
Connector X1 Connector X2 Color Relation
1 4 White Pair
2 5 Blue
3 6 Orange -
4 1 White Pair
5 2 Green
6 3 Brown -
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Technical Specifications
Table 3-199 Technical specifications of the 120-ohm trunk cable
Par Mo Description Co Co Cable Le Nu Fire
t del nne nn Type ng mb Ratin
Nu cto ect th er g
mb r or of
er X1 X2 Cor
es
040 - Trunk MP MP Twisted 3 2 IEC
404 Cable,3m,120ohm,1E1,0. 8-II 8-II -Pair m cor 60332
97 4mm,MP8- Cable,1 es/ -1
II,120CC4P0.4P430U(S), 20ohm, pair
MP8-II SEYVP,0
.4mm,2
040 - Trunk MP MP 6AWG, 15 2 IEC
402 Cable,15m,120ohm,1E1,0 8-II 8-II 4Pairs, m cor 60332
61 .4mm,MP8- Panton es/ -1
II,120CC4P0.4P430U(S), e 430U pair
MP8-II
3.5.6 Clock Cable (External Clock/External Time Mode,
Prepared Onsite)
Overview
A clock cable is used to connect the clock interface on a router to that on another
device. If equipped with only one main control board, a router can receive one-
channel 2 Mbit/s clock signals, one-channel 2 MHz clock signals, one-channel
DCLS time signals, or one-channel 1PPS+TOD time signals from the upstream
device and provides one-channel 2 Mbit/s clock signals, one-channel 2 MHz clock
signals, one-channel DCLS time signals, or one-channel 1PPS+TOD time signals to
the downstream device. If equipped with two main control boards, a router can
receive two-channel 2 Mbit/s clock signals, two-channel 2 MHz clock signals, two-
channel DCLS time signals, or two-channel 1PPS+TOD time signals from the
upstream device and provides two-channel 2 Mbit/s clock signals, two-channel 2
MHz clock signals, two-channel DCLS time signals, or two-channel 1PPS+TOD
time signals to the downstream device.
The clock cable features RJ45 connectors at both ends: one is used to connect to
the clock interface on the front panel of a main control board, and the other is
used to connect to the clock interface on an external device.
An RJ45 connector is used together with the 120-ohm trunk cable.
NO TE
The wire sequence of a trunk cable used as a clock cable differs from that of an ordinary
twisted pair cable.
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Appearance
The 120-ohm clock cable uses the RJ45 connector. The following figure shows the
cable structure.
Figure 3-40 Appearance of the 120-ohm clock cable connector
Pin Assignments
Table 3-200 Pin assignments of the 120-ohm clock cable
Pin Rela Description
tion
ship External Clock External Time External Time Mode
Mode Mode (DCLS)
(1PPS + Time
Information)
X1.1 Twis Receive Not defined Not defined
ted negative for
CLK signals
X1.2 Receive positive Not defined Not defined
for CLK signals
X1.3 Twis Not defined Negative for IPPS Negative for DCLS
ted signals signals
X1.6 Not defined Positive for IPPS Positive for DCLS
signals signals
X1.4 Twis Transmit Ground end Ground end
ted negative for
CLK signals
X1.5 Transmit Ground end Ground end
positive for CLK
signals
X1.7 Twis Not defined Negative for time Not defined
ted information
X1.8 Not defined Positive for time Not defined
information
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Technical Specifications
Table 3-201 Technical specifications of the 120-ohm clock cable
Part Mod Description Con Connect Num Firepro
Nu el nect or X2 ber of
mbe or of Level
r X1 Core
s
1408 - Network Interface - - - -
0097 Connector,8-Bit
8PIN,Shielded,Crystal Model
Connector,24-26AWG,Leads
Single Solide Cable,For OEM
Matching 25050057
2505 - Twisted-Pair - - 2 IEC603
0057 Cable,100ohm,Category cores 32-1
5e,FTP,0.52mm,24AWG,8Core /pair
s,4Pairs,PANTONE 430U,Use
with Plug:14080097
3.5.7 Clock Bridging Cable
Overview
The clock bridging cable used by a device is the 120-ohm-to-75-ohm clock cable.
Structure
Figure 3-41 shows the structure of the 120-ohm-to-75-ohm clock cable.
Figure 3-41 Structure of a clock bridging cable
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Pin Assignments
Table 3-202 Pin assignments of clock bridging cables
120-ohm Cable 75-ohm
Cable
Connector Pin Core Wire Cable Relations Core Wire
Color Description hip No.
X1.1 Orange Receive Twisted W1
negative for the
120-ohm
external clock
X1.2 White Receive positive
for the 120-
ohm external
clock
X1.4 Blue Transmit Twisted W2
negative for the
120-ohm
external clock
X1.5 White Transmit
positive for the
120-ohm
external clock
X1.3 Green Not defined Twisted W3
X1.6 White Not defined
X1.7 White Not defined Twisted W4
X1.8 Brown Not defined
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Technical Specifications
Table 3-203 Technical specifications of a clock bridging cable
Part Mo Description Conn Con Cabl N Firepr
Nu del ector nect e u oof
mb X1 or Len m Level
er X2 gth be
r
of
C
or
es
040 T-1- Signal Cable,120ohm To MP8- - 30 - -
447 Sh- 75ohm Clock II m
26 RJ45 Cable,30m,MP8-II,
-30 (120CC4P0.4P430U(S)
+4*(SYV75-2/0.34(S))
3.5.8 Ethernet Cable
Overview
Ethernet cables are also known as network cables and can be classified into
straight-through cables and crossover cables according to the connection sequence
of the copper wire cores in the cables.
An Ethernet service interface can detect whether a straight-through or crossover
cable is plugged in, meaning it will work automatically with either cable type.
Therefore, you can choose either cable type as needed for your network setup.
NO TE
Ethernet cables need to be made onsite.
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Appearance
Figure 3-42 Appearance of the Ethernet cable
Pin Assignments
Table 3-204 Pin assignments of the straight-through cable
Connector X1 Pin Connector X2 Pin Color Relationship
X1.1 X2.1 White/Orange Twisted
X1.2 X2.2 Orange
X1.3 X2.3 White/Green Twisted
X1.6 X2.6 Green
X1.4 X2.4 Blue Twisted
X1.5 X2.5 White/Blue
X1.7 X2.7 White/Brown Twisted
X1.8 X2.8 Brown
Table 3-205 Pin assignments of the crossover cable
Connector X1 Pin Connector X2 Pin Color Relationship
X1.1 X2.3 White/Orange Twisted
X1.2 X2.6 Orange
X1.3 X2.1 White/Green Twisted
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Connector X1 Pin Connector X2 Pin Color Relationship
X1.6 X2.2 Green
X1.4 X2.4 Blue Twisted
X1.5 X2.5 White/Blue
X1.7 X2.7 White/Brown Twisted
X1.8 X2.8 Brown
Technical Specifications
Table 3-206 Technical specifications of the straight-through cable
Descr Twisted-Pair Cable,100ohm,Category
iptio 5e,FTP,0.52mm,24AWG,8Cores,4Pairs,PANTONE 430U
n
Conn Network Interface Connector,8PIN,8-Bit,Shielded,Crystal Plug,AWG24–
ector 26,Solid-Core Cable with Inner Conductor
X1
Conn Network Interface Connector,8PIN,8-Bit,Shielded,Crystal Plug,AWG24–
ector 26,Solid-Core Cable with Inner Conductor
X2
Cabl 1 m, 3 m, 5 m, 10 m, 20 m, 30 m
e
Leng
th
Inner 0.52 mm
Diam
eter
Num 2 cores/pair
ber
of
Cores
Table 3-207 Technical specifications of the crossover cable
Descr Twisted-Pair Cable,100ohm,Category
iptio 5e,FTP,0.52mm,24AWG,8Cores,4Pairs,PANTONE 430U
n
Conn Network Interface Connector,8PIN,8-Bit,Shielded,Crystal Plug,AWG24–
ector 26,Solid-Core Cable with Inner Conductor
X1
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Conn Network Interface Connector,8PIN,8-Bit,Shielded,Crystal Plug,AWG24–
ector 26,Solid-Core Cable with Inner Conductor
X2
Cabl 2 m, 3 m, 5 m, 10 m, 20 m, 30 m
e
Leng
th
Inner 0.52 mm
Diam
eter
Num 2 cores/pair
ber
of
Cores
3.5.9 Fiber Jumpers
Overview
A fiber jumper consists of one or more optical fibers of a certain length and the
optical connectors at both ends. A fiber jumper connects an optical module to a
fiber terminal box.
NO TE
The MPO-MPO optical fibers for routers use type B connectors (Key Up/Key Up).
Comply with the following rules when selecting fiber jumpers:
1. Determine the length of fiber jumpers based on the onsite cabling distance.
2. Determine the fiber type based on the optical module type.
– Use a multimode fiber jumper for a multimode optical module.
– Use a single-mode fiber jumper for a single-mode optical module.
3. Determine the optical connector type based on the port type.
Ensure that the optical connector at each end of a fiber jumper is of the same
type as the port to which it will be connected.
NO TICE
The optical transmission module of the multi-transverse mode needs to be
connected to the multimode fiber. The optical transmitting module of the single-
longitudinal mode or multi-longitudinal mode needs to be connected to the
single-mode fiber.
Optical Fibers
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Optical fibers are classified into single-mode fibers and multimode fibers.
● Single-mode fibers have a diameter of 5 to 10 μm and transmit laser in a
single mode with a specified wavelength. These fibers support a wide
frequency band and a large transmission capacity, so they are used for long-
distance transmission. Most single-mode fibers are yellow, as shown in Figure
3-44.
● Multimode fibers have a diameter of 50 or 62.5 μm and transmit laser in
multiple modes with a specified wavelength. They have a small capacity and
their performance is inferior to that of single-mode fibers, making them
suitable to short-distance transmission.
In the latest cabling infrastructure of ISO/IEC 11801, multimode fibers are
classified into four categories: OM1, OM2, OM3, and OM4.
– OM1: traditional 62.5/125 μm multimode fibers. OM1 fibers have a large
core diameter and numerical aperture, and provide high light gathering
ability and bending resistance.
– OM2: traditional 50/125 μm multimode fibers. OM2 fibers have a small
core diameter and numerical aperture. Compared with OM1 fibers, OM2
fibers provide higher bandwidth because they significantly reduce the
modal dispersion. When transmitting data at 1 Gbit/s with 850 nm
wavelength, OM1 and OM2 fibers support maximum link lengths of 220
m and 550 m, respectively. These two types of fibers can provide
sufficient bandwidth within a distance of 300 m. Generally, OM1 and
OM2 fibers are orange, as shown in Figure 3-45.
– OM3: next-generation multimode fibers, with longer transmission
distances than OM1 and OM2 fibers.
– OM4: laser optimized multimode fibers with 50 μm core diameter. OM4
is an improvement to OM3 and only increases the modal bandwidth.
OM4 fibers provide 4700 MHz*km of modal bandwidth, whereas OM3
fibers provide only 2000 MHz*km of modal bandwidth. Generally, OM3
and OM4 fibers are light green, as shown in Figure 3-46. You can identify
OM3 and OM4 fibers by their labels or printed marks.
MPO fibers are used for 40G and 100G optical modules. An MPO fiber consists of
multiple multimode fiber cores, and each multimode fiber core provides one laser
transmission channel. Some fiber suppliers produce 8-strand MPO fibers, while
some suppliers produce 12-strand or 24-strand MPO fibers.
● A 40G optical module uses four channels to transmit laser and four channels
to receive laser. That is, a total of eight channels are required for a 40G
optical module. 8-strand and 12-strand MPO fibers use the same definition of
fiber channels. Therefore, they are equivalent in functionality when
connecting to 40G optical modules.
● When 100G optical modules are used, choose MPO fibers according to the
optical module form factor. Choose 8-strand or 12-strand fibers for QSFP28
optical modules with MPO connectors.
Optical Connectors
Optical connectors are used to connect optical fibers of the same type. Table
3-208 lists common optical connectors.
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Table 3-208 Common optical connectors
Connector Optical Connector
Type
Square SC/PC LC/PC MTRJ/PC MPO
connector connector connector connector connector
Round FC/PC ST/PC - -
connector connector connector
Figure 3-43 shows an LC/PC optical connector.
Figure 3-43 LC/PC optical connector
NO TICE
When connecting or removing an LC/PC optical connector, align the connector
with the optical port and do not rotate the fiber. Pay attention to the following
points:
● To connect a fiber, align the optical connector with the optical port and gently
insert the optical fiber into the port.
● To remove a fiber, press the clip on the connector, push the connector inward
slightly, and pull the fiber out.
Appearance
Figure 3-44 shows the appearance of an LC single-mode fiber.
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Figure 3-44 Appearance of an LC single-mode fiber
Figure 3-45 shows the appearance of an LC multimode fiber.
Figure 3-45 Appearance of an LC multimode fiber
Figure 3-46 shows the appearance of an MPO-MPO fiber.
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Figure 3-46 Appearance of an MPO-MPO fiber
Figure 3-47 shows the appearance of an MPO-4*DLC fiber.
Figure 3-47 Appearance of an MPO-4*DLC fiber
Pin Assignments of an MPO-4*DLC fiber
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Figure 3-48 Structure of an MPO-4*DLC fiber
Table 3-209 Pin assignments of an MPO-4*DLC fiber
X1 Pin X2 Pin
1 1B
2 2B
3 3B
4 4B
9 4A
10 3A
11 2A
12 1A
NO TE
If the X1 end port is down but the X2 end port is up, check the X1 end port.
● Check whether this port supports the breakout function. If the X1 end port does not
support the breakout function, replace it with another port that supports the breakout
function.
● Check whether the X1 end port is in the breakout state. If the X1 end port is not in the
breakout state, configure the port to be in the breakout state.
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Technical Specifications
Table 3-210 Breakout fibers supported
Part Number Model Description Mode
14132537-005 SS-OP- Optical Cable Multimode
MPO12-4*DLC- Parts,MPO/
M-15B PC,4DLC/
PC,MULTI-
MODE,15m,8
CORES,0/1m,GJFH
-8A1A.2(OM3),3.5
mm,2mm,LSZH,43
MM SHORT
MPO,BENDING
INSENSITIVE
14132537-006 SS-OP- Optical Cable Multimode
MPO12-4*DLC- Parts,MPO/
M-30 PC,4DLC/
PC,MULTI-
MODE,30m,8
CORES,0/1m,GJFH
-8A1A.2(OM3),3.5
MM,2mm,LSZH,4
3MM SHORT
MPO,BENDING
INSENSITIVE
14132538 MPO12-4DLC- Optical Cable Single-mode
SM-15 Parts,MPO/
APC,4DLC/
PC,Single
mode,15m,8
cores,0m/
1m,GYFH-8G.657
A2,3.5mm,2mm,L
SZH,43mm short
MPO,Bending
insensitive
3.6 Fiber Breakout
3.6.1 Breakout Fibers
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Positioning
Breakout fibers are used to flexibly allocate bandwidth resources to routers. They
cooperate with a breakout optical module to convert an MPO interface into
multiple LC interfaces to facilitate fiber layout.
Usage Scenario
The breakout function applies to a scenario where bandwidth resources are
unevenly allocated between two routers at different levels. In comparison with
breakout boxes, breakout fibers implement the following functions:
● Loosen fiber layout.
● Extend the cabling distance.
Fiber Structure
To insert a breakout optical module (multimode and short transmission distance)
into a port, use an MPO-LC fiber to directly connect the optical module.
Figure 3-49 MPO-LC fiber structure
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NO TE
When using a breakout optical fiber, insert the X1 end into a 40GE QSFP+ optical module
and the X2 end into four 10GE interfaces. If the 40GE interface is Down but the four 10GE
interfaces are Up, check the 40GE interface status.
● Check whether the 40GE interface supports the breakout function. If the 40GE interface
does not support the breakout function, replace it with another interface that supports
the breakout function.
● Check whether the 40GE interface is in the breakout state. If the 40GE interface is not in
the breakout state, configure the 40GE interface to be in the breakout state.
Technical Specifications
Table 3-211 lists the breakout fibers.
Table 3-211 Breakout fibers supported
Type BOM Number Offi Mode
cial
Na
me
Optical Cable 14134759 MP Single mode
Parts,MPO/APC,MPO/ O1
APC,Single 2-
mode,10m,8 MP
cores,GJFH-8G.657A2,3 O1
.5mm,LSZH,43mm 2-
Short MPO,Bending SM-
insensitive 10
Optical Cable 14132538 MP Single mode
Assembly,MPO/ O1
APC,4*DLC/ 2-4
PC,Singlemode,GJFH DLC
8G.657A2(LSZH),15m, -
3.5mm,8 Cores,0m/ SM-
1m,2mm 15
Optical Cable 14132537 SS- Multimode
Parts,MPO/PC,4DLC/ OP-
PC,Multi-mode,5m,8 MP
cores,0/1m,GJFH-8A1a. O1
2(OM3),3.5mm,2mm,L 2-4*
SZH,43mm Short DLC
MPO,Bending -
insensitive M-5
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Type BOM Number Offi Mode
cial
Na
me
Optical Cable 14132537-005 SS- Multimode
Parts,MPO/PC,4DLC/ OP-
PC,Multi-mode,15m,8 MP
cores,0/1m,GJFH-8A1a. O1
2(OM3),3.5mm,2mm,L 2-4*
SZH,43mm Short DLC
MPO,Bending -
insensitive M-1
5B
Optical Cable 14132537-006 SS- Multimode
Parts,MPO/PC,4DLC/ OP-
PC,MULTI- MP
MODE,30m,8 O1
CORES,0/1m,GJFH-8A1 2-4*
A.2(OM3),3.5MM,2mm DLC
,LSZH,43MM SHORT -
MPO,BENDING M-3
INSENSITIVE 0
Optical Cable 14132537-001 SS- Multimode
Parts,MPO/PC,4DLC/ OP-
PC,Multi-mode,100m,8 MP
cores,0/1m,GJFH-8A1a. O1
2(OM3),3.5mm,2mm,L 2-4*
SZH,43mm Short DLC
MPO,Bending -
insensitive M-1
00
Optical Cable 14136626 MP Single mode
Parts,MPO/APC,8FC/ O1
UPC,SINGLE 2-4
MODE,15m,8 DFC
CORES,0/1m,GJFH-8G. -
657A2,3.5mm,2mm,LS SM-
ZH,43MM SHORT 15
MPO,BENDING
INSENSITIVE
Optical Cable 14136627 MP Single mode
Parts,MPO/APC,8SC/ O1
UPC,SINGLE 2-4
MODE,15m,8 DSC
CORES,0/1m,GJFH-8G. -
657A2,3.5mm,2mm,LS SM-
ZH,43MM SHORT 15
MPO,BENDING
INSENSITIVE
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Table 3-212 lists the optical modules and ports mapping breakout fibers.
Table 3-212 Optical modules and boards mapping breakout fibers
Breakout Fiber Optical Module Board
[14134759/MPO12- [02311NUA/ Check the Hardware
MPO12-SM-10] Optical OSM010N11] High Description. If the
Cable Parts,MPO/ Speed Transceiver,QSFP description of a port
APC,MPO/APC,Single +,1310,41.25Gbps,-8.2dB contains QSFP28 or
mode,10m,8 m,0.5dBm,-12.6dBm,MP QSFP+ and supports the
cores,GJFH-8G.657A2,3.5 O,SM,10km breakout function, the
mm,LSZH,43mm Short optical module and
MPO,Bending insensitive breakout fiber can be
used together with the
[14132538/ port.
MPO12-4DLC-SM-15]
Optical Cable
Assembly,MPO/
APC,4*DLC/
PC,Singlemode,GJFH
8G.657A2(LSZH),15m,3.5
mm,8 Cores,0m/
1m,2mm
[14136626/
MPO12-4DFC-SM-15]
Optical Cable
Parts,MPO/APC,8FC/
UPC,SINGLE
MODE,15m,8
CORES,0/1m,GJFH-8G.65
7A2,3.5mm,2mm,LSZH,4
3MM SHORT
MPO,BENDING
INSENSITIVE
[14136627/
MPO12-4DSC-SM-15]
Optical Cable
Parts,MPO/APC,8SC/
UPC,SINGLE
MODE,15m,8
CORES,0/1m,GJFH-8G.65
7A2,3.5mm,2mm,LSZH,4
3MM SHORT
MPO,BENDING
INSENSITIVE
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Breakout Fiber Optical Module Board
[14132537/SS-OP- [02310WUU/
MPO12-4*DLC-M-5] OMXD30010] Optical
Optical Cable Transceiver,QSFP
Parts,MPO/PC,4DLC/ +,850nm,41.25Gbps,-7.6d
PC,Multi-mode,5m,8 Bm,-1dBm,-9.5dBm,MPO,
cores,0/1m,GJFH-8A1a.2( MMF,0.15km
OM3),3.5mm,2mm,LSZH,
43mm Short
MPO,Bending insensitive
[14132537-005/SS-OP-
MPO12-4*DLC-M-15B]
Optical Cable
Parts,MPO/PC,4DLC/
PC,Multi-mode,15m,8
cores,0/1m,GJFH-8A1a.2(
OM3),3.5mm,2mm,LSZH,
43mm Short
MPO,Bending insensitive
[14132537-006/SS-OP-
MPO12-4*DLC-M-30]
Optical Cable
Parts,MPO/PC,4DLC/
PC,MULTI-MODE,30m,8
CORES,0/1m,GJFH-8A1A.
2(OM3),3.5MM,2mm,LS
ZH,43MM SHORT
MPO,BENDING
INSENSITIVE
[14132537-001/SS-OP-
MPO12-4*DLC-M-100]
Optical Cable
Parts,MPO/PC,4DLC/
PC,Multi-mode,100m,8
cores,0/1m,GJFH-8A1a.2(
OM3),3.5mm,2mm,LSZH,
43mm Short
MPO,Bending insensitive
[14132537/SS-OP- [02311NTY/
MPO12-4*DLC-M-5] OMND10N13] High
Optical Cable Speed
Parts,MPO/PC,4DLC/ Transceiver,QSFP28,850n
PC,Multi-mode,5m,8 m,100G,-8.4dBm,2.4dBm,
cores,0/1m,GJFH-8A1a.2( -10.3dBm,MPO,MM,0.1k
OM3),3.5mm,2mm,LSZH, m,OM4
43mm Short
MPO,Bending insensitive
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Breakout Fiber Optical Module Board
[14132537-005/SS-OP-
MPO12-4*DLC-M-15B]
Optical Cable
Parts,MPO/PC,4DLC/
PC,Multi-mode,15m,8
cores,0/1m,GJFH-8A1a.2(
OM3),3.5mm,2mm,LSZH,
43mm Short
MPO,Bending insensitive
[14132537-006/SS-OP-
MPO12-4*DLC-M-30]
Optical Cable
Parts,MPO/PC,4DLC/
PC,MULTI-MODE,30m,8
CORES,0/1m,GJFH-8A1A.
2(OM3),3.5MM,2mm,LS
ZH,43MM SHORT
MPO,BENDING
INSENSITIVE
NO TE
Characters in the brackets indicate the BOM number and official name that are separated
using a slash ("/") in the [BOM number/Official name] format.
3.6.2 Breakout Boxes
3.6.2.1 Product Overview
Positioning
Breakout boxes are used to flexibly allocate bandwidth resources to routers. They
cooperate with a breakout optical module and optical jumper to convert an MPO
interface into multiple LC interfaces to facilitate fiber layout.
Product Features
● LC interfaces support automatic dust-proof covers, and MPO interfaces
support dust-proof plugs.
● In comparison with breakout fibers (MPO-LC fibers), breakout boxes feature
more flexible fiber layout.
● There is no restriction on the installation direction of breakout boxes, so that
the breakout boxes can be installed positively or negatively as needed.
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Usage Scenario
The breakout function applies to a scenario where bandwidth resources are
unevenly allocated between two routers at different levels. In comparison with
breakout fibers, breakout boxes implement the following functions:
● Increase the density of fiber layout.
● Shorten the cabling distance.
Figure 3-50 Breakout box cabling
3.6.2.2 10-Port-MPO-12-40-Port-LC-Breakout Box(single-mode)
Appearance
Figure 3-51 10-Port-MPO-12-40-Port-LC-Breakout Box(single-mode)
Components
Figure 3-52 10-Port-MPO-12-40-Port-LC-Breakout Box(single-mode)
1. MPO adapter 2. LC adapter 3. Mounting ear
MPO adapters map LC adapters according to their numbers displayed on the
panel. Figure 3-53 shows the mapping between MPO and LC adapters.
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Figure 3-53 Mapping between MPO and LC adapters
MPO-12 Jumper
The TYPE-B MPO jumper is used. The following figure shows the MPO-12 jumper
structure and line orders of X1 and X2 ports.
Table 3-213 describes the mappings between the lanes of the X1 and X2 ports.
Table 3-213 Mappings between the lanes of the X1 and X2 ports
Start End Start End
X1-1 X2-12 X1-7 /
X1-2 X2-11 X1-8 /
X1-3 X2-10 X1-9 X2-4
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Start End Start End
X1-4 X2-9 X1-10 X2-3
X1-5 / X1-11 X2-2
X1-6 / X1-12 X2-1
Technical Specifications
Table 3-214 Technical specifications of the 10-Port-MPO-12-40-Port-LC-Breakout
Box (single-mode)
Item Description
BOM Number 02082890
Official Name ODBS10040
Dimensions (H x W x D) 43.6 mm x 442 mm x 164 mm
Mounting ear 19-inch supported
Weight 2.3 kg
Insertion loss ≤ 0.75 db
Return loss Single-mode: ≥ 30 db
Operating temperature –40°C to +65°C
Storage temperature –40°C to +70°C
Relative operating humidity ● Long term: 5% RH to 85% RH, non-
condensing
● Short term: 5% RH to 95% RH,
non-condensing
Relative storage humidity 0% RH to 95% RH, non-condensing
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Table 3-215 Optical modules, jumpers, and ports supported by the 10-Port-
MPO-12-40-Port-LC-Breakout Box (single-mode)
Optical Module MPO-MPO Fiber Port
[02311NUA/ [14134759/MPO12- Supported boards:
OSM010N11] Function MPO12-SM-10] Optical Check the Hardware
Module,OSM010N11,Hig Cable Parts,MPO/ Description. If the
h Speed Transceiver,QSFP APC,MPO/APC,Single description of a port
+,1310,41.25Gbps,-8.2dB mode,10m,8 contains QSFP28 or QSFP
m,0.5dBm,-12.6dBm,MP cores,GJFH-8G.657A2,3.5 + and and supports the
O,SM,10km mm,LSZH,43mm Short breakout function, the
MPO,Bending insensitive optical module and
breakout fiber can be
used together with the
port.
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4 Hardware Installation and Parts
Replacement
4.1 Hardware Installation and Maintenance Guide of NetEngine 8000 F1A-8H20Q
4.1 Hardware Installation and Maintenance Guide of
NetEngine 8000 F1A-8H20Q
4.1.1 Hardware Installation and Usage Precautions
Following All Safety Precautions
● To ensure human and device security, comply with all the safety precautions
marked on the device and instructed in this document before any operation.
The CAUTION, WARNING, and NOTE items in this document do not cover all
the safety precautions that must be obeyed. They are supplements to the
safety precautions.
● When operating Huawei products and equipment, comply with safety
precautions and special safety instructions relevant to the corresponding
equipment provided by Huawei. The safety precautions in this document are
only some that Huawei can predict. Huawei is not liable for any consequence
that results from violation of universal regulations for safety operations and
safety codes on design, production, and equipment use.
Complying with Local Rules and Regulations
When operating a device, comply with local laws and regulations.
Installation Personnel Requirement
Installation and maintenance personnel must be trained to perform operations
correctly and safely.
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Personnel Safety
● A high-voltage power supply provides power for device operations. Direct
human contact with the high voltage power supply or human contact through
damp objects can be fatal.
● Unspecified or unauthorized high voltage operations could result in fire or
electric shock, or both.
● Ground a device before powering it on; otherwise, the human body and the
device are exposed to danger.
● Before performing operations on the power supply facilities, power off these
facilities.
● Do not look into the optical port without eye protection when handling
optical fibers.
● To protect human respiratory organs and human eyes from dust, take
protective measures when drilling holes.
● When working at heights, prevent objects from falling down.
Device Security
● Keep an unpacked device upright and handle it with care when carrying it or
installing it into a cabinet.
● Use a ladder to lay out cables. Do not trample on a device.
● Wear an ESD wrist strap or ESD gloves when handling circuit boards.
Otherwise, the static electricity discharged from the human body may
damage the electrostatic sensitive components, such as large-scale integrated
circuits (LSIs) on the circuit board.
● Before operating the device, check the electrical connection of the device, and
ensure that the device is properly grounded.
Chassis
Filler panels must be installed in vacant slots to ensure the device functions
correctly. For example, they ensure electromagnetic compatibility, prevent the
ingress of dust or foreign objects, and maintain proper airflow for heat dissipation.
Power Module
● After a power module enters the protection state, it cannot supply power. If
the power module cannot automatically resume power supply after the
triggering condition of the protection state is removed, remove the power
module from the chassis and reinstall it at least 30s later. The power module
then can work properly.
● When a power module enters overtemperature protection state, take
measures to lower the temperature of the chassis. The power module can
automatically resume power supply when the temperature falls within the
normal range.
Cable
● To protect personal safety, do not install power cables when the power is on.
Before connecting power cables, make sure that the power switches of the
external power supply system and the device are all in OFF position.
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● Before connecting signal cables, take ESD protection measures, for example,
wear ESD gloves or an ESD wrist strap.
● Before connecting Ethernet cables, use an Ethernet cable tester to test cable
connectivity.
● Both ends of an idle high-speed cable must be covered by an ESD cap.
● The bend radius of high-speed cables must be larger than the minimum bend
radius. Overbending high-speed cables may damage wires in the cables.
● Laser beams will cause eye damage. Do not look into bores of optical
modules or optical fibers without eye protection.
● Cover idle optical ports and optical modules with dust plugs and cover idle
optical fibers with dust caps.
● Bundle optical fibers with binding tape. Apply appropriate force to ensure that
the optical fibers in a bundle can be moved easily.
● Fiber connectors must be tidy and clean to ensure normal communication. If
a fiber connector is contaminated, clean it using a piece of fiber cleaning
fabric.
Optical Module
● Devices must use optical modules that are certified for Huawei devices.
Optical modules that are not certified for Huawei devices cannot ensure
transmission reliability and may affect service stability. Huawei is not liable
for any problems caused by the use of optical modules that are not certified
for Huawei devices.
● The transmit power of a long-distance optical module is often larger than its
overload power. Therefore, when using such optical modules, select optical
fibers of an appropriate length to ensure that the actual receive power is
smaller than the overload power. If the optical fibers connected to a long-
distance optical module are too short, use an optical attenuator to reduce the
receive power on the remote optical module. Otherwise, the remote optical
module may be burnt.
4.1.2 Introduction to the A66E Cabinet
Naming Conventions
Figure 4-1 shows the naming conventions of the A66E cabinet.
Figure 4-1 Cabinet name
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Table 4-1 Cabinet naming conventions
Field Description
1 ALPEN, indicating the cabinet appearance series
2 Cabinet width: 600 mm
3 Cabinet depth: 600 mm
4 Enforce, indicating an enhanced performance model (Base, indicating a
basic performance model)
Appearance
Figure 4-2 shows the A66E cabinet appearance.
Figure 4-2 Cabinet appearance
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Physical Structure
Figure 4-3 shows components of the A66E cabinet.
Figure 4-3 Cabinet components
1. Front door 2. Top cover 3. Rear door 4. Side panel
(installed on the
side with a chassis
header)
5. Mounting rail 6. Rack - -
Functions and Features
The cabinet is made of class-A high-strength carbon cold rolled steel and
galvanized sheet, which complies with the Restriction of the use of certain
Hazardous Substances (RoHS). The fire endurance of interior materials complies
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with Underwriter Laboratories (UL) standards. The distance between front and
rear mounting rails is adjustable in 25 mm increments. Its assembled architecture
facilitates capacity expansion.
The cabinet has the following features and functions:
● Overhead and underfloor cabling
● Sufficient space to place and connect components
● Ability in protecting internal components from contamination
● Ability in preventing damage to internal components
Heat Dissipation
The front and rear doors of the cabinet are of mesh construction. Air enters the
chassis from the front door and base and is exhausted through the rear door.
Figure4 shows the airflow.
Figure 4-4 Airflow in the cabinet
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Technical Specifications
Table 4-2 Technical specifications of the A66E cabinet
Item Details
Dimensions without 2200 mm x 600 mm x 600 mm (86.61 in. x 23.62 in. x
packaging (H x W x 23.62 in.)
D)
Dimensions with 2340 mm x 710 mm x 860 mm (92.13 in. x 27.95 in. x
packaging (H x W x 33.86 in.)
D)
Weight (empty, 96 kg (211.64 lb)
without packaging)
Weight (assembly 156 kg (343.92 lb)
cabinet, with
packaging)
Standards IEC60297
compliance
Distance between 381.25mm
mounting rails
Available space 47U
Installation scenario Indoor installation
Installation mode Installation on a concrete floor or ESD floor
Part number 02116432
4.1.3 Cabinet Accessories
4.1.3.1 (Optional) Cabinet Stand
Appearance
The cabinet stand is pictured in Figure 4-5.
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Figure 4-5 Cabinet stand
Functions
The stand elevates and supports the cabinet.
Technical Specifications
Table 4-3 lists technical specifications of the cabinet stand.
Table 4-3 Technical specifications of the cabinet stand
Stand Type Applicable ESD Floor Wi Applicable Chassis
Height (mm) dth Depth (mm)
(m
m)
Stand I 200–270 600 1000, 1100, and 1200
Stand II 270–410
Stand III 410–700
NO TE
The ESD floor height is the distance between the upper surface of the ESD floor and the
surface of the concrete floor.
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4.1.4 A66E Cabinet Installation
4.1.4.1 Installing the Cabinet on the Concrete Floor
4.1.4.1.1 Removing the Ground Cables and Cabinet Doors
NO TE
Before removing the ground cables and cabinet doors, remove the marking-off template
and concrete mounting kits.
1. Removing the ground cables from the front door and rear door. One end of
the ground cable is connected with the cabinet door.
2. Pull down the hook pin at the upper part of the door panel.
3. Remove the front door.
4. Follow the same steps to remove the rear door.
Figure 4-6 Removing the ground cable and door
NO TE
For the coming use, put away the front and rear doors of the cabinet and bolts.
4.1.4.1.2 Determining the Installation Position of the Cabinets
1. Positioning the cabinet.
a. Attach the plumb line to the cable rack that is vertical to the front of the
cabinet. Use the marker to mark the point of the plumb on the ground.
b. Follow the same procedure to mark the second point, and draw the
baseline by using the powder marker.
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Figure 4-7 Positioning the cabinet
NO TE
The method for positioning the cabinet described in this document is only for
reference. Follow the engineering drawing to position the cabinet in the actual
installation.
2. Determining installation holes for the cabinet.
Figure 4-8 Determining installation holes for the cabinet
NO TE
The spacing between the rear door of the front access cabinet and the wall or any
other obstacles should be no less than 100 mm.
3. Confirming the position of the drill holes.
a. Lay out the templates side by side and ensure that there is 600 mm
between the center lines of two adjacent templates.
b. Use a marker to mark installation holes on the concrete floor.
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Figure 4-9 Confirming the position of the drill holes
NO TE
Position the template so that the semicircular gap indicates the front of the
cabinet.
After marking the reference lines, check the hole positions with a ruler.
4.1.4.1.3 Installing Expansion Bolts
1. Fasten the expansion bolt clockwise untill the guide rib is fixed on the guide
trough.
2. Put the expansion bolt vertically into the hole. Use a claw hammer to strike
the expansion tube into the hole completely.
3. Fasten the expansion bolt clockwise until the nut is firmly inserted into the
expansion tube.
4. Turn the expansion bolt counterclock-wise and remove the expansion bolt,
spring washer, and flat washer in turn.
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Figure 4-10 Installing expansion bolts
4.1.4.1.4 Installing the Cabinet
1. Placing the cabinet.
a. Place the cabinet on the specified position, and align the installation
holes of the cabinet with the holes on the floor.
b. Fix the spring washer, flat washer and insulation tube on the expansion
bolt. Insert them into the holes and tighten the four expansion bolts a
bit, but do not fasten them.
c. Lift one side of the cabinet and insert the insulation plate under the
cabinet. Insert another insulation plate under the other side of the
cabinet. Ensure that the gaps properly lock the expansion bolts.
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Figure 4-11 Placing the cabinet
4.1.4.1.5 Leveling the cabinet and testing the insulation
1. Leveling and fixing the cabinet.
a. Remove the four adjusting bolts attached on the bottom enclosure frame,
install them on the adjusting nuts.
b. Check whether the cabinet is horizontal or vertical by using a spirit level
and a plumb line respectively.
c. If the cabinet is not horizontal, adjust the adjusting bolts by using a
socket wrench.
d. When the cabinet is horizontal, fasten the four expansion bolts to 45
N·m.
Figure 4-12 Leveling and fixing the cabinet
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NO TE
The adjustment range of adjusting anchor is from 0 mm to 10 mm.
2. Testing the insulation of the cabinet.
a. Set the multimeter to read mega ohms.
b. Measure the resistance between the expansion bolt and the ground bolt
of the rack, the measured resistance is more than five mega ohms.
Figure 4-13 Testing the insulation of the cabinet
NO TE
If the measured resistance is less than five mega ohms, check whether any
insulation part is damaged or not installed. Measure the resistance again.
Otherwise, remove all components, install and fasten the cabinet again.
4.1.4.1.6 Attaching the cabinets
1. Remove the connection plates on the lintels of the front and rear doors and
install them again as shown in the figure.
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Figure 4-14 Installing the connection plates
2. Use the spirit level and the plumb line to verify that the bottom line of the
cabinet is horizontal and the front line of the column is vertical. If the cabinet
is not horizontal, adjust the adjusting anchor by using a socket wrench.
Figure 4-15 Leveling the cabinet
NO TE
Both the gap between cabinets and the vertical deviation should be less than 3 mm.
4.1.4.1.7 Installing cabinet doors
NO TE
Install the cabinet door after the inside components and cables. To install the components
inside the cabinets and cables, see the Installaiton Guide.
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1. Installing the cabinet doors.
a. Align the door with the front face of the column.
b. Place the door on the lower lintel and close the door till the lower pin
automatically inserts into the hole in the lower lintel.
c. Press the spring pin with your finger and push the upper part of the door
till the spring pin properly inserts in the installation hole at the top of the
lintel.
d. Check the spring pin and lower pins and ensure that the door is properly
installed.
e. To install the rear door, see the front door installation.
Figure 4-16 Installing the cabinet doors
2. Install the ground cables at the front doors and rear doors as shown in the
figure.
Figure 4-17 Installing the ground cables
4.1.4.2 Installing the Cabinet on the ESD Floor
4.1.4.2.1 Removing the Ground Cables and Cabinet Doors
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NO TE
Before removing the ground cables and cabinet doors, remove the marking-off template
and concrete mounting kits.
1. Remove the ground cables from the front door and rear door. One end of the
ground cable is connected with the cabinet door.
2. Pull down the hook pin at the upper part of the door panel.
3. Remove the front door.
4. Follow the same steps to remove the rear door.
Figure 4-18 Removing the ground cables and doors
NO TE
For the coming use, put away the front and rear doors of the cabinet and bolts.
4.1.4.2.2 Determining the Installation Position of the Supports
1. Positioning the cabinet.
Figure 4-19 Positioning the cabinet
NO TE
The spacing between the rear door of the front access cabinet and the wall or any
other obstacles should be no less than 100 mm.
2. Determining installation holes for the cabinet.
a. Lay out the templates side by side and ensure that there is 600 mm
between the center lines of two adjacent templates.
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b. Use a marker to mark installation holes on the concrete floor.
Figure 4-20 Determining installation holes for the cabinet
NO TE
Position the template so that the semicircular gap indicates the front of the
cabinet.
After marking the reference lines, check the hole positions with a ruler.
4.1.4.2.3 Installing Expansion Bolts
1. Fasten the expansion bolt clockwise until the guide rib is fixed on the guide
trough.
2. Put the expansion bolt vertically into the hole. Use a claw hammer to strike
the expansion tube into the hole completely.
3. Fasten the expansion bolt clockwise until the nut is firmly inserted into the
expansion tube.
4. Turn the expansion bolt counterclockwise and remove the expansion bolt,
spring washer, and flat washer in tum.
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Figure 4-21 Installing expansion bolts
4.1.4.2.4 Installing Supports
1. Adjusting the height of supports.
a. Use a ruler to measure the distance between the concrete floor and the
upper surface of the antistatic floor.
b. Adjust the support to the required height based on the measurement
results and the scale on the support.
c. Partially tighten the height locking bolts on both sides.
Figure 4-22 Adjusting the height of supports.
2. Assembling the Support.
a. Adjust the telescopic rod based on the cabinet depth until the scale
indicating the cabinet length is displayed.
b. Use a torque socket to secure the 6 M8x20 screw assemblies on the
telescopic rods to 13 N·m.
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c. Assemble the telescopic rod and support by using eight M8x20 screw
assemblies and ensure that the protruding side of the guide rail faces
outwards. Then tighten all screw assemblies using a torque socket to a
torque of 13 N·m.
d. Use a level to check the levelness of the support.
e. If the support is not horizontal, loosen the bolt and slightly adjust the
support till it is level.
f. Use a torque socket to secure all the bolts that are used to fix the height
to 45 N·m.
Figure 4-23 Assembling the Support
3. Installing a Single Support.
a. Align the four mounting holes of the support with the four expansion
bolt holes on the floor and secure four expansion bolts
b. Adjust the position of the support and use a level to measure the
levelness of the support.
c. If the support is not level, place shims under the support.
d. Use a torque socket to fasten the four expansion bolts to 45 N·m.
e. Assemble the combining parts to support by using two M8x20 screw
assemblies tighten to a torque of 13 N·m.
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Figure 4-24 Installing a Single Support
4. Installing the supports in a row.
a. Combine other supports with the first support using combining parts.
Ensure that the fronts of all supports are in the same line and the centers
of adjacent combining parts are 600 mm away from each other. Use a
torque socket to secure the M8x20 screw assemblies on the telescopic
rods to 13 N·m.
b. Check the support levelness by using a level.
c. If the support is not level, place spacers under the support.
d. Tighten all expansion bolts using a torque socket to a torque of 45 N·m.
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Figure 4-25 Installing the supports in a row
4.1.4.2.5 Installing the Cabinet
1. Placing the cabinet.
a. Place the cabinet on the slide rails, and align the installation holes of the
cabinet with the holes of the slide rails.
b. Fit the spring washer, flat washer and insulation tube on the four M12x40
bolts. Insert them into the installation holes and tighten the bolts a bit,
but do not fasten them.
c. Lift one side of the cabinet and insert the insulation plate under the
cabinet. Insert another insulation plate under the other side of the
cabinet. Ensure that the gaps properly lock the expansion bolts.
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Figure 4-26 Placing the cabinet
2. Leveling and fixing the cabinet.
a. Remove the four adjusting bolts attached on the bottom enclosure frame,
install them on the adjusting nuts.
b. Check whether the cabinet is horizontal or vertical by using a spirit level
and a plumb line respectively.
c. If the cabinet is not horizontal,use a socket wrench to screw the adjusting
bolts at the bottom.
d. Lift one side of the cabinet and insert when the cabinet is horizontal,
screw the four M12x40 bolts to 45 N·m with a torque wrench.
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Figure 4-27 Leveling and fixing the cabinet
4.1.4.2.6 Testing the Insulation and Installing the Front Pallet
1. Testing the insulation of the cabinet.
a. Set the multimeter to read mega ohms.
b. Measure the resistance between the M12x40 bolt and the ground bolt of
the rack, the measured resistance is more than five mega ohms.
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Figure 4-28 Testing the insulation of the cabinet
2. Installing the floor support bracket.
Fix the floor support bracket on the support by using the M12x25 assembly
bolts.
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Figure 4-29 Installing the floor support bracket
4.1.4.2.7 Attaching the Cabinets and Restoring the ESD Floor
1. Installing the connection plates.
a. Remove the connection plates on the lintels of the front and rear doors
and install them again as shown in the figure.
Figure 4-30 Installing the connection plates
b. Use the spirit level and the plumb line to verify that the bottom line of
the cabinet is horizontal and the front line of the column is vertical. If the
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cabinet is not horizontal, adjust the adjusting anchor by using a socket
wrench.
Figure 4-31 Leveling the cabinet
NO TE
Both the gap between cabinets and the vertical deviation should be no less than
3 mm.
2. Restoring the ESD floor.
Figure 4-32 Restoring the ESD floor
NO TE
The ESD floor has been removed before you determine the installation position of the
supports. Cut the ESD floor according to the size of the cabinet.
For underfloor cabling, place the cables before you restore the ESD floor.
4.1.4.2.8 Installing Cabinet Doors
1. Installing the cabinet doors.
NO TE
Install the cabinet door after the inside components and cables. To install the
components inside the cabinets and cables, see the Installation Guide.
a. Align the door with the front face of the column.
b. Place the door on the lower lintel and close the door till the lower pin
automatically inserts into the hole in the lower lintel.
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c. Press the spring pin with your finger and push the upper part of the door
till the spring pin properly inserts in the installation hole at the top of the
lintel.
d. Check the spring pin and lower pins and ensure that the door is properly
installed.
e. Follow the same steps to install the rear door.
Figure 4-33 Installing the cabinet doors
2. Installing the ground cables at the front doors and rear doors as shown in the
figure.
Figure 4-34 Installing the ground cables
4.1.5 Device Installation Process
This section describes the general device installation process. Before installing
device, you need to determine the installation mode according to installation
environment. After unpacking and inspecting the device, you need to install the
chassis, boards, fibers, and cables in sequence, and then check the installation
result. After determining that the installation is correct, you can power on the
device and then check fiber connections.
Table 4-4 lists the general installation process.
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Table 4-4 Device installation process
Installation Process Description
Preparing for the Before installing a device, plan and construct the
installation installation space and confirm the installation method
based on the requirements of device operation
environment. This is a prerequisite for smooth
installation, commissioning, and stable running of the
device. For details, see section " Hardware Installation
and Maintenance - Preparation before installation."
Unpacking a device After the project starts, the project supervisor should
unpack and check the device together with the customer
representative. For details, see section "Hardware
Installation and Maintenance- Preparing before
installation - Unpacking a Device."
Installing a chassis The installation method of the chassis varies according
to the installation environment. For details, see section
"Hardware Installation and Maintenance - Installing a
Chassis in Cabinet."
Installing Generally, the components are installed in the chassis. If
components the components are delivered separately, see section
"Hardware Installation and Maintenance - Installing of
Components."
Planning cable To ensure that power cables are connected in order, you
routing are advised to plan power cable routing. For details, see
section "Hardware Installation and Maintenance - Cable
Routing Planning."
Installing cables The methods of installing cables vary according to the
installation environment of the chassis. For details, see
section "Hardware Installation and Maintenance -
Installation of cables."
Checking the To ensure normal and stable running of a device, you
installation need to check the installation of the device after all
hardware is installed. For details, see section "Hardware
Installation and Maintenance - Post-Installation Check."
Performing a power- Before powering on a device, you need to check the
on check voltage and fuse capacity of the external power supply.
After the power-on, you need to check whether the
device is running normally by observing the indicators.
For details, see section "Hardware Installation and
Maintenance - Power-on Check."
Maintaining a device Faulty fuses and other electronic components can only
be replaced by professionals authorized by Huawei. For
details, see section "Hardware Installation and
Maintenance - Maintenance of the device."
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4.1.6 Preparation before installation
4.1.6.1 Reading Carefully the Safety Precautions
Before you start the installation procedure, read all safety precautions described in
this document and observe any warning labels affixed to the device. Doing so
ensures your safety and protects the device from damage.
Safety precautions provided in this document may not cover every eventuality, so
remain mindful of safety at all times.
Huawei is not liable for any consequence that results from violation of regulations
pertaining to safe operations or safety codes pertaining to design, production, and
equipment use.
Only trained and qualified personnel are allowed to install, operate, or maintain
the device. Familiarize yourself with all safety precautions before performing any
operation on the device.
General Safety
CA UTION
● Always take precautions against ESD whenever you handle a device. For
example, wear ESD gloves or an ESD wrist strap. To avoid electric shock or
burn, remove conductive objects like jewelry and watch.
● Connect the ground cable first after installing the device into a cabinet or rack.
Do not remove the ground cable unless all the other cables and modules have
been removed from the device.
NO TICE
● During device transport and installation, prevent the device from colliding with
objects like doors, walls, or shelves.
● Move an unpacked device upright gently to avoid damages to the device. Do
not lay down the unpacked device and drag it.
● Do not touch unpainted surfaces of the device with wet or contaminated
gloves.
● Do not open the ESD bags of cards and modules until they are delivered to the
equipment room. When taking a card out of the ESD bag, do not use the
connector to support the card's weight because this operation will distort the
connector and make the pins on the backplane connector bend.
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Environmental Safety
DANGER
Do not place or operate the device in an environment with flammable or explosive
gases or smoke.
NO TICE
● Keep the device away from sources of water to prevent damages to circuits.
● The installation site must be well ventilated to prevent the device from
overheating.
Electrical Safety
DANGER
● Direct contact with a high-voltage power source or indirect contact through
damp objects can be fatal. Misoperations on high-voltage facilities may result
in fire, electric shock, or other accidents.
● Never install or remove the device or power cables when the power is on. The
electric arc or spark generated between a power cable and conductor may
cause fire or eye damage.
● To protect personal and equipment safety, ground the device before powering it
on.
Laser Safety
CA UTION
● Laser beams will cause eye damage. Do not look into bores of optical modules
or optical fibers without eye protection.
● Cover fiber connectors with dust caps when they are not connected.
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Mechanical Safety
CA UTION
● Wear protective gloves when you are moving the device.
● Use safe lifting practices when moving the equipment. Never attempt to lift
objects that are too heavy for one person to handle. Instead, seek help or use
appropriate tools.
● Before installing the chassis into or removing it from a cabinet, ensure there are
no objects that could fall from the cabinet and cause injury.
● If main control boards, service boards, and power modules have been installed
on the chassis, you are advised to remove them before moving the chassis to
prevent them from falling off and causing injury.
● Do not drill unapproved holes into a cabinet, as doing so may impair its
electromagnetic shielding and damage cables inside. In addition, drilling holes
produces metal shavings that may enter the cabinet and cause short circuits on
printed circuit boards (PCBs).
4.1.6.2 Checking the Installation Site
The Device must be used indoors. To ensure normal operations and long service
life of the device, the installation site must meet the following requirements
described in Table 4-5.
Table 4-5 Requirements for the installation site
Item Requirement
Cleanliness The device must be installed in a clean, dry, and well
ventilated standard equipment room with stable
temperature. The equipment room must be free from
leaking or dripping water, heavy dew, and humidity.
Dust proofing Dustproof measures must be taken in the site. Dust will
cause electrostatic discharges on the chassis and affect
connections of metal connectors and joints. This shortens
service life of the device and may cause failures of the
device.
Temperature and The temperature and humidity in the installation site must
humidity be within specifications. For the operating temperature
and relative humidity ranges required by the device, see
device overview. If the relative humidity exceeds 70% RH,
using dehumidifiers or dehumidifying air conditioners is
recommended.
Corrosive gases The installation site must be free from acidic, alkaline, or
avoidance corrosive gases.
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Item Requirement
Heat dissipation Keep any objects or obstructions at least 75 mm away
space from the air intake and exhaust vents to facilitate heat
dissipation.
Maintenance The equipment must be stacked in the cabinet or installed
space at an interval of 2U or more to prevent the return air from
affecting heat dissipation.
4.1.6.3 Checking the Cabinet
The device can only be installed in a standard 19-inch cabinet. Huawei A66E
cabinet is recommended. If you purchase a cabinet by yourself, ensure that the
cabinet meets the following requirements:
1. 19-inch cabinet with a depth of greater than or equal to 600 mm.
2. The cabling space in front of the cabinet complies with the cabling space
requirements of boards.
NO TE
If a board requires optical modules or attenuators with a puller, GE electrical modules,
or shielded network cables, ensure that sufficient space is available for routing optical
fibers. For a convex door or open rack, it is recommended that the distance between
the cabinet door and the front panel of the board be greater than or equal to 105 mm
(4.13 in.).
3. The device is designed with front-to-back or back-to-front airflow. Prevent the
air intake vent and air exhaust vent from being blocked during installation.
4. The porosity of each cabinet door must be greater than 50%, meeting heat
dissipation requirements of devices.
5. The cabinet has installation accessories, such as guide rails, floating nuts, and
screws.
6. The cabinet has a ground terminal to connect to the device.
7. The cabinet has a cable outlet on the top or at the bottom for overhead or
underfloor cabling.
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Figure 4-35 A66E cabinet
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4.1.6.4 Preparing Installation Tools and Accessories
Table 4-6 lists the tools required for installing a device.
Table 4-6 Installation tools
Tool Description Picture
ESD gloves Used to
prevent
electrostatic
discharges.
Protective Used to
gloves protect hands
during
operation.
ESD wrist Used to
strap prevent
electrostatic
discharges.
Wear the
strap on your
wrist and
insert the
other end into
the ESD jack
on the
cabinet.
Utility knife Used to cut
cartons or
paper.
Scissors Used to cut
the
installation
template or
other
materials.
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Tool Description Picture
Tweezers Used to
unplug
Ethernet
cables and
optical fibers.
Measuring Used to
tape measure
distances.
Marker Used to mark
component
installation
positions.
Flat-head Used to turn
screwdriver slotted-head
screws and
bolts.
Phillips Used to turn
screwdriver cross-head
screws and
bolts.
Combinatio Used to clamp
n pliers or bend metal
sheets, cut
metal wires,
strip off
coating of
cables, and
unplug nails.
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Tool Description Picture
Diagonal Used to cut
pliers insulation
tubes and
cable ties.
Wire Used to strip
stripper off the
insulation
coating and
shields of
communicatio
n cables with
small cross-
sectional
areas.
RJ45 Used to crimp
crimping Ethernet
tool cables.
COAX Used to crimp
crimping the metal
tool shield at the
end of a
coaxial cable.
Ethernet Used to test
cable tester Ethernet cable
connectivity.
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Tool Description Picture
Multimeter Used to test
cabinet
insulation,
cable
connectivity,
and device
electrical
performance
indicators,
including
voltage,
current, and
resistance.
Adjustable Used to
wrench tighten or
loosen hex or
square bolts
and nuts. The
span can be
adjusted to
suit bolts or
nuts in
different sizes.
Table 4-7 lists the installation accessories required for installing a device.
Table 4-7 Installation accessories
Tool Description Picture
Insulation Used to
tape insulate
power wires
or other
conductors.
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Tool Description Picture
Corrugated Used to
pipe protect optical
fibers.
Table 4-8 lists the installation accessories delivered with the device.
Table 4-8 Installation accessories
Accessory Quantity Description Part Number
Serial 1 Used to connect the console 04040838
cable port of the device to a serial
port of a maintenance terminal
for local commissioning or
maintenance of the device.
Panel 8 Used to fix expandable guide 26020141
screw rails and the device.
(M6x12)
Floating 8 Installed on mounting rails of a 26020075
nut (M6) cabinet or rack and used with
M6 screws to secure the
expandable guide rails and the
device in the cabinet or rack.
ESD wrist 1 Prevents ESD damages when 28050001
strap you touch or operate the
equipment or components.
Fiber 1 m Used to bundle optical fibers. 21101258
binding
tape
Cable tie 50 Used to bundle cables. 21100144
(300 x 3.6
mm)
Label 12 Used to bundle cables and 21200708
cable tie attach the power cable label
(29041061) to the cables.
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Accessory Quantity Description Part Number
Signal 1 Used to identify locations of 29041060
cable signal cables.
label
Power 1 Used to identify locations of 29041061
cable power cables.
label
4.1.6.5 Inspecting and Cleaning Optical Fiber Connectors and Adapters
4.1.6.5.1 Overview
This topic introduces the purpose and procedure of cleaning optical fiber
connectors, as well as polluters to optical fiber connectors.
Cleaning fiber connectors is to remove dust or other dirt to avoid performance
degradation of optical transmission systems.
Figure 4-36 shows an optical fiber connector.
Figure 4-36 Optical fiber connector
Optical fiber connectors should be free of:
● Dust
● Grease (usually brought by hands)
● Condensate residue
● Powder (evaporated residue of water or solvent)
Dust is the most common dirt in optical fiber connectors. The dust particles that
can be seen only by a microscope can affect the quality of optical signals,
deteriorate the system performance, and cause instability in network operation.
A 1-micrometer dust particle on the single-mode fiber connector can block 1%
light and cause 0.05 dB attenuation. A 9-micrometer dust particle that cannot be
seen by human eyes can block an entire fiber core. Therefore, small dirt even that
cannot be seen by human eyes should be removed.
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NO TE
Before you connect any optical component, make sure that you have checked and cleaned
the component.
4.1.6.5.2 Protection of Optical Fiber Connectors
This topic describes requirements for fiber connector protection.
The requirements are as follows:
● All boards with optical ports must be packed properly, to avoid mechanical
and electrostatic damages and to reduce vibrations.
● The protective caps must be put in an ESD bag.
● Protective caps must be installed on all optical fiber connectors when not in
use. The optical fiber connectors must be stored in proper packages to keep
them clean.
● Figure 4-37 shows the recommended protective caps, whereas Figure 4-38
shows the protective caps not recommended.
Figure 4-37 Protective caps recommended
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Figure 4-38 Protective caps not recommended
NO TE
The protective caps not recommended are made of soft rubber, which are apt to absorb
dust and sundries, and difficult to clean.
4.1.6.5.3 Tools, Equipment, and Materials
Optical connectors should be cleaned using recommended tools, equipment and
materials.
The following provides the recommended tools, equipment and materials:
● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
● Cassette cleaner
● Cleaning solvent (Isoamylol is preferred, propyl alcohol is the next, and
alcohol or formalin is forbidden.)
● Non-woven lens tissue, fiber cleaning tissue, and dustfree cloth (Non-woven
lens tissue is recommended.)
● Special compressed air
● Special cleaning roll
● Dustfree absorbent swab (made of medical cotton or long fiber cotton)
shown in Figure 4-39 and Figure 4-40
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Figure 4-39 Dustfree absorbent swabs for cleaning the SC and FC connectors
Figure 4-40 Dustfree absorbent swabs for cleaning the LC connectors
4.1.6.5.4 Inspecting Optical Fiber Connectors
This topic describes how to inspect the end face of optical fibers using a fiber
microscope.
Tools, Equipment, and Materials
The following provides the required tools, equipment and materials for inspecting
optical fiber connectors:
● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
Precautions
CA UTION
Laser energy is invisible and may cause eye injuries. Never look directly into fiber
connectors or ports.
Use a fiber microscope equipped with a safety device or a desktop video fiber
microscope when inspecting the optical fiber connectors.
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NO TICE
Electrostatic discharge is hazardous to the electronic equipment. Wear an ESD
wrist strap and ensure that the strap is grounded properly before touching the
equipment and boards, to protect the static-sensitive components against
electrostatic discharge of the human body. Otherwise, the equipment may be
damaged or the service may be interrupted.
Procedure
1. Shut down the laser and disconnect the fiber end before inspecting the fiber
connector.
2. Test the optical power using a power meter to ensure that the laser is shut
down.
3. Use a fiber microscope to check whether the fiber connector is contaminated
or damaged. See the examples below.
– Clean fiber and face
Figure 4-41 shows an image of a clean fiber end face under the fiber
microscope.
Figure 4-41 Clean fiber and face
– Damaged fiber end face
Figure 4-42 shows images of the damaged fiber end face. The image on
the left shows a severely damaged fiber. Severely damaged fibers can
cause damage to the equipment and should not be used. The image on
the right shows a defective fiber. If the output power is within a certain
range, the defective fiber might not cause any damage to the equipment.
If the output power is unstable or out of the range, however, the
defective fiber can cause damage to the equipment.
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Figure 4-42 Damaged or defective fiber end face
NO TE
Figure 4-42 shows only the 800-micrometer fiber cores.
For details on acceptable and unacceptable fibers, see Figure 4-43, Figure
4-44 and Figure 4-45.
Figure 4-43 Clean fiber end face
Figure 4-44 Acceptable fibers with imperfections
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Figure 4-45 Unacceptable fibers with imperfections
4. If any dirt is detected, clean the optical fiber connector. For details, see
"Cleaning Optical Fiber Connectors Using the Cassette Cleaner" and "Cleaning
Optical Fiber Connectors Using Lens Tissue".
5. If any damage is detected, replace the fiber.
4.1.6.5.5 Inspecting the Optical Fiber Link
This section describes the insertion loss and reflection requirements of optical links
and the method of checking the quality of optical links for the application of 50G
optical modules with the PAM4 coding technology.
Tools, Equipment, and Materials
Tools and instruments for checking optical fiber links are as follows:
● OTDR meter
● Fiber microscope
Precautions
CA UTION
Because the transmit optical power of the OTDR meter is much higher than the
damaged optical power threshold at the receive end, the optical fiber must be
removed from the optical module when the OTDR meter is used to test the optical
path quality.
Currently, the Ethernet port rate is increasing. Since the 50G optical module link
uses the PAM4 encoding technology, there are higher requirements on the optical
fiber and cable quality and the link is more sensitive to multipath reflection
interference of signals. If the fiber link connector, fiber section, or fiber splicing
surface is dirty, optical signals are reflected back and forth on the fiber link,
causing interference due to co-channel noise on the receive side. As a result, the
optical link is unstable or intermittently disconnected.
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According to the national standard (GBT50312-2016), the loss of the optical fiber
link connector must meet the requirements described in Table 4-9.
Table 4-9 Maximum attenuation of the optical fiber connector
Type Maximum attenuation of an optical fiber
connector (dB)
Fiber splicing connector 0.3
Optical mechanical connector 0.3
Optical connector 0.75
NO TE
Fiber cores are connected through connectors, such as the ODF, optical attenuator, and
flange, in splicing and mechanical modes.
Table 4-10 describes requirements for the reflection of the optical fiber connector
when Ethernet ports (such as 50G) use PAM4 encoding to double the rate. More
connectors bring lower requirements for the reflection.
Table 4-10 Maximum reflection of connectors
Number of Maximum Reflection of Each Connector (dB)
Optical Fiber
Connectors 50GBASE-FR 50GBASE-LR 50GBASE-ER
1 -25 -22 -19
2 -31 -29 -27
4 -35 -33 -32
6 -38 -35 -35
8 -40 -37 -37
10 -41 -39 -39
Procedure
1. After the optical fiber at the peer end is disconnected, use the OTDR meter to
test the local end. Check whether the loss and reflection of each link and
node are normal. (The loss of a fiber splicing connector should be less than
0.3 dB, the loss of a connector should be less than 0.75 dB, and the reflection
of a connector should be less than -30 dB.) If the test result is not within the
required range, process the abnormal port.
2. Locate the equipment room where the port resides based on the distance
between abnormal points in the OTDR test result. Preliminarily determine the
port location, disconnect the port, and perform an OTDR test on the port that
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reports alarms. Check whether the distance is consistent with that in the
previous test. If not, continue to test other ports.
3. After the abnormal port is found, test the port using a fiber microscope. If the
port is dirty, clean it. For details, see "Inspecting and Cleaning Optical Fiber
Connectors and Adapters".
4. After the port is cleaned, restore the port, and ensure that the connector is
tightened. Perform an OTDR test on the port to check whether loss and
reflection of each link and node are normal.
5. If the fault persists, replace the flange and perform an OTDR test on the port
that reports alarms to check whether loss and reflection of each link and
node are normal.
6. If the fault persists, replace the optical fiber and perform an OTDR test on the
port that reports alarms to check whether loss and reflection of each link and
node are normal.
7. If multiple abnormal points exist on the link, repeat steps 2 to 6.
4.1.6.5.6 Cleaning Optical Fiber Connectors Using the Cassette Cleaner
This topic describes how to clean the fiber connectors using a cassette cleaner.
Prerequisites
Before cleaning, inspect the fiber end face with a fiber microscope or a magnifier
to confirm the degree of fiber contamination. Clean the fiber only when it is
severely contaminated. This is because the cleaning operation itself may introduce
dust, dirt, or cause damage to the fiber.
The following procedure provides the steps to clean the fiber connectors using
cartridge type cleaners.
Tools, Equipment, and Materials
The following lists the required tools, equipment and materials for cleaning optical
fiber connectors:
● cassette cleaner
● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
Precautions
CA UTION
Laser energy is invisible and may cause eye injuries. Never look directly into fiber
connectors or ports.
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NO TICE
Electrostatic discharge is hazardous to the electronic equipment. Wear an ESD
wrist strap and ensure that the strap is grounded properly before touching the
equipment and boards, to protect the static-sensitive components against
electrostatic discharge of the human body. Otherwise, the equipment may be
damaged or the service may be interrupted.
Procedure
1. Shut down the laser and disconnect the fiber end before inspecting the fiber
connector.
2. Test the optical power using a power meter to ensure that the laser is shut
down.
3. Press down and hold the lever of the cassette cleaner. The shutter slides back
and exposes a new cleaning area.
4. Place the fiber end face gently against the cleaning area.
5. Drag the fiber end face gently on one cleaning area in the arrow direction
each time. Do it again on the other cleaning area in the same direction as the
first time once.
NO TICE
Do not drag the fiber end face on the same cleaning area more than once.
Otherwise, the connector can be contaminated or damaged.
6. Release the lever of the cassette cleaner to close the cleaning area.
7. Use a fiber microscope to inspect the fiber to check whether there is any dirt.
For details see the examples shown in "Inspecting Optical Fiber Connectors".
If the fiber end face is still dirty, repeat 1 to 6.
8. Connect the fiber to the optical port immediately. If it is not used for the time
being, put a protective cap on it.
9. Turn on the laser after connecting the fiber to the board.
4.1.6.5.7 Cleaning Optical Fiber Connectors Using Lens Tissue
This topic describes how to clean the fiber connectors using lens tissue.
Prerequisites
Before cleaning, inspect the fiber end face with a fiber microscope or a magnifier
to confirm the degree of fiber contamination. Clean the fiber only when it is
severely contaminated. This is because the cleaning operation itself may introduce
dust, dirt, or cause damage to the fiber.
Tools, Equipment, and Materials
The following provides the required tools, equipment and materials:
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● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
● Cleaning solvent (Isoamylol is preferred, propyl alcohol is the next, and
alcohol or formalin is forbidden.)
● Non-woven lens tissue, fiber cleaning tissue, and dustfree cloth (Non-woven
lens tissue is recommended.)
● Special compressed air or cleaning roll
Precautions
CA UTION
Laser energy is invisible and may cause eye injuries. Never look directly into fiber
connectors or ports.
NO TICE
Electrostatic discharge is hazardous to the electronic equipment. Wear an ESD
wrist strap and ensure that the strap is grounded properly before touching the
equipment and boards, to protect the static-sensitive components against
electrostatic discharge of the human body. Otherwise, the equipment may be
damaged or the service may be interrupted.
Procedure
1. Shut down the laser and disconnect the fiber end before inspecting the fiber
connector.
2. Test the optical power using a power meter to ensure that the laser is shut
down.
3. Put a little cleaning solvent on the lens tissue.
4. Clean the fiber end face on the lens tissue. See Figure 4-46 and Figure 4-47.
NO TICE
Drag the fiber end face on the same area in the lens tissue only once.
Otherwise, the connector can be contaminated or damaged.
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Figure 4-46 Cleaning the fiber end face using the lens tissue on the desk
Figure 4-47 Cleaning the fiber end face using the lens tissue on the hand
5. Repeat 4 several times on the areas of the lens tissue that have not been
used.
6. Use the compressed air to blow off dust on the fiber end face.
NO TE
● When using the compressed air, keep the nozzle as close as possible to the fiber
end face without touching it.
● Before using the compressed air, first spray it into the air to expel deposits in the
compressed air.
● If the compressed air is not available, use a cleaning roll instead.
7. Use a fiber microscope to inspect the fiber to check whether there is any dirt.
For details, see the examples shown in "Inspecting Optical Fiber Connectors".
If the fiber end face is still dirty, repeat 1 to 6.
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8. Do not touch the fiber connector after cleaning it. Connect it to the optical
port immediately. If it is not used for the time being, put a protective cap on
it.
NO TE
Do not use the same cleaning area to clean the fiber connector for more than one
time.
9. Turn on the laser after connecting the fiber to the board.
4.1.6.5.8 Cleaning Optical Fiber Adapters Using Dustfree Absorbent Swabs
This topic describes how to clean fiber adapters using dustfree absorbent swabs.
Prerequisites
There are several types of dustfree absorbent swabs available. Select appropriate
dustfree absorbent swabs based on site conditions. You can obtain the following
tools and materials from a fiber cable and connector manufacturer.
Tools, Equipment, and Materials
The following lists the required tools, equipment and materials:
● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
● Cleaning solvent (Isoamylol is preferred, propyl alcohol is the next, and
alcohol or formalin is forbidden.)
● Special compressed air
● Dustfree absorbent swab (made of medical cotton or long fiber cotton)
Precautions
CA UTION
Laser energy is invisible and may cause eye injuries. Never look directly into fiber
connectors or ports.
NO TICE
Electrostatic discharge is hazardous to the electronic equipment. Wear an ESD
wrist strap and ensure that the strap is grounded properly before touching the
equipment and boards, to protect the static-sensitive components against
electrostatic discharge of the human body. Otherwise, the equipment may be
damaged or the service may be interrupted.
Procedure
1. Shut down the laser and disconnect the fiber end before inspecting the fiber
connector.
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2. Test the optical power using a power meter to ensure that the laser is shut
down.
3. Select the dustfree absorbent swab with a proper diameter based on the type
of an adapter.
NO TE
For SC and FC fiber adapters, use the dustfree absorbent swab with a diameter of 2.5
mm (0.1 in.); for the LC fiber adapter, use the dustfree absorbent swab with a
diameter of 1.25 mm (0.05 in.). See Figure 4-48 and Figure 4-49.
Figure 4-48 Dustfree absorbent swabs for cleaning the SC and FC connectors
Figure 4-49 Dustfree absorbent swabs for cleaning the LC connectors
4. Put a little cleaning solvent on the dustfree absorbent swab.
5. Place the dustfree absorbent swab gently on the adapter so that the cleaning
solvent is against the fiber end face. Draw out the dustfree absorbent swab
from the fiber adapter and then rotate the dustfree absorbent swab clockwise
once. Ensure that the tip of the dustfree absorbent swab directly contacts the
fiber end face.
6. Use the compressed air to blow off dust on the fiber end face.
NO TE
● When using the compressed air, keep the nozzle as close as possible to the fiber
end face without touching it.
● Before using the compressed air, first spray it into the air to expel deposits in the
compressed air.
7. Use a fiber microscope to inspect the fiber to check whether there is any dirt.
For details, see "Inspecting Optical Fiber Connectors". If the fiber end face is
still dirty, repeat 1 to 6.
8. Connect the fiber to the optical port immediately. If it is not used for the time
being, put a protective cap on it.
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9. Turn on the laser after connecting the fiber to the board.
4.1.6.6 Inspection of power distribution environment
4.1.6.6.1 Introduction to the Power Distribution System
Devices support both AC and DC power supplies.
● AC power supply mode: Under normal conditions, uninterruptible power
supply (UPS) obtains three-phase 380 V AC power input from a mains power
outlet and transmits 380 V AC power to an AC power distribution frame. A
chassis receives power from the AC power distribution frame through the
power distribution unit (PDU) installed in the cabinet.
Figure 4-50 AC power supply mode
● High-voltage (240 V) DC power supply mode: Under normal conditions, a
rectifier system obtains three-phase 380 V AC power input from a mains
power outlet and transmits 240 V DC power to a DC power distribution frame.
A chassis receives power from the DC power distribution frame through the
PDU installed in the cabinet/rack.
Figure 4-51 High-voltage (240 V) DC power supply mode
● DC power supply mode: Under normal conditions, a rectifier system receives
three-phase 380 V AC power input from a mains power outlet and transmits
-48 V DC power to a DC power distribution frame. The device obtains power
from the DC power distribution frame.
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Figure 4-52 DC power supply mode
4.1.6.6.2 DC Power Distribution Guide
DANGER
Do not install power cables when the power is on. This is to avoid injuries.
Figure 4-53 Schematic diagram of the DC power distribution
DC Power Supply System
For cable specifications, see "Hardware Description"-Equipment Cables-Power
Cables.
Table 4-11 PDF circuit breaker specifications
Item Description Remarks
Circuit breaker of ≥32 A -
each channel NOTICE
The circuit breaker
current must not
be greater than
the maximum
derating current of
the device.
Installing Power Cables
1. Connect the power cord to the power connector.
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2. Attach temporary labels to both ends of each power cable.
3. Route power cables along the cable ladder and lay them on the chassis.
4. Take off the plastic cover from each power module, connect one end of each
power cable to the corresponding terminal and the other end to the PDF.
Figure 4-54 Installing the Power Cables
5. Use cable ties to bundle cables every 150 mm upwards from the bottom and
fasten the cables to the cable tray.
6. Attach permanent labels 20 mm from both ends of each power cable.
NO TE
To ensure that the power cable is long enough, perform the following steps to install a
power cable:
1. Prepare a power cable a little longer than the distance between the power module and
PDF.
2. Install a terminal on one end of the power cable and connect the terminal to the device.
3. Connect power cables to the positive and negative electrodes securely. Otherwise, the
power test result is inaccurate.
4. Route the power cable, bind it to the cable tray, and cut any excess length of the cable.
Install a terminal on the other end of the power cable and connect the terminal to the
PDF.
4.1.6.6.3 AC Power Distribution Guide
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DANGER
Do not install power cables when the power is on. This is to avoid injuries.
Figure 4-55 Schematic diagram of the AC power distribution
AC Power Supply System
For cable specifications, see "Hardware Description"-Equipment Cables-Power
Cables.
Table 4-12 PDF circuit breaker specifications
Item Description Remarks
Circuit breaker of ≥10 A For hierarchical power supplying
each channel NOTICE protection, the current of the circuit
The circuit breaker breaker at the user side should be no
current must not less than 10 A.
be greater than
the maximum
derating current of
the device.
Installing AC Power Cables
1. Route AC power cables along the cable ladder and lay them on the chassis.
2. Insert the AC power cable to the AC input port and secure it using the loose-
proof pinch as shown in Figure 4-56. Connect the other end of the AC power
cable to the PDF of the equipment room.
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Figure 4-56 Installing the AC power cable
3. Use cable ties to bundle AC cables every 150 mm upwards from the bottom
and fasten the cables to the cable tray.
4. Attach permanent labels 20 mm from both ends of each AC power cable.
Instructions for Connecting the AC Power Cable to the Power Distribution
Box
1. Cut the PE ground wire (yellow-green wire) at the peeling place (wrap it with
insulation tape to prevent leakage or short circuit), peel the L wire (brown
wire) and N wire (blue wire) and crimp the OT terminal Or cold-pressed
terminal (terminal type is selected according to actual conditions).
2. Connect the L and N wires to the corresponding L and N input terminals of
the power distribution box.
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When using 110V power supply (dual live wire power supply), L and N are
connected to the two live wires (L) of the equipment room and connected to
the PGND cable. At the same time, both L and N poles must be configured
with circuit breakers.
4.1.6.7 Unpacking a Device
Unpack the chassis before starting the installation.
4.1.6.7.1 Unpacking a Carton
Tools
● ESD gloves
● Diagonal pliers
● Paper knife
CA UTION
● Integrated circuits (ICs) are sensitive to electrostatic discharge from the
human body. When handling boards or metallic parts of the equipment,
wear ESD gloves and hold only the edges of the boards during operation.
● If the equipment is transported from a cold and dry place to a warm and
damp place, wait at least 30 minutes before unpacking it. Otherwise, the
moisture condenses on the board surface and damages the components.
Procedure
1. Transport the packing box to the equipment room.
2. Check the packing box, and stop unpacking it in any of the following cases:
– The outer package is severely damaged.
– There is water leakage on the outer package.
Find the causes and provide feedback to the local representative office of
Huawei.
3. Observe the labels on the carton to check the equipment configuration and
take a record.
4. Cut the strap with the diagonal plier and then split the adhesive tape properly
along the seam between the cover and the body of the box with the paper
knife. Do not scratch the articles inside the box.
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Figure 4-57 Unpacking the carton of the NetEngine 8000 F1A-8H20Q
1. Pressure- 2. Carton label 3. Packing box 4. ESD PE bag
sensitive adhesive
tape
5. Foam protector 6. Chassis - -
5. Open the carton and take out the chassis box from the carton.
6. Open the chassis box and take out the chassis. Then, check whether the
chassis is damaged.
4.1.7 Installing a Chassis in Cabinet
Precautions
Ensure that the cabinet has been properly installed before installing devices in the
cabinet. The cabinet can be installed on an ESD floor or concrete floor.
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NO TICE
● When installing devices, ensure that the total heat consumption of all devices
in the cabinet is less than or equal to the heat dissipation capability of the
cabinet.
● To prevent heat dissipation from being affected by air return, devices must be
installed at an interval of 1 U or more in the cabinet. In addition, the middle-
column cabinets support device stacking.
● Ensure that heat dissipation holes on the panel are not blocked.
● When the chassis is installed together with other equipment in the same
cabinet, do not install the chassis near the air exhaust vent of other equipment.
● Determine whether the air exhaust vent affects adjacent devices to avoid high
temperature of adjacent devices.
Installing a Chassis in a Standard 19-Inch Cabinet
1. Wear an ESD wrist strap or ESD gloves. Ensure that the ESD wrist strap is
grounded and in close contact with your wrist.
2. Use a measuring tape to measure the distance between the front and rear
mounting rails in the cabinet.
3. Select front mounting brackets, rear mounting brackets, and rear mounting
bracket guide rails according to the distance between the front and rear
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mounting rails. Table 4-13 shows the front mounting brackets, rear mounting
brackets, and rear mounting bracket guide rails used on the device for
different distances between the front and rear mounting rails.
Table 4-13 Selection of front mounting brackets, rear mounting brackets, and
rear mounting bracket guide rails used on the device
Distance Front Mounting Brackets, Rear Mounting Brackets, and
Between Rear Mounting Bracket Guide Rails
Front and
Rear
Mounting
Rails
310 mm to
351 mm
369 mm to
410 mm
438 mm to
479 mm
497 mm to
538 mm
539 mm to
637 mm
638 mm to
696 mm
697 mm to
835 mm
4. Fix floating nuts and M6 screws in the correct holes.
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NO TE
When tightening floating nuts, ensure a minimum distance of 75 mm between a
chassis side and its adjacent column for ventilation.
5. Use a torque screwdriver to install the front mounting brackets using three
M4 screws with a torque of 1.2 N m.
6. Use a torque screwdriver to install the extension rails of the expandable
mounting brackets on the rear of the chassis using four M4 screws with a
torque of 1.2 N m.
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Install the front mounting brackets, rear mounting brackets, and rear
mounting bracket guide rails depending on the distance between the front
and rear mounting rails in the cabinet. See Table 4-14.
Table 4-14 Installing front mounting brackets, rear mounting brackets, and
rear mounting bracket guide rails
Distance Installation of Front Mounting Brackets, Rear Mounting
Between Brackets, and Rear Mounting Bracket Guide Rails
Front and
Rear
Mounting
Rails
310 mm to
351 mm
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Distance Installation of Front Mounting Brackets, Rear Mounting
Between Brackets, and Rear Mounting Bracket Guide Rails
Front and
Rear
Mounting
Rails
369 mm to
410 mm
438 mm to
479 mm
497 mm to
538 mm
539 mm to
637 mm
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Distance Installation of Front Mounting Brackets, Rear Mounting
Between Brackets, and Rear Mounting Bracket Guide Rails
Front and
Rear
Mounting
Rails
638 mm to
696 mm
697 mm to
835 mm
7. Use a torque screwdriver to install the extension runners of the expandable
mounting brackets on the rear posts of the cabinet using M6 screws with a
torque of 3 N m. Horizontally insert the chassis into the cabinet from the
front of the cabinet until the extension rails are fully inserted into the
extension runners. Then, use screws to fix the front mounting brackets to the
cabinet.
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8. Use a torque screwdriver to install the ground cable using an M4 screw with a
torque of 1.2 N m.
4.1.8 Cable Routing Planning
4.1.8.1 DC Power Cable Routing Planning
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Context
To ensure that power cables are connected in order, you are advised to plan power
cable routing.
NO TICE
Do not bundle or route outdoor cables (such as outdoor antenna feeders and
outdoor power cables) and indoor cables together in the cabinet or on the cable
tray.
If the cables on the right side are tightly bundled but the cabling space is still
insufficient, you can route the extra cables on the left side. In the case of left-side
cabling, keep the cables away from the upper and lower board, power module,
and fan module insertion/removal areas to facilitate future maintenance.
Power Cable Routing Planning
It is recommended that DC power cables be routed on the left side of the cabinet
or rack.
It is recommended that cables, such as optical fibers, and Ethernet cables, be
routed on the left and right sides of the cabinet as the circumstances may require.
Figure 4-58 shows the cable layout of a DC device.
Figure 4-58 Cable layout
4.1.8.2 AC Power Cable Routing Planning
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Context
To ensure that power cables are connected in order, you are advised to plan power
cable routing.
NO TICE
Do not bundle or route outdoor cables (such as outdoor antenna feeders and
outdoor power cables) and indoor cables together in the cabinet or on the cable
tray.
If the cables on the right side are tightly bundled but the cabling space is still
insufficient, you can route the extra cables on the left side. In the case of left-side
cabling, keep the cables away from the upper and lower board, power module,
and fan module insertion/removal areas to facilitate future maintenance.
Power Cable Routing Planning
It is recommended that AC power cables be routed on the left side of the cabinet.
It is recommended that cables, such as optical fibers, and Ethernet cables, be
routed on the left and right sides of the cabinet as the circumstances may require.
Figure 4-59 shows the cable layout of an AC device.
Figure 4-59 Cable layout
4.1.9 Installation of cables
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4.1.9.1 Installing Optical Fibers
NO TICE
● Wear an ESD wrist strap or ESD gloves before installing optical modules.
● The bending radius of a single-mode G.657A2 optical fiber is greater than or
equal to 10 mm, and the bending radius of a multi-mode A1b optical fiber is
greater than or equal to 30 mm.
● Cover empty optical interfaces and idle optical modules with dust caps.
● Do not bundle optical fibers too tightly. You must be able to conveniently
remove a single fiber from the bundle.
● Properly fix optical fibers onto the cabinet columns to prevent impact on the
surrounding devices.
1. Attach temporary labels to both ends of each optical fiber.
2. Arrange optical fibers into a bundle and feed them through the corrugated
pipe.
3. Wrap adhesive tapes on both ends of the corrugated pipe to protect it from
cuts.
4. Route the corrugated pipe along the cable ladder.
5. Insert the corrugated pipe through the dedicated cable hole on the cabinet
top to the cabinet about 100 mm and tie the pipe to the cabinet.
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Figure 4-60 Inserting the corrugated pipe
6. Install the optical module, as shown in step 1 in Figure 4-61.
7. Route optical fibers along the cable tray, remove the dust caps from the
optical modules and optical fiber interfaces. Then connect the end of each
optical fiber to the corresponding optical interface, as shown in step 2 in
Figure 4-61.
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Figure 4-61 Installing Optical Fibers
8. Connect the other end of each optical fiber to the ODF.
9. Bundle optical fibers with binding straps at an interval of 150 mm and fasten
the optical fibers to the cable tray.
10. Attach permanent labels 20 mm from both ends of each optical fiber.
4.1.9.2 Installing Network Cables
NO TICE
Before bundling network cables, use a network cable tester to test cable
connectivity.
NO TE
● Bundle the network cables in a rectangle shape. Ensure that the cable ties are evenly
spaced and face the same direction.
● Route cables at a proper distance from each other. Otherwise, the installation of other
cables may be affected.
● Route Ethernet cables, power cables, and ground cables separately. The Ethernet cables
must not be damaged or broken or have joints.
1. Attach temporary labels to both ends of each network cable.
2. Route network cables along the cable tray and plug them into corresponding
interfaces.
3. Use a network cable tester to test the connectivity of network cables.
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4. Use cable ties to bundle network cables at an interval of 150 mm and fasten
the network cables to the rack.
5. Attach permanent labels 20 mm from both ends of each network cable.
Figure 4-62 Installing network cables
4.1.9.3 Installing a Cabinet Ground Cable
1. Install a cabinet ground cable.
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Figure 4-63 Installing a cabinet ground cable
2. Install the ground cable between the device and cabinet.
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Figure 4-64 Installing the ground cable between the device and cabinet
4.1.10 Post-Installation Check
CA UTION
Before starting the post-installation check, make sure that the power switches of
the external power supply system are in OFF position.
After completing installation of a device, check the items listed in the following
table. If any item fails the check, check for the reason, reinstall the related
component, and check again. Ensure that all the items pass the check.
Check cabinets according to Table 4-15.
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Table 4-15 Cabinet checklist
No. Item Method
1 The cabinet installation location complies Observe
with the engineering design document.
2 Components are correctly installed in a Observe
cabinet. No component is loose or damaged.
3 All the bolts are tightened, especially those Observe
for electrical connections. The flat washers
and spring washers are installed completely
and properly.
4 The vertical deviation of a cabinet is less Measure
than 3 mm. You can use a plumb bob to
measure the vertical deviation.
5 The cabinets on the sides of the main path Measure
are aligned in a line, with a deviation of less
than 5 mm.
6 The surfaces of the cabinets in the same row Observe
are on the same plane. The cabinets are
deployed close to each other.
7 The front door of a cabinet can be opened Observe
and closed easily.
8 The cable outlets on the top and bottom of Observe
a cabinet are properly sealed.
9 Metal components in a cabinet have good Observe
electrical connections with the rack. Screw
mounting holes, guide rails, and mounting
brackets are not covered with insulation
painting.
10 Ground busbars of adjacent cabinets are Observe
connected through busbar cables.
Check cables according to Table 4-16.
Table 4-16 Cable checklist
No. Item Method
1 Routes of signal cables comply with the Observe
engineering design document.
2 Signal cables are not damaged or broken Observe
and have no splices.
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No. Item Method
3 Signal cable connectors are clean, intact, and Observe
correctly connected. Wires of each signal
cable are securely clamped in the
connectors.
4 Signal cables do not cross each other and Observe
have sufficient slack at the bent part. (Signal
cables can be crossed within 1 m outside the
cabinet.)
5 Pigtail fibers outside a cabinet are laid in a Observe
protection pipe or trough and are not
squeezed by other cables or objects.
6 Optical fibers are led into a cabinet through Observe and
a corrugated pipe. The corrugated pipe measure
should be no longer than 100 mm and be
bundled on the cabinet.
7 The bend radius of optical fibers is 20 times Observe and
larger than their diameters. Generally, the measure
bend radius of optical fibers should be no
less than 40 mm. The path of optical fibers is
not blocked by any components.
8 Optical fibers are bundled by binding tape Observe
with appropriate force.
9 Each signal cable has correct, clear, and tidy Observe
labels attached on both ends.
10 The routes of power cables and ground Observe
cables conform to the engineering design
document, facilitating future maintenance
and system expansion.
11 All power cables and ground cables are Observe
complete copper wires without splices.
Coatings of power cables and ground cables
are intact.
12 Power cables and ground cables are Observe
connected properly.
13 Power cables and ground cables are routed Observe
in compliance with the engineering design
document, meeting power distribution
requirements.
14 Power cables and ground cables are Observe
separated from signal cables.
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No. Item Method
15 Power cables and ground cables are routed Observe
straightly and properly bundled, with
sufficient slack at the bend part.
16 Power cables, ground cables, and power Observe
switches on power distribution boxes and
power distribution frames are identified by
correct, clear, and tidy labels.
17 The yellow-green ground cables are correctly Observe
connected. One end of a ground cable is
connected to the PGND ground bar in the
power distribution cabinet, and the other
end is connected to the ground point on a
cabinet. Screws at both ends of a ground
cable are securely fastened.
Check the installation environment according to Table 4-17.
Table 4-17 Installation environment checklist
No. Item Method
1 No fingerprints or other smears exist on the Observe
surface of the equipment cabinet.
2 No excessive adhesive tapes or cable ties Observe
exist on the cables.
3 No tapes, cable ties, wastepaper, or packing Observe
bags are left around the equipment.
4 All the items around the equipment are neat, Observe
clean, and intact.
4.1.11 Power-on Check
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Power-on Check Flowchart
Figure 4-65 Power-on Check Flowchart
NO TICE
The normal input voltage of the DC power supply system ranges from -40 V DC to
-72 V DC. The normal input voltage of the AC power supply system ranges from
90 V AC to 290 V AC.
Indicator description
Item Indicator Color Status Description
Fan module FAN Green The fan module works normally.
Red The fan module fails.
- If this indicator is steady off, the
fan module is not powered on or
the fan hardware is faulty.
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Item Indicator Color Status Description
Working STAT Green The device works normally.
status
indicator Red The hardware is faulty.
- If this indicator is steady off, the
device is not running or no power
is input.
Connection/ L/A Green If this indicator is steady green, the
data link is Up.
transmission
status If this indicator blinks, data is
indicator being received and transmitted.
Orange If this indicator blinks, data is
being received and transmitted.
- If this indicator is steady off, the
link is Down.
Breakout Breakout Green Each indicator for channels 0, 1, 2,
channel 0-3 and 3 turns on for 5s in sequence
indicator to indicate the status of the
corresponding channel. This
process repeats.
4.1.12 (Optional) Checking Optical Power
The following table describes comparison between the transmit optical power of
50 Gbps optical modules and damaged optical power threshold at the receive end:
Optical Maximum Minimum Damaged Description
Module Type Average Average Optical
Transmit Transmit Power
Optical Optical Threshold at
Power Power the Receive
End
50GBASE-FR 3 -4.1 5.2 The damaged
optical power
50GBASE-LR 4.2 -4.5 5.2 threshold is
greater than
the maximum
average
transmit
optical power,
posting low
self-loop risks.
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Optical Maximum Minimum Damaged Description
Module Type Average Average Optical
Transmit Transmit Power
Optical Optical Threshold at
Power Power the Receive
End
50GBASE-ER 6.6 0.4 -2.4 The damaged
optical power
threshold is
9dBm lower
than the
maximum
average
transmit
optical power
and 2.8dBm
lower than
the minimum
average
transmit
optical power,
posing high
self-loop risks.
In this case,
an optical
attenuator
must be
configured for
self-loop.
For applications of the 50 Gbps optical module supporting a distance of 40 km:
1. To ensure that the optical module runs stably for a long time, adjust the
receive optical power of the optical module to a value lower than -4 dB.
According to the IEEE 802.3 standard, if the receive optical power of the
optical module exceeds -2.3 dB, the optical module may be permanently
damaged.
2. Before connecting to the optical module, use an optical power meter to
measure the receive optical power (P). If P is less than -4 dB, the optical
module can be directly connected. If P is greater than -4 dB, add an optical
attenuator at the receive end to ensure that the receive optical power is less
than -4 dB. Alternatively, add an optical attenuator (no less than 10 dB is
recommended) before the interconnection, and then adjust the optical
attenuator based on the site requirements to prevent the optical module from
being damaged.
3. If a loopback occurs on the pigtail of the optical module or the optical
module is connected for a short distance, an optical attenuator must be
added. It is recommended that the optical attenuator be no less than 10 dB.
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4.1.13 Maintenance of the device
4.1.13.1 Basic Operation Process and Precautions
Context
To ensure that the device provides uninterrupted communication services for users
in networks, parts of a device are replaced mostly when the power is on.
Therefore, to ensure safe operation of a device and to minimize the impact of
parts replacement on services, maintenance personnel must strictly abide by the
basic operation process regulated in the manual, as shown in Figure 4-66.
Figure 4-66 Basic operation process of replacing parts
Procedure
1. Assess the feasibility of the operation.
During the process of troubleshooting or repairing a device, maintenance
personnel must assess whether the operation is feasible before replacing a
certain part.
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a. Whether the needed spare parts are available in the depot.
b. Whether the maintenance personnel is qualified for carrying out the
operation.
NO TE
Parts replacement can be carried out only by maintenance personnel who are
professionally trained. That is, maintenance personnel must familiarize
themselves with the functions of each part of the device, know the basic
operation process of parts replacement, and master the basic skills of parts
replacement.
c. Whether the risks of the operation can be controlled.
NO TICE
Parts replacement is risky to a certain extent. Hence, improper operation
may cause abnormal running of the device, service interruption, or
injuries to the personnel. Therefore, before replacing parts, maintenance
personnel must comprehensively evaluate the risks of the operation, that
is, whether the risks can be controlled through certain measures if the
system remains active. Maintenance personnel can replace the parts only
when the risks can be controlled. Otherwise, contact a Huawei local
office for timely technical support.
2. Prepare tools and spare parts.
After determining that the operation is feasible, maintenance personnel need
to prepare tools and spare parts.
a. Prepare spare parts.
NO TICE
Before replacing the component, contact Huawei engineers to see if a
license is required. You can apply for a license or use Stick License to
activate some license control items.
b. The common tools include the multimeter, cable tester, ESD wrist strap,
Phillips screwdriver, flat-head screwdriver, needle-nose pliers, cutter, and
pliers.
3. Take protective measures.
Although parts replacement is risky, in most cases, however, maintenance
personnel can prevent the risks by taking protective measures. For example,
before replacing a master board, maintenance personnel can switch services
on the master board to the slave board. After the slave board runs properly,
maintenance personnel can replace the master board. In this manner,
interruption of services is prevented.
Therefore, to ensure safe operation of a device and to minimize the impact of
parts replacement on services, maintenance personnel must take related
protective measures.
4. Replace parts.
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After checking that the protective measures are available, maintenance
personnel can carry out parts replacement according to the regulations
specified in the manual.
DANGER
Wear an ESD wrist strap or ESD gloves before replacing parts when the power
is on.
Avoid direct eye exposure to the laser beam launched from the optical
interface board or fiber.
5. Verify the functions of the new parts.
After completing part replacement, maintenance personnel must verify the
functions of the new parts through the testing methods described in this
section.
NO TE
The operation is considered successful only when the new parts are proved to be
running normally. Otherwise, contact Huawei technical support personnel.
6. Return and repair the faulty parts.
If a part that is replaced is confirmed to be faulty, maintenance personnel
should fill in the Offsite Repair Card for Faulty Materials, and send the card
and the faulty part to a Huawei local office for timely maintenance.
NO TICE
Carefully maintain the damaged control board that store data to prevent
information leak.
Before you replace the control board, delete data from it to prevent data
embezzlement.
Use either of the following methods to delete data from the control board:
● Connect the control board to a PC and then delete data from the control
board on the PC.
● Physically destroy the control board.
4.1.13.2 Replacing a power module
4.1.13.2.1 Replacing the DC Power Module
Precautions
Before replacing a power module, you need to note the following points:
Before replacing a power module, switch off the corresponding circuit breaker on
the power distribution cabinet.
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Do not touch metal parts when removing or installing a power module with the
power on.
Tools
Before replacing a power module, you need the following tools:
● ESD wrist strap or ESD glove
Procedure
1. Check the location of the power module to be replaced.
Before pulling out a power module that is to be replaced, you should first
check the location of the module, for example, the cabinet and chassis where
the power module resides. Then, locate the power module to be replaced in
the chassis and attach a label to the panel to identify the power module.
2. Switch off the corresponding circuit breaker on the power distribution cabinet.
Thus, the power module to be replaced is powered off.
3. Wear the ESD wrist strap and connect the grounding terminal to the ESD jack
on the rack.
4. Disconnect power cables from the wiring terminals.
5. Press and hold the lock on the power module rightward with your thumb,
slowly pull the power module out by the handle, as shown in Figure 4-67.
Figure 4-67 Pull out the power module
6. Hold both sides of the power module and insert the module into the guide
rail of the slot. Ensure that the power module is in good contact with the
backplane of the chassis, as shown in Figure 4-68.
Figure 4-68 Insert the power module
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7. Connect the cables to the power module in the original sequence, and
reinstall the protective cover.
8. Switch on the corresponding circuit breaker on the power distribution cabinet.
Verify the functions of the new power module.
– If the STAT indicator on the panel of the power module is on and is
green, power module works normally.
– Run the display device command on the console interface to check the
running status of the new power module. If the Status is displayed as
Normal, it indicates that the power module runs normally.
If the fan module fails to return to the normal state, you should contact a
Huawei local office for timely technical support.
Follow-up Procedure
After replacing the power module, collect the tools. If a power module that is
replaced is confirmed to be faulty, you should fill in the Offsite Repair Card for
Faulty Materials, and send the card and the faulty power module to a Huawei
local office for timely maintenance.
4.1.13.2.2 Replacing the AC Power Module
Precautions
Before replacing a power module, you need to note the following points:
Before replacing a power module, switch off the corresponding circuit breaker on
the power distribution cabinet.
Do not touch metal parts when removing or installing a power module with the
power on.
Tools
Before replacing a power module, you need the following tools:
● ESD wrist strap or ESD glove
Procedure
1. Check the location of the power module to be replaced.
Before pulling out a power module that is to be replaced, you should first
check the location of the module, for example, the cabinet and chassis where
the power module resides. Then, locate the power module to be replaced in
the chassis and attach a label to the panel to identify the power module.
2. Switch off the corresponding circuit breaker on the power distribution cabinet.
Thus, the power module to be replaced is powered off.
3. Wear the ESD wrist strap and connect the grounding terminal to the ESD jack
on the rack.
4. Disconnect power cables from the wiring terminals.
5. Press and hold the lock on the power module rightward with your thumb,
slowly pull the power module out by the handle, as shown in Figure 4-69.
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Figure 4-69 Pull out the power module
6. Hold both sides of the power module and insert the module into the guide
rail of the slot. Ensure that the power module is in good contact with the
backplane of the chassis, as shown in Figure 4-70.
Figure 4-70 Insert the power module
7. Connect the cables to the power module in the original sequence, and
reinstall the protective cover.
8. Switch on the corresponding circuit breaker on the power distribution cabinet.
Verify the functions of the new power module.
– If the STAT indicator on the panel of the power module is on and is
green, power module works normally.
– Run the display device command on the console interface to check the
running status of the new power module. If the Status is displayed as
Normal, it indicates that the power module runs normally.
If the fan module fails to return to the normal state, you should contact a
Huawei local office for timely technical support.
Follow-up Procedure
After replacing the power module, collect the tools. If a power module that is
replaced is confirmed to be faulty, you should fill in the Offsite Repair Card for
Faulty Materials, and send the card and the faulty power module to a Huawei
local office for timely maintenance.
4.1.13.3 Replacing the Fan Module
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Precautions
● To ensure that system heat dissipation is not affected, a fan module must be
replaced within one minute.
● The fans are exposed on the left side of the fan tray. Keep your fingers,
clothing, and jewelry away from the fans. Always handle the fan tray by the
handle.
● Do not touch the fan when the fan is rotating.
Tools
● ESD wrist strap or ESD gloves
Procedure
1. Check the location of the fan module to be replaced.
Before removing the old fan module, check its location, for example, the
cabinet and chassis where the fan module resides. Then, find the fan module
to be replaced in the chassis and attach a label to the panel to identify the
fan module to avoid misoperation.
2. Wear the ESD wrist strap and connect the ground terminal to the ESD jack on
the chassis.
3. Hold the handle on the fan module with one hand and pull part of it. Support
the bottom of the fan module with the other hand until the fan module is
completely pulled out, as shown in Figure 4-71.
Figure 4-71 Pull out the fanmodule
4. Hold the handle on the new fan module with one hand and support the
bottom of the fan module with the other hand. Then, insert the fan module
into the chassis, as shown in Figure 4-72.
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Figure 4-72 Insert the fan module
5. Verify the function of the new fan module.
In normal situations, after the new fan module is inserted into the chassis, the
fans inside it immediately start to roatate. In this case, you can check whether
the new fan module functions normally in the following manners:
– If the FAN indicator on the panel of the fan module is on and green, it
indicates that the fan module runs normally.
If the indicator is red, it indicates that the fan module fails to run normally. If
the new fan module fails to return to the normal state, contact Huawei
technical personnel.
Follow-up Procedure
After replacing a part, collect the tools. If the part is faulty, maintenance personnel
should fill in the Offsite Repair Card for Faulty Materials, and send the card and
the faulty part to Huawei for timely maintenance.
4.1.13.4 Replacing an Optical Module
Context
CA UTION
Laser beams will cause eye damage. Do not look into bores of Optical Modules or
optical fibers without eye protection.
NO TICE
● Huawei-certified Optical Modules are strongly recommended because non-
Huawei-certified Optical Modules cannot ensure transmission reliability and
may affect service stability.
● Optical Modules are hot swappable, and you do not need to power off the
device when replacing Optical Modules.
● Optical Modules are electrostatic-sensitive components. Therefore, you must
take ESD protection measures when replacing Optical Modules.
● Only external Optical Modules can be replaced and pluggable. Built-in Optical
Modules cannot be replaced.
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Follow these guidelines when replacing an Optical Module:
● Replacing an Optical Module interrupts service transmission. Therefore,
replace an Optical Module only when you confirm that the Optical Module
has failed.
● Ensure that the new Optical Module has the same center wavelength and
complies with the same standards as the old one.
● When replacing an Optical Module, ensure that no optical fiber is connected
to the Optical Module. Install or remove optical fibers carefully to avoid
damages to fiber connectors. Exercise caution when installing or removing
optical fibers to prevent damage to the Optical Module.
● After removing the optical fibers from an Optical Module, cover the fiber
connectors with dust caps. Place the optical fibers in an appropriate place to
prevent them from swinging.
● Use assistant tools like the tweezers delivered with the device to remove an
Optical Module in a confined space.
● After removing a copper transceiver, wait at least 2 seconds before inserting a
new one. Otherwise, the port may fail to go Up. If the port cannot go Up,
remove the copper transceiver and install it 2 seconds later.
● If the LINK indicator on an optical port with two optical fibers is off, swap the
two optical fibers.
● During the replacement, keep the bores of the Optical Module and fiber
connectors clean, protecting them from dust and other contamination
sources. Install dust plugs on idle optical ports.
Tools and Accessories
● ESD wrist strap or ESD gloves
● Spare Optical Module
● Dust caps
● (Optional) Optical port dust plug
● (Optional) Tweezers
Procedure
1. Check the location of the Optical Module to be replaced.
Before pulling out an Optical Module that is to be replaced, you should first
check the location of the module, for example, the cabinet and chassis where
the Optical Module resides. Then, locate the Optical Module to be replaced in
the chassis and attach a label to the panel to identify the Optical Module.
2. Run the display interface interface-type interface-number command to view
and record the type of the Optical Module to be replaced, as the following
output in bold displays:
<HUAWEI> display interface Gigabitethernet0/1/0
GigabitEthernet0/1/0 current state : DOWN
Line protocol current state : DOWN
Description: HUAWEI, GigabitEthernet0/1/0 Interface (ifindex: 7)
Route Port,The Maximum Transmit Unit is 1500
IP Sending Frames' Format is PKTFMT_ETHNT_2, Hardware address is 001a-2b11-4d51
The Vendor PN is RTXM191-400
The Vendor Name is WTD
Port BW: 1G, Transceiver max BW: 1G, Transceiver Mode: SingleMode
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WaveLength: 1310nm, Transmission Distance: 10km
Rx Power: -1.43dBm, normal range: [-19.014, -3.000]dBm
Tx Power: -4.86dBm, normal range: [-6.859, -2.857]dBm
Loopback:none, full-duplex mode, negotiation: disable, Pause Flowcontrol:Receive Enable and
Send Enable
Last physical up time : 2012-10-11 10:01:20
Last physical down time : 2012-10-11 10:01:19
Current system time: 2012-10-12 09:53:44
Statistics last cleared:2012-10-12 09:02:03
Last 300 seconds input rate: 0 bits/sec, 0 packets/sec
Last 300 seconds output rate: 0 bits/sec, 0 packets/sec
Input peak rate 88 bits/sec, Record time: 2012-10-12 09:03:45
Output peak rate 78 bits/sec, Record time: 2012-10-12 09:02:54
Input: 2144 bytes, 22 packets
Output: 614 bytes, 7 packets
Input:
Unicast: 21 packets, Multicast: 1 packets
Broadcast: 0 packets, JumboOctets: 0 packets
CRC: 0 packets, Symbol: 0 packets
Overrun: 0 packets, InRangeLength: 0 packets
LongPacket: 0 packets, Jabber: 0 packets, Alignment: 0 packets
Fragment: 0 packets, Undersized Frame: 0 packets
RxPause: 0 packets
Output:
Unicast: 6 packets, Multicast: 1 packets
Broadcast: 0 packets, JumboOctets: 0 packets
Lost: 0 packets, Overflow: 0 packets, Underrun: 0 packets
System: 0 packets, Overruns: 0 packets
TxPause: 0 packets
Last 300 seconds input utility rate: 0.00%
Last 300 seconds output utility rate: 0.00%
3. Record the location of the cables and check whether the labels on the cables
are correct and clear. If the labels are hard to identify, re-make labels and re-
label the cables in case the cables are not connected properly.
4. Wear the ESD gloves or wrist strap and connect the grounding terminal to the
ESD jack on the rack.
5. Pull out the Optical Module to be replaced.
a. Remove the optical cables from the connector and cover the connector
with a dust cap.
b. Pull the bail-clasp or pull-tab latch on the optical module, as shown in
Figure2 and Figure3 respectively.
NO TE
When the operation space is insufficient, you can use a fiber interface clamp to
remove an Optical Module. Figure1 shows the appearance of a fiber interface
clamp.
Figure 4-73 Fiber interface clamp
c. Hold the handle to pull out the Optical Module carefully from the optical
interface, as (2) shown in Figure2. When installing a CFP Optical Module,
hold the screw rods with both hands, and slightly pull out the Optical
Module from the optical port.
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CA UTION
The QSFP28 and QSFP-DD modules will get very hot during operation. To
prevent injuries, do not touch the module shells when removing the
modules.
d. Place the removed Optical Module in the ESD bag.
Figure 4-74 Pulling out an bail-clasp Optical Module
Figure 4-75 pull-tab latchPulling out an Optical Module
6. Insert the new Optical Module into the optical interface.
a. Take out the new Optical Module from the ESD bag and check whether
there is any damage or component missing. Check whether the new
Optical Module is of the same type as the Optical Module to be replaced.
b. Insert the new Optical Module into the optical interface, as shown in
Figure 4-76. When the click of the reed in the Optical Module is heard, it
indicates that the Optical Module is correctly inserted. If the new Optical
Module is a CFP one, insert the new Optical Module into the optical port
of the card, push the transceiver panel horizontally into the connector
using even force with both thumbs. After the transceiver is inserted, push
the transceiver slightly to ensure that it has reached the stop position.
Pull out the two screw rods slightly to ensure that they can properly
function. Pre-tighten one of the screw rods. Then, tighten the other screw
rod. After that, tighten the first screw rod. To prevent the Optical Module
from getting loosened due to vibration or collision, you are advised to use
a screwdriver to tighten the screw rods.
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CA UTION
Do not insert an Optical Module reversely. If an Optical Module cannot
be completely inserted into an optical port, do not force it into the port.
Instead, turn the Optical Module over and try again.
Figure 4-76 Inserting an Optical Module
c. Remove the dust cap from the connector and insert the optical cables in
the original sequence.
7. Verify the functions of the new Optical Module.
Then, you can verify the functions of the new Optical Module in the following
ways:
– Check whether the LINK indicator on the optical interface works
normally. If the indicator is green, it indicates that the links connected to
the interface are Up.
– Run the display interface interface-type interface-number command on
the console interface to view the type and running status of the new
Optical Module. Check whether the type of the new Optical Module
corresponds to that of the original Optical Module, as the following
output in bold displays:
<HUAWEI> display interface Gigabitethernet0/1/0
GigabitEthernet0/1/0 current state : DOWN
Line protocol current state : DOWN
Description: HUAWEI, GigabitEthernet0/1/0 Interface (ifindex: 7)
Route Port,The Maximum Transmit Unit is 1500
IP Sending Frames' Format is PKTFMT_ETHNT_2, Hardware address is 001a-2b11-4d51
The Vendor PN is RTXM191-400
The Vendor Name is WTD
Port BW: 1G, Transceiver max BW: 1G, Transceiver Mode: SingleMode
WaveLength: 1310nm, Transmission Distance: 10km
Rx Power: -1.43dBm, normal range: [-19.014, -3.000]dBm
Tx Power: -4.86dBm, normal range: [-6.859, -2.857]dBm
Loopback:none, full-duplex mode, negotiation: disable, Pause Flowcontrol:Receive Enable
and Send Enable
Last physical up time : 2012-10-11 10:01:20
Last physical down time : 2012-10-11 10:01:19
Current system time: 2012-10-12 09:53:44
Statistics last cleared:2012-10-12 09:02:03
Last 300 seconds input rate: 0 bits/sec, 0 packets/sec
Last 300 seconds output rate: 0 bits/sec, 0 packets/sec
Input peak rate 88 bits/sec, Record time: 2012-10-12 09:03:45
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Output peak rate 78 bits/sec, Record time: 2012-10-12 09:02:54
Input: 2144 bytes, 22 packets
Output: 614 bytes, 7 packets
Input:
Unicast: 21 packets, Multicast: 1 packets
Broadcast: 0 packets, JumboOctets: 0 packets
CRC: 0 packets, Symbol: 0 packets
Overrun: 0 packets, InRangeLength: 0 packets
LongPacket: 0 packets, Jabber: 0 packets, Alignment: 0 packets
Fragment: 0 packets, Undersized Frame: 0 packets
RxPause: 0 packets
Output:
Unicast: 6 packets, Multicast: 1 packets
Broadcast: 0 packets, JumboOctets: 0 packets
Lost: 0 packets, Overflow: 0 packets, Underrun: 0 packets
System: 0 packets, Overruns: 0 packets
TxPause: 0 packets
Last 300 seconds input utility rate: 0.00%
Last 300 seconds output utility rate: 0.00%
– Check whether there is any new alarm or performance event.
– Check whether the services are normal on the new Optical Module. If the
services are normal, it indicates that replacing an Optical Module is
successful.
If the new Optical Module fails to return to the normal state, you should
contact a Huawei local office for timely technical support.
Follow-up Procedure
After replacing an Optical Module, collect the tools. If an Optical Module that is
replaced and is confirmed to be faulty, you should fill in the Offsite Repair Card
for Faulty Materials, and send the card and the faulty Optical Module to a Huawei
local office for timely maintenance.
4.1.13.5 Replacing an Optical Cable
Context
Before replacing an optical cable, you need to note the flowing points:
● During the process of replacing an optical cable, the services are interrupted
temporarily.
● Be careful when you remove or insert an optical cable in case that the
connector of the optical cable is damaged.
● When installing or maintaining an optical interface board or an optical cable,
do not observe an optical interface or connectors of an optical cable.
● The bending radius of a single-mode G.657A2 optical fiber is greater than or
equal to 10 mm, and the bending radius of a multi-mode A1b optical fiber is
greater than or equal to 30 mm.
● Connectors of optical cables are divided into the LC type and the SC type. You
must select an optical cable according to the interface type.
Tool
Before replacing an optical cable, you need the following tools:
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● Cutter
● Binding strap
● ESD wrist strap or ESD glove
Procedure
1. Record the location of both ends of the optical cable to be replaced and the
cabling mode.
2. Take out the new optical cable and check whether the type of the new optical
cable is consistent with that of the old one. The multi-mode optical cable is
orange and the single-mode optical cable is yellow.
3. Make a new label according to the contents of the label on the old optical
cable.
4. Lay out the new optical cable in the original place.
5. Remove the old optical cable.
a. Put on the ESD gloves or wrist strap and connect the grounding terminal
to the ESD jack on the rack.
b. Hold the connectors and remove them. Then, cover the connectors with
dust caps.
NO TE
If a connector is dusty, clean it with dust-free cloth or fiber cleaning paper.
c. Remove the old optical cable from the corrugated pipe.
6. Insert the new optical cable.
Before inserting the new optical cable, remove the dust caps and keep them
properly for future use. Then, connect both ends of the new optical cable to
the optical interfaces and secure the optical cables.
7. Attach a label to the new optical cable, as shown in Figure 4-77.
Figure 4-77 Attaching a label to a new optical cable
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8. Lay out the new optical cable in a tidy manner in the cabinet and bind the
optical cable with a binding strap. Note that the optical cable should be
bound with proper strength and with even space in between. Bind the
redundancies of the optical cable at the ODF side.
9. Check whether the new optical cable works normally.
a. Check the LINK indicator at the optical interface. If the indicator is steady
on and green, it indicates that the link is Up.
b. Check whether the service on the board where the new optical cable
connects is normal. If the services are normal, it indicates that the optical
cable is replaced successfully.
c. Check whether there is any new alarm or performance event.
Follow-up Procedure
After replacing an optical cable, collect the tools and the replaced optical cable.
Do not place the old and the new optical cables together to avoid confusions.
4.1.13.6 Replacing a Network Cable
Context
Before replacing a network cable, you need to note the following points:
● During the process of replacing a network cable, the services are interrupted
temporarily.
● It is recommended that you replace a network cable during the hours when
the network is not busy, for example, from 00:00 am to 06:00 am.
Tool
Before replacing a network cable, you need the following tools:
● Cutter
● Cable tie
● ESD wrist strap or ESD glove
● Cable tester
● Crimper
Procedure
1. Check the location and cabling of the network cable to be replaced.
2. Prepare a new network cable. The type of the new network cable must be
consistent with that of the old network cable. When a network cable is made,
test its connectivity with a cable tester.
3. Wear the ESD gloves or wrist strap and connect the grounding terminal to the
ESD jack on the rack.
4. Lay out the new network cable according to the original cabling mode.
If you need to replace more than one network cable at a time, you should
attach temporary labels to the new network cables to identify the cables. The
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new network cables must be numbered consistently with the network cables
to be replaced.
5. Remove the old network cable and record the location where the old network
cable is installed.
a. Remove the connectors of the network cable.
b. Cut the cable tie with a cutter and remove the network cable.
6. Insert the new network cable connector into the network interface of which
the location is recorded. If a click is heard, it indicates that the insertion is
successful. The indicator of the network interface being steady on and green
indicates that the link is Up.
7. Attach a label to the new network cable, as shown in Figure 4-78.
Figure 4-78 Attaching a label to a new network cable
8. Bind the cable with a cable tie and cut the redundancies of the tie.
9. Run the ping command to check the connection between both ends of the
new network cable. If both ends fail to communicate normally, check whether
the network cable is damaged or whether the connectors are secured.
Follow-up Procedure
After replacing a network cable, collect the tools and the replaced cable. Do not
place the old and the new cables together to avoid confusions.
4.1.14 Appendix
4.1.14.1 On-site Cable Assembly and Installation
4.1.14.1.1 Cable Assembly Precautions
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Checking the Appearance of Cables
● If the cable jacket or insulation is visibly dirty, clean it before assembly.
● If the jacket or insulation of a cable has visible damage, irreparable scuffing,
or other defects, do not use the cable.
● If the shield layer of a cable is damaged, do not use the cable.
● If the cable jacket or insulation cracks after the cable is bent or twisted,
discard this cable and check whether other cables have the same problem. If
other cables have the same problem, replace these cables.
Checking the Appearance of Connectors
● Do not use connectors with visible defects, damage, rust, or scuffing.
● Do not use connectors if their shells or pins have exposed part or uneven
plating, or their pins are lost, broken, or bent.
● Do not use connectors that have dirt on their pins or in their jacks or if there
are conductors between pins or between pins and the shell.
Precautions for Assembly
● Use dedicated tools or tools delivered by Huawei and follow the methods
given here during assembly.
● Hold terminals of cables instead of pulling the cables themselves when
installing or removing cable components.
● Take the following precautions when cutting or stripping cables:
– Make cables slightly longer than necessary.
– Coil cables longer than 2 m (6.56 ft) after cutting. Bind and fasten the
coils using bundling ropes. The inner diameters of the coils should be
larger than 20 times the outer diameters of the cables.
– When stripping the jackets of cables, avoid damaging the shield layers
(braid or aluminum foil), insulation, core conductors, and other jackets
that do not need to be stripped.
– After assembling cables, cut all visible cross sections of jackets to ensure
that the cross sections are arranged neatly.
– Do not touch the core conductors of cables with your hands. Terminate
exposed conductors in a timely way after stripping off insulation so that
the surface of the conductors does not become oxidized.
● Take the following precautions when crimping and connecting cables or
connectors:
– The terminals and conductors should be connected tightly after they are
crimped. They should not be moved or turned.
– Cut all the exposed copper wires.
– Try to avoid a second crimping of sleeves.
– Keep all the conductors clean and aligned.
NO TE
The connectors, cables, and tools provided by different vendors may be different. The
figures in this document are for your reference only.
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4.1.14.1.2 Assembling Power Cables
Assembling the OT Terminal and Power Cable
Background
Figure 4-79 shows the components of an OT terminal and a power cable.
Figure 4-79 the components of an OT terminal and a power cable
A. Heat shrink B. Bare crimping C. Insulation D. Conductor
tubing terminal
Procedure
1. Based on the cross-sectional area of the cable conductor, strip a length of
insulation coating C to expose the conductor D of length L1, as shown in
Figure 4-80. The recommended values of L1 are listed in Table 4-18.
Figure 4-80 Stripping a power cable (OT terminal)
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NO TICE
● When you strip a power cable, do not damage the conductor of the cable.
● If the bare crimping terminal is not provided by Huawei, the value of L1 is
1 mm (0.04 in.) to 2 mm (0.08 in.) greater than the value of L.
Table 4-18 Mapping between the cross-sectional area of the conductor and
the value of L1
Cross- Value of L1 (mm Cross-Sectional Value of L1 (mm
Sectional (in.)) Area of (in.))
Area of Conductor (mm2
Conductor (in.2))
(mm2 (in.2))
1 (0.002) 7 (0.28) 10 (0.015) 11 (0.43)
1.5 (0.002) 7 (0.28) 16 (0.025) 13 (0.51)
2.5 (0.004) 7 (0.28) 25 (0.039) 14 (0.55)
4 (0.006) 8 (0.31) 35 (0.054) 16 (0.63)
6 (0.009) 9 (0.35) 50 (0.077) 16 (0.63)
NO TE
If you are proficient in assembling OT terminals and power cables, you can obtain the
value of L1 by comparing the part to be crimped with the power cable.
2. Put the heat-shrinkable (A) tubing onto the bare crimping terminal, as shown
in Figure 4-81.
Figure 4-81 Putting the heat shrink tubing onto the bare crimping terminal
3. Put the OT terminal B onto the exposed conductor, and ensure that the OT
terminal is in good contact with the insulation coating C, as shown in Figure
4-81.
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NO TICE
After the conductor is fed into the OT terminal, the protruding part of the
conductor, or L2 in Figure 4-81, must not be longer than 2 mm (0.08 in.).
4. Crimp the joint parts of the bare crimping terminal and the conductor, as
shown in Figure 4-82.
NO TE
The shapes of crimped parts may vary with the crimping dies.
Figure 4-82 Crimping the joint parts of the bare crimping terminal and the
conductor (OT terminal)
5. Push the heat shrink tubing (A) toward the connector until the tube covers
the crimped part, and then use a heat gun to heat the tube, as shown in
Figure 4-83.
Figure 4-83 Heating the heat shrink tubing (OT terminal)
NO TICE
Stop heating the shrink tubing when the connector is securely locked in the
shrink tubing. Do not heat the shrink tubing too long as this may damage the
insulation coating.
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Assembling the JG2 Terminal and Power Cable
Bacnground
Figure 4-84 shows the components of a JG2 terminal and a power cable.
Figure 4-84 Components of a JG2 terminal and a power cable
A. Heat shrink B. JG2 terminal C. Insulation layer D. Conductor of a
tubing of a power cable power cable
Procedure
1. Strip a part of the insulation to expose the cable conductor with a length of L,
as shown in Figure 4-85. The recommended values of L are listed in Table
4-19.
Figure 4-85 Stripping a power cable (JG2 terminal)
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NO TICE
● When you strip a power cable, do not damage the conductor of the cable.
● If the bare crimping terminal is not provided by Huawei, you can adjust the
value of L as required
Table 4-19 Mapping between the cross-sectional area of the conductor and
the value of L
Cross-Sectional Area of Conductor Value of L (mm (in.))
(mm2 (in.2))
16 (0.025) 13 (0.51)
25 (0.039) 14 (0.55)
35 (0.054) 16 (0.63)
2. Put the heat shrink tubing onto the bare crimping terminal, as shown in
Figure 4-86.
Figure 4-86 Putting the heat shrink tubing onto the bare crimping terminal
3. Put the bare crimping terminal onto the exposed conductor, and ensure that
the bare crimping terminal is in good contact with the insulation of the power
cable, as shown in Figure 4-86.
4. Crimp the joint parts of the bare crimping terminal and the conductor, as
shown in Figure 4-87.
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Figure 4-87 Crimping the joint parts of the bare crimping terminal and the
conductor (JG2 terminal)
5. Push the heat shrink tubing toward the connector until the tube covers the
crimped part, and then use a heat gun to heat the tube, as shown in Figure
4-88.
Figure 4-88 Heating the heat shrink tubing (JG2 terminal)
Assembling the Cord End Terminal and Power Cable
Background
Figure 4-89 shows the components of a cord end terminal and a power cable.
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Figure 4-89 Components of a cord end terminal and a power cable
A. Cord end terminal B. Insulation layer of a C. Conductor of a power
power cable cable
Procedure
1. Strip a part of the insulation layer to expose the cable conductor with a
length of L1, as shown in Figure 4-90. Determine the value of L1 based on
the cross-sectional area of the cable conductor. The recommended values of
L1 are listed in Table 4-20.
NO TICE
When you strip a power cable, do not damage the conductor of the cable.
Figure 4-90 Stripping a power cable (cord end terminal)
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Table 4-20 Mapping between the cross-sectional area of the conductor and
the value of L1
Cross- Value of L1 (mm Cross-Sectional Value of L1 (mm
Sectional (in.)) Area of (in.))
Area of Conductor (mm2
Conductor (in.2))
(mm2 (in.2))
1 8 10 15
1.5 10 16 15
2.5 10 25 18
4 12 35 19
6 14 50 26
2. Put the cord end terminal onto the exposed conductor and ensure that the
conductor is aligned with the edge of the cord end terminal, as shown in
Figure 4-91.
NO TICE
After the conductor is fed into the cord end terminal, the protruding part of
the conductor must not be longer than 1 mm (0.04 in.).
Figure 4-91 Putting the cord end terminal onto the conductor
3. Select a proper cross-sectional area, and crimp the joint parts of the cord end
terminal and the conductor, as shown in Figure 4-92.
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Figure 4-92 Crimping the joint parts of the cord end terminal and the
conductor
4. Check the maximum width of the crimped terminal. Table 4-21 lists the
maximum width of a crimped terminal.
Table 4-21 Maximum width of a crimped terminal
Cross-Sectional Area of the Maximum Width of the Crimped
Terminal (mm2) Terminal — W1 (mm(in.))
0.25 1
0.5 1
1.0 1.5
1.5 1.5
2.5 2.4
4 3.1
6 4
10 5.3
16 6
25 8.7
35 10
Assembling an SPC1 Connector and the Power Cable
Context
NO TE
Colors and exteriors of cables may vary with countries and regions.
Figure1shows an SPC1 connector.
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Figure 4-93 Connector
(1) SPC1 (2) Scale (3) Hole for the cable
Procedure
1. Strip the jacket off the cable according to the scale on the connector, as
shown in Figure2.
NO TICE
● The figure for stripping the jacket shows the minimum length of the jacket
to be stripped off the cable.
● Ensure that the wires do not split during cable stripping.
Figure 4-94 Stripping the jacket off the cable
2. Insert the positive conducting wire to hole 1 (+) and the negative conducting
wire to hole 2 (–), as shown in Figure3.
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NO TICE
● Before power-on, check whether the positive and negative conducting
wires of all power cables are correctly connected. Any incorrect power
cable connection may cause damage to equipment or unexpected injuries
of human body.
● If the conducting wires are inserted properly, you will hear two click
sounds.
● When a cable is connected to an SPC1 connector, if the connector is not
removed and the cable is reversely connected, the following issues may
occur: sparking, fuse blowout, and connector damage. Therefore, remove
the SPC1 connector before the cable connection.
NO TE
The cross-sectional area of the cable supported by the SPC1 connector ranges from 1.5
mm2 to 10 mm2 or 0.0023 in.2 to 0.016 in.2.
Figure 4-95 Inserting the conducting wires
3. After the conducting wires are inserted, check whether they are secured by
springs from the visible window, as shown in Figure4. Pull each conducting
wire slightly to check whether it is securely connected. If the conducting wire
is pulled out a bit or a spring presses the insulation layer, remove and cut the
split conducting wire, and then strip the jacket and install the conducting wire
again.
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Figure 4-96 Checking whether conducting wires are secured by springs from
the visible window
NO TICE
● A conducting wire cannot deviate from the hole center, as shown in
Figure5.
● Ensure that the conducting wire is aligned with the cable hole, and avoid
the situation shown in Figure6.
Figure 4-97 Wire deviating from the hole center
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Figure 4-98 Wires not aligned with the holes
4.1.14.1.3 Assembling Ethernet Cables
Assembling the Shielded RJ45 Connector and Ethernet Cable
Background
Figure 4-99 shows the components of an RJ45 connector and a shielded Ethernet
cable.
Figure 4-99 Shielded RJ45 connector and cable
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A. Jacket of B. Metal shell of C. Wire holder of D. Plug of
connector connector connector connector
E. Jacket of F. Shield layer of G. Twisted-pair -
Ethernet cable Ethernet cable wires
Procedure
1. Fit the jacket of the connector onto the Ethernet cable, as shown in Figure
4-100.
Figure 4-100 Fitting the jacket of the connector onto the Ethernet cable
2. Remove a 30 mm (1.18 in.) long section of the jacket, cut off the nylon twine
inside the jacket, and cut a no more than 5 mm (0.20 in.) cleft in the jacket,
as shown in Figure 4-101.
Figure 4-101 Removing the jacket of a twisted-pair cable (unit: mm (in.))
NO TICE
● When you remove a section of the jacket, do not damage the shield layer
of the twisted-pair cable.
● When you remove the shield layer, do not damage the insulation of the
twisted-pair cable.
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3. Fit the metal shell onto the twisted-pair cable. The shield layer is covered by
the metal shell, as shown in Figure 4-102.
Figure 4-102 Fitting the metal shell onto the twisted-pair cable
4. Fit the metal shell onto the twisted-pair cable until the shield layer is covered
completely. Along the edge of the metal shell, cut off the aluminum foil shield
layer and ensure that there is no surplus copper wire. The exposed twisted-
pair cable is about 20 mm (0.79 in.) long, as shown in Figure 4-103.
Figure 4-103 Removing the shield layer of a twisted-pair cable (unit: mm
(in.))
5. Lead the four pairs of twisted-pair wires through the wire holder, as shown in
Figure 4-104 and Figure 4-105. Ensure that the colored wires are in the
correct location in the cable.
Figure 4-104 Leading wires through the wire holder
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Figure 4-105 Cable locations in a wire holder
6. Align the four pairs of cables in the holder, as shown in Figure 4-106. The
connections between the wires and the pins are shown in Figure 4-107 and
listed in Table 4-22.
Figure 4-106 Four pairs of cables on a wire holder
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Figure 4-107 Connections between wires and pins
Table 4-22 Connections between wires and pins (using a straight-through
cable as an example)
Matching Pins of Wires Wire Color
1 White-Orange
2 Orange
3 White-Green
4 Blue
5 White-Blue
6 Green
7 White-Brown
8 Brown
7. Cut off the surplus cables along the lower edge of the wire holder, as shown
in Figure 4-108.
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Figure 4-108 Cutting off surplus cables
8. Put the connector body onto the wire holder and turn the metal shell by 90°,
as shown in Figure 4-109.
Figure 4-109 Putting the connector body onto the wire holder
NO TE
Ensure that the wire holder is in good contact with the connector body.
9. Push the metal shell toward the connector body until the wire holder and the
connector body are engaged completely. Crimp the connector, as shown in
Figure 4-110.
Figure 4-110 Crimping the connector
10. Push the jacket towards the metal shell until the metal shell is covered. This
completes the assembly of one end of the cable, as shown in Figure 4-111.
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Figure 4-111 Pushing the metal shell
11. To complete the assembly of the other end, repeat steps 1 to 10.
Assembling an Unshielded RJ45 Connector and Ethernet Cable
Background
Figure 4-112 shows the components of an unshielded RJ45 connector and cable.
Figure 4-112 Components of an unshielded RJ45 connector and cable
A. Plug of connector B. Jacket C. Twisted-pair wires
Procedure
1. Remove a 16-mm (0.63 in.) long section of the jacket, as shown in Figure
4-113.
NO TICE
When you remove the shield layer, do not damage the insulation of the
twisted-pair cable.
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Figure 4-113 Removing the jacket of a twisted-pair cable (unit: mm (in.))
2. Align the four pairs of wires and cut the ends neatly, as shown in Figure
4-114. The connections between the wires and the pins are listed in Table
4-23.
Figure 4-114 Connections between wires and pins (unit: mm (in.))
Table 4-23 Connections between wires and pins (using a straight-through
cable as an example)
Matching Pins of Wires Wire Color
1 White-Orange
2 Orange
3 White-Green
4 Blue
5 White-Blue
6 Green
7 White-Brown
8 Brown
3. Feed the cable into the plug, and crimp the connector, as shown in Figure
4-115.
NO TE
When inserting the cable, check from the side or bore of the plug to ensure that the
cable is completely seated in the plug.
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Figure 4-115 Crimping the connector
4. To complete the assembly of the other end, repeat steps 1 to 3.
Checking the Appearance of Contact Strips
Background
● To ensure proper contact between the crimped wires and the wire conductors,
the heights and sizes of the contact strips must be standard and the same.
● The contact strips must be parallel to each other, with an offset of less than ±
5°. The top margin of a strip must be parallel to the axis of the connector,
with an offset of less than ± 10°.
● To ensure conductivity, the surface of the contact strips must be clean.
● The contact strips must be in good contact with the RJ45 socket. The plastic
separators must remain intact and be aligned.
● The contact strip blade must extend beyond the ends of the wires. The ends
of the wires must be in contact with the edge of the RJ45. The distance
between them must be less than 0.5 mm (0.02 in.).
Procedure
1. Hold the crimped connector, with the front side facing you, and check
whether the contact strips are of the same height. The height should be 6.02
± 0.13 mm (0.237 ± 0.005). If a measuring tool is not available, you can
compare the connector with a standard connector. Figure 4-116 shows an
unqualified piece, and Figure 4-117 shows a qualified piece.
NO TE
All unqualified pieces must be crimped again.
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Figure 4-116 Contact strips of different heights
Figure 4-117 Contact strips of the same height
2. Hold an RJ45 connector and turn it 45°. Observe the top edges of the metal
contact strips. Figure 4-118 shows an unqualified piece.
Figure 4-118 Unparallel contact strips of different heights
3. Check whether the contact strips are clean. If they are not clean and the dirt
cannot be removed, replace it with a new RJ45 connector. Figure 4-119 shows
an unqualified piece.
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Figure 4-119 Dirt on a contract strip
4. Check whether the contact strips and the plastic separators are well aligned
and intact. If a separator is skewed and cannot be fixed, replace it with a new
RJ45 connector. Figure 4-120 shows an unqualified piece.
Figure 4-120 Skewed plastic separators
5. Hold the connector with the side facing towards you, and check whether you
can see the cross-sections of the wires. Ensure that the ends of the wires are
in good contact with the edge of the RJ45, and that the contact strip blade
extends beyond the ends of the wires and is crimped with the wires. If not,
replace the connector. Figure 4-121 shows an unqualified piece.
Figure 4-121 Wires not in good contact with the edge of the RJ45
Testing the Connection of Assembled Cables
Background
Huawei provides two types of Ethernet cables: straight-through cables and
crossover cables.
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● Straight-through cables are connected in a one-to-one manner. They are used
to connect terminals such as a computer or switch to network devices. Table
Pin assignment of the straight-through cable connector lists the
connections of core wires in a straight-through cable.
Table 4-24 Pin assignment of the straight-through cable connector
Connector X1 Connector X2 Color Relation
Pin Pin
X1.1 X2.1 White-orange Twisted pair
X1.2 X2.2 Orange
X1.3 X2.3 White-green Twisted pair
X1.6 X2.6 Green
X1.4 X2.4 Blue Twisted pair
X1.5 X2.5 White-blue
X1.7 X2.7 White-brown Twisted pair
X1.8 X2.8 Brown
● Crossover cables are connected in a crossover manner. They are used to
connect terminals such as two computers or switches. Table Pin assignment
of the crossover cable connector lists the connections of core wires in a
crossover cable
Table 4-25 Pin assignment of the crossover cable connector
Connector X1 Connector X2 Color Relation
Pin Pin
X1.1 X2.3 White-orange Twisted pair
X1.2 X2.6 Orange
X1.3 X2.1 White-green Twisted pair
X1.6 X2.2 Green
X1.4 X2.4 Blue Twisted pair
X1.5 X2.5 White-blue
X1.7 X2.7 White-brown Twisted pair
X1.8 X2.8 Brown
Figure 4-122 shows the pins of an RJ45 connector.
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Figure 4-122 Pins of an RJ45 connector
Procedure
1. Feed both connectors of the cable into the ports of the cable tester.
2. After the connectors are properly inserted, turn on the tester. If the indicators
from 1 to G turn on simultaneously, you can infer that the pins work normally
and the wires are correctly connected.
NO TE
Turn the switch to the S position to slow down lighting of the indicators so that you
can see the indicators more clearly, as shown in Figure 4-123.
Figure 4-123 Testing the conduction and connections of wires
3. Gently shake the connector and repeat Step 2 to check whether the metal
contact strips are in good contact with the core wires and Ethernet ports, as
shown in Figure 4-124.
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Figure 4-124 Checking the reliability
The procedure for testing a crossover cable is the same as that for testing a
straight-through cable except for the sequence in which the indicators turn
on, which depends on the wire connections of a crossover cable.
The Ethernet cable is qualified if the indicators turn on in the following
sequence:
At the master (left) section of the tester, the indicators turn on in the
sequence of 1-8-G. At the slave (right) section of the tester, the indicators
turn on in the sequence of 3-6-1-4-5-2-7-8-G.
If the indicators do not come on in this sequence, the Ethernet cable is
unqualified.
NO TE
If a tester is not available, you can use a multimeter to perform a simple test, as
shown in Figure 4-125.
Figure 4-125 Testing the connection of an Ethernet cable
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4.1.14.1.4 Installing Cable Accessories
Precautions for Installing Cable Accessories
NO TE
The illustrations in this document may differ from actual situations, but the installation
methods are the same. For example, in this document, the adapters of cable connectors
have separate interfaces. In the actual situation, the adapters may have interfaces fixed on
equipment.
Tools
Use dedicated tools provided or specified by Huawei and follow the installation
procedure described here.
Bending Radius
Unless otherwise specified, bending radius (R) of cables or fibers must meet the
requirements listed in Table 4-26.
Table 4-26 Bending radius of cables or fibers
Cable or Fiber Bending Radius (R)
Ordinary cable In normal cases, R ≥ 2d. When the
cable is connected with a connector, R
≥ 5d.
Fiber Single-mode G.657A2 optical fiber: R ≥
10 mm (0.39 in.), bending angle > 90°
Multi-mode A1b optical fiber: 30 mm
(1.18 in.) ≤ R ≤ 40 mm (1.57 in.),
bending angle > 90°
NO TE
The letter d indicates the diameter of a cable or fiber.
Precautions for Installation
● Hold terminals of cables instead of pulling the cables themselves when
installing or removing cable components.
● Do not insert a connector forcibly when the connector is blocked. Use a
dedicated tool to pull out the connector. Install the connector again after you
check that the pins are inserted properly.
● Before tightening screws on cable connectors, ensure that the connectors are
properly connected to their adapters. Tighten the screw with appropriate force
using a flat-head or Phillips screwdriver instead of bare hands or an electric
screwdriver. If the screw cannot be screwed into the tapped hole, determine
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the reason and try again. Do not apply too much force, or the screw or
adapter may be damaged.
● When removing densely aligned cables or fiber connectors, use dedicated
pliers such as cable-pulling pliers and fiber-pulling pliers.
● Do not twist, bend, stretch, or extrude fibers during installation.
● Cover the idle fiber connectors with dust caps. Remove the dust caps before
using the fiber connectors.
Requirements for Cable Routing
● To protect cables, remove the burrs in the cable through-holes or install
protective rings in the holes.
● To ease the connection and to avoid stress, keep cable joints slack. After
connecting multiple cables to a connector that has multiple interfaces, keep
the cables slack to avoid generating stress.
● Bind or clean cables gently because cable distortion affects signal quality.
● Keep cables away from moveable components such as doors.
● Sharp objects must not touch cable wiring to prevent damage to cables.
● To protect power cables, route power cables of the active and standby power
modules separately.
Installing Power Adapters
?.1. Installing the OT Terminal
This section describes how to install OT terminals on the terminals. You can install
one OT terminal or two OT terminals on one terminal.
Procedure
● Install an OT terminal.
a. Align the hole of the OT terminal (conductor upward) with a connecting
hole, as shown in Figure 4-126.
Figure 4-126 Aligning the OT terminal with a connecting hole
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NO TE
When you install an OT terminal, the crimping sleeve is installed as shown in
Figure 4-127, where A is correct and B is incorrect.
Figure 4-127 Installing an OT terminal, showing the orientation of
crimping sleeve
b. Place the spring washer and flat washer in turn, mount a matching screw,
and fasten it clockwise, as shown in Figure 4-128.
Figure 4-128 Installing two terminals back to back
NO TICE
Ensure that the OT terminal is not in contact with other terminals or
metal components.
c. Move the cable slightly and ensure that it is securely connected, as shown
in Figure 4-129.
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Figure 4-129 Installed OT terminal
● Install two OT terminals on a post.
Before you install two OT terminals on a post, ensure that the two terminals
can be installed on the post and that the electrical connecting pieces have a
large contact area. Two OT terminals can be installed using any of these
methods:
– Bend the upper OT terminal at a 45- or 90-degree angle, as shown in
Figure 4-130.
– Cross the two terminals, as shown in Figure 4-131.
Figure 4-130 Bending the upper OT terminal at a 45- or 90-degree angle
Figure 4-131 Crossing two terminals
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NO TICE
If the two terminals are different sizes, place the smaller one above the bigger
one. A maximum of two terminals can be installed on a post.
● To remove an OT terminal, loosen the screw counterclockwise.
4.1.14.1.5 Installing Ethernet Adapters
Installing a Shielded Ethernet Connector
Procedure
1. Hold the male and female connectors, with the male connector facing the
female connector, as shown in Figure 4-132.
Figure 4-132 Holding the male and female shielded connectors
2. Insert the male connector into the female connector, as shown in Figure
4-133.
Figure 4-133 Feeding the male shielded connector into the female shielded
connector
3. When you hear a click, the cable connector is completely inserted in the port.
(The clip on the cable connector pops up to fix the connector in the port.) Pull
the connector slightly and ensure that it is securely connected, as shown in
Figure 4-134.
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Figure 4-134 Installed shielded Ethernet connector
4. To remove an Ethernet connector, press the locking key and pull out the
connector, as shown in Figure 4-135.
Figure 4-135 Removing a shielded Ethernet connector
Installing an Unshielded Ethernet Connector
Procedure
1. Hold the male and female connectors, with the male connector facing the
female connector, as shown in Figure 4-136.
Figure 4-136 Holding the male and female unshielded connectors
2. Feed the male connector into the female connector, as shown in Figure
4-137.
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Figure 4-137 Feeding the male connector into the female unshielded
connector
3. A crisp click indicates that the connector is locked by the locking key. Pull the
connector slightly and ensure that it is securely connected. Figure 4-138
shows an installed Ethernet connector.
Figure 4-138 Installed unshielded Ethernet connector
4. To remove an Ethernet connector, press the locking key and pull out the
connector, as shown in Figure 4-139.
Figure 4-139 Removing an unshielded Ethernet connector
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4.1.14.1.6 Installing Fiber Connectors
NO TE
● After you remove the dustproof cap, ensure that the fiber pins are clean and install
them as soon as possible.
● When you disassemble fiber connectors, you must use a dedicated tool if the connectors
are densely installed. Do not pull fiber protection pipes to remove fiber connectors.
Installing an FC Fiber Connector
Procedure
1. Remove the dustproof cap of the FC connector and store it for future use.
2. Align the core pin of the male connector with that of the female connector, as
shown in Figure 4-140.
Figure 4-140 Aligning the male connector with the female connector
3. Align the male connector with the female connector and gently push the
male connector until it is completely seated in the female connector, as
shown in Figure 4-141.
Figure 4-141 Feeding the male connector into the female connector
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4. Fasten the locking nut clockwise and ensure that the connector is securely
installed, as shown in Figure 4-142.
Figure 4-142 Fastening the locking nut
5. To disassemble an FC fiber connector, loosen the locking nut
counterclockwise, and gently pull the male connector, as shown in Figure
4-143.
Figure 4-143 Disassembling an FC fiber connector
Installing an LC Fiber Connector
Procedure
1. Remove the dustproof cap of the LC fiber connector and store it for future
use.
2. Align the core pin of the male connector with that of the female connector, as
shown in Figure 4-144.
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Figure 4-144 Aligning the male connector with the female connector
3. Align the male connector with the fiber adapter and gently push the male
connector until it is completely seated in the fiber connector, as shown in
Figure 4-145.
Figure 4-145 Feeding the male connector into the female connector
4. A clicking sound indicates that the male connector is locked, as shown in
Figure 4-146.
Figure 4-146 Installed LC connector
5. To disassemble an LC fiber connector, press the locking nut to release the
locking clips from the bore, and gently pull the male connector, as shown in
Figure 4-147.
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Figure 4-147 Disassembling an LC fiber connector
Installing an SC Fiber Connector
Procedure
1. Remove the dustproof cap of the SC fiber connector and store it for future
use.
2. Align the core pin of the male connector with that of the female connector, as
shown in Figure 4-148.
Figure 4-148 Aligning the male connector with the female connector
3. Feed the fiber connector into the female connector, with your fingers holding
the shell of the fiber connector (not the pigtail). When you hear a click, the
fiber connector is secured by the clips (internal parts, not illustrated in the
figure). Pull the fiber connector gently. If the connector does not loosen, the
installation is complete. As shown in Figure 4-149.
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Figure 4-149 Installed SC fiber connector
4. To disassemble an SC fiber connector, hold the shell of the connector (do not
hold the fiber) and gently pull the connector in the direction vertical to the
adapter. Unlock the male connector, and then separate it from the shell, as
shown in Figure 4-150.
Figure 4-150 Disassembling an SC fiber connector
NO TICE
During operation, pinch the housing instead of the tail.
Installing an MTRJ Fiber Connector
Procedure
1. Remove the dustproof cap of the MTRJ fiber connector and store it for future
use.
2. Align the core pin of the male connector with that of the female connector,
make sure that the center PINs of the two connectors are on the same axis,
and the pins and card slots are in the same direction, as shown in Figure
4-151.
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Figure 4-151 Aligning the male connector with the female connector
3. Align the fiber adapter along the axis and gently push the fiber plug, as
shown in Figure 4-152.
Figure 4-152 Feeding the male connector into the female connector
4. When you hear a "click", it has been plugged into place. At this time, the
hook has popped up to lock the fiber plug. Pull gently without loosening, as
shown in Figure 4-153.
Figure 4-153 Installed MTRJ fiber connector
5. When disassembling, lightly press the button of the optical fiber plug to
disengage the hook from the slot, and gently pull the optical fiber plug
housing along the axis, and the disassembly is completed, as shown in Figure
4-154.
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Figure 4-154 Disassembling a MTRJ fiber connector
Installing an MPO Connector
Procedure
1. Remove the dustproof cap of the MPO fiber connector and store it for future
use.
2. Align the core pin of the male connector with that of the female connector, as
shown in Figure 4-155.
Figure 4-155 Aligning the male connector with the female connector
3. Hold the shell labeled "PUSH" and feed the male connector into the female
connector until you hear a clicking sound. The male and female connectors
are securely installed, as shown in Figure 4-156.
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Figure 4-156 Installed MPO fiber connector
4. To disassemble an MPO fiber connector, hold the shell labeled "PULL" and
remove the male connector, as shown in Figure 4-157.
Figure 4-157 Disassembling an MPO fiber connector
4.1.14.1.7 Replacing the Mold of the Crimping Tool
Procedure
1. Hold the handles of a pair of COAX crimping tools. Loosen the two fastening
screws counterclockwise, as shown in Figure 4-158.
Figure 4-158 Loosening two fastening screws
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2. Hold the handles of the COAX crimping tools to open the self-locking
mechanism. The jaw of the COAX crimping tools opens automatically, as
shown in Figure 4-159.
Figure 4-159 Pliers jaw opening automatically
3. Remove the mold from the COAX crimping tools, as shown in Figure 4-160.
Figure 4-160 Removing the mold from the COAX crimping tools
4. Place the mold to be installed into the jaw of the COAX crimping tools and
align the screw holes, as shown in Figure 4-161.
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Figure 4-161 Installing a new mold in the COAX crimping tool
NO TICE
Keep the short side of the mold inwards and the long side outwards, with the
teeth of the mold aligning from the larger size to the smaller size.
5. Hold the handles of the COAX crimping tools tightly to match the mold and
the jaw completely. Align the screw holes, as shown in Figure 4-162.
Figure 4-162 Aligning the screw holes
6. Hold the handles of the COAX crimping tools with one hand. Tighten the two
fastening screws clockwise. Figure 4-163 and Figure 4-164 shows the mold
installed in the COAX crimping tool.
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Figure 4-163 Mold installed in the COAX crimping tool
Figure 4-164 An installed mold
4.1.14.2 Environmental Requirements for Device Operation
4.1.14.2.1 Environmental Requirements for Equipment Room
Requirements for Selecting a Site for Equipment Room
When designing a project, consider the communication network planning and
technical requirements of the equipment. Also consider hydrographic, geological,
seismic, power supply, and transportation factors.
Construction, structure, heating and ventilation, power supply, lighting and fire-
proof construction of the equipment room should be designed by specialized
construction designers to suit the environmental requirements of devices. The
equipment room should also follow local regulations concerning the industrial
construction, environmental protection, fire safety, and civil air defense.
Construction must conform to government standards, regulations, and other
requirements.
The equipment room should be located in a place free from high temperature,
dust, toxic gases, explosive materials, or unstable voltage. Keep the equipment
room away from significant vibrations or loud noises, as well as power transformer
stations.
The specific requirements for selecting a site for an equipment room are as
follows:
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● The room should be located at a distance of at least 5 km (3.11 mi.) from
heavy pollution sources such as smelting and coal mines. It should be located
at a distance of at least 3.7 km (2.30 mi.) from moderate pollution sources
such as chemical, rubber, and galvanization factories. It should be located at a
distance of at least 2 km (1.24 mi.) from light pollution sources such as
packinghouses and tanyards. If these pollution sources cannot be avoided,
ensure that the equipment room is upwind of the pollution sources. In
addition, use a high-quality equipment room or protection products.
● The room should be located away from livestock farms, or be upwind of the
livestock farms. Do not use an old livestock room or fertilizer warehouse as
the equipment room.
● The equipment room must be far away from residential areas. An equipment
room that is not far away from residential areas must comply with equipment
room construction standards to avoid noise pollution.
● The room should be located far away from industrial and heating boilers.
● The room should be at least 3.7 km (2.30 mi.) away from the seaside or salt
lake. Otherwise, the equipment room should be airtight with cooling facilities.
In addition, alkalized soil cannot be used as the construction material.
Otherwise, equipment suitable for wet conditions must be used.
● The doors and windows of the equipment room must be kept closed to
maintain an airtight room.
● Using steel doors to ensure sound insulation is recommended.
● No cracks or openings are allowed on the walls or floors. The outlet holes on
the walls or windows must be sealed. Walls must be constructed such that
they are smooth, wear-resistant, dustproof, flame retardant, sound insulated,
heat absorptive, and have electromagnetic shielding.
● The air vent of the room should be far from the exhaust of city waste pipes,
big cesspools and sewage treatment tanks. The room should be in the positive
pressure state to prevent corrosive gases from entering the equipment room
and corroding components and circuit boards.
● It is recommended that the room be on or above the second floor. If this
requirement cannot be met, the ground for equipment installation in the
room should be at least 600 mm (23.62 in, ) above the maximum flood level.
● The equipment room should be strong enough to resist winds and downpours.
● The room should be located away from dusty roads or sand. If this is
unavoidable, the doors and windows of the equipment room must not face
pollution sources.
● Do not place air conditioning vents near the equipment so that they blow
directly on the equipment because condensation may be blown into the
equipment.
● Do not use decorative materials that contain sulfur in the equipment room.
Equipment Room Layout
An equipment room usually contains mobile switching equipment,
telecommunications equipment, power supply equipment, and other auxiliary
equipment. To ensure easy maintenance and management, place the equipment
in different rooms. Figure 4-165 shows the layout of the equipment room.
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Figure 4-165 Layout of the equipment room
The general layout principles of the equipment room are as follows:
● It should meet requirements for laying out and maintaining communication
cables and power cables.
● It should reduce the cabling distance, which facilitates cable maintenance,
reduces potential communication faults, and maximizes efficiency.
Construction Requirements for the Equipment Room
Table 4-27 describes the construction requirements for the equipment room.
Table 4-27 Construction requirements for the equipment room
Item Requirements
Area The smallest area of the equipment room can accommodate the
equipment with the largest capacity.
Net height The minimum height of the equipment room should not be less
than 3 m (9.84 ft). The minimum height of the equipment room
is the net height below overhead beams or ventilation pipes.
Floor The floor in the equipment room should be semi-conductive and
dustproof. A raised floor with an ESD covering is recommended.
Cover the raised floor tightly and solidly. The horizontal
tolerance of each square meter should be less than 2 mm (0.08
in.). If raised floors are unavailable, use a static-electricity-
conductive floor material, with a volume resistivity of 1.0 x 10^7
ohms to 1.0 x 10^10 ohms. Ground this floor material or raised
floor. You can connect them to ground using a one megohm
current-limiting resistor and connection line.
Load-bearing The floor must bear loads larger than 561 kg/m2 (0.79 bf/in.2).
capacity
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Item Requirements
Door and The door of the equipment room should be 2 m (6.56 ft) high
windows and 1 m (3.28 ft) wide. One door is enough. Seal the doors and
windows with dustproof plastic tape. Use double-pane glass in
the windows and seal them tightly.
Wall surface Paste wallpaper on the wall or apply flat paint. Do not use
treatment pulverized paint.
Cable trays Use cable trays to arrange cables. The inner faces of the cable
trays must be smooth. The reserved length and width of the
cable trays, and the number, position and dimensions of the
holes must comply with the requirements of device
arrangement.
Water pipe Do not pass service pipes, drainpipes, and storm sewers through
the equipment room. Do not place a fire hydrant in the
equipment room, but place it in the corridor or near the
staircase.
Internal Separate the area where the equipment is installed from the
partition wall equipment room door. The partition wall can block some outside
dust. As shown in Figure 4-166.
Installation Install air conditioner vents so that the air does not blow directly
position of on equipment.
the air
conditioner
Other Avoid the proliferation of mildew, and keep out rodents (like
requirements mice).
Figure 4-166 Internal partition wall inside the equipment room
Equipment Room Environment
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Dust on devices may cause electrostatic discharge and result in poor contact for
connectors or metal connection points. This problem can shorten the life span of
devices and cause faults.
The equipment room must be free from explosive, conductive, magnetically-
permeable, and corrosive dust. Table 4-28 lists the requirement for dust
concentration in the equipment room.
Table 4-28 Requirements for dust particles in the equipment room
Mechanical active Unit Concentration
material
Dust particle Particle /m3 ≤ 3x 104
(no visible dust
accumulated on a
workbench in three
days)
Suspending dust mg/m3 ≤0.2
Precipitable dust mg/m2·h ≤1.5
NOTE
● Dust particle diameter ≥ 5 µm
● Suspending dust diameter ≤ 75 µm
● 75 µm ≤ precipitable dust diameter ≤ 150 µm
Take the following measures to meet the requirements:
● Use dustproof materials for ground, wall, and ceiling construction.
● Use screens on the door and windows facing outside. The outer windows
should be dust-proof.
● Clean the equipment room regularly and clean the air filter door monthly.
● Wear shoe covers and ESD clothing before entering the equipment room.
Requirements for Corrosive Gases
The room should be free from dusts and corrosive gases, such as SO2, H2S, and
NH3. Table 4-29 lists the requirements for the corrosive gas concentration.
Table 4-29 Requirements for corrosive gas concentration
Chemical Unit Concentration
active material
3
SO2 mg/m ≤0.30
3
H2S mg/m ≤0.10
3
NOx mg/m ≤0.50
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Chemical Unit Concentration
active material
3
NH3 mg/m ≤1.00
3
Cl2 mg/m ≤0.10
HCl mg/m3 ≤0.10
HF mg/m3 ≤0.01
3
O3 mg/m ≤0.05
Take the following measures to meet the requirements:
● Avoid constructing the room near a place where the corrosive gas
concentration is high, such as a chemical plant.
● Ensure the air intake vent of the room is in the prevailing upwind direction
from any pollution source.
● Place batteries in different rooms.
● A professional service should monitor the corrosive gas conditions regularly.
Requirements for ESD Prevention
The absolute value of electrostatic voltage must be less than 1000 V.
Take the following measures to meet this requirement:
● Train operators about ESD prevention.
● Keep the correct humidity level in the equipment room to reduce the impact
of static electricity.
● Lay out an ESD floor in equipment rooms.
● Wear ESD shoes and clothing before entering equipment room.
● Use ESD tools, such as wrist straps, tweezers, and pullers.
● Ground all conductive materials in the room, including computer terminals.
Use ESD worktables.
● Keep non-ESD materials (such as common bags, foam, and rubber) at least
30 cm (11.81 in.) away from boards and ESD-sensitive components.
Electromagnetism Requirements for the Equipment Room
All interference sources, inside or outside the equipment room, can cause
equipment problems with capacitive coupling, inductive coupling, electromagnetic
wave radiation, and common impedance (including grounding system) coupling.
Prevent the interference using these approaches:
● Take effective measures against electrical interference from the power supply
system.
● Do not use the working ground of the equipment as the same ground for
surge protection. Separate them as far as possible.
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● Keep the equipment far away from high-power radio transmitters, radar units,
and high-frequency and high-current equipment.
● Use electromagnetic shielding if necessary.
Requirements for Lightning Proof Grounding
Table 4-30 lists the requirements for lightning proof grounding.
Table 4-30 Requirements for lightning proof grounding
Item Requirements
Capital ● Use reinforced concrete to construct the equipment room.
construction ● Install a lightning proof device like a lightning rod outside
the room.
● The lightning proof ground shares the same grounding
body with the protective ground of the room.
Power cables ● After the AC low-voltage power cables are led into the
leading in the room, install the surge protector for the power cables in the
equipment AC voltage stabilizer and the AC power distribution panel
room need to (box). Correctly ground the surge protector nearby.
be equipped ● After the DC power cable is led into the equipment room or
with a surge outdoor cabinet from outdoors or outside the cabinet,
protector install a power lightning protection device for the DC power
cable. The lightning protection device should be grounded
in proximity.
● For an equipment room in urban area, install a power
supply surge protector with the nominal discharge current
of no less than 20 kA. For an equipment room that is built
in a suburb and subject to lightning strikes, install a power
supply surge protector with the nominal discharge current
of more than 60 kA. For an equipment room that is built in
a mountain area and subject to frequent lightning strikes,
or in a separate high-rise building in a city, install a power
supply surge protector with the nominal discharge current
of more than 100 kA.
● The ground cable of the surge protector should be no
longer than 1 m (3.28 ft).
Grounding for ● Connect the DC working ground (positive pole of the -48 V
DC power DC power supply or the negative pole of the 24 V DC power
distribution supply) with the indoor collective ground cable nearby. The
total ground cable should meet the maximum load of the
equipment.
● The power equipment must have a DC working ground
cable, which can connect the power equipment to the
collective ground cable of the telecommunication site (or
the protective ground bar of the equipment room).
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Item Requirements
Equipotential ● Properly ground the devices and auxiliary devices in the
connection room such as mobile base station, transmission, switching
equipment, power supply equipment, and cable distribution
frame. Connect all PGND cables to the collective protective
ground bar. Connect all PGND cables in one equipment
room to one protective ground bar.
● Apply joint grounding to the working ground and protective
ground of devices, which means the two share one
grounding network.
● The cable tray, rack or shell, metal ventilation pipe, metal
door or window of the equipment should be grounded for
protection.
General ● Do not connect the neutral line of the AC power cable with
requirements the protective ground of any telecom equipment in the
for grounding equipment room.
● Do not install a fuse or switch on the ground cable.
● All ground cables should be as short as possible, and
arranged in a straight line.
Grounding ● The grounding resistance must be lower than 1 ohm.
resistance ● The upper end of the grounding body should be at least 0.7
m (2.30 ft) over the ground. In cold areas, bury the
grounding body below the frozen ground.
● Measure the grounding resistance periodically to ensure
effective grounding.
Routing of ● Do not arrange the signal cables overhead in the
signal cable equipment room. All signal cables must be led into the site
underground.
● Use the cables with a metal jacket or place them into a
metal pipe if they come out/in the equipment room.
● Ground the idle lines inside the cable in the equipment
room.
● Signal cables should be deployed on internal walls. Do not
deploy outdoor aerial cables.
● Keep signal cables away from power cables and surge
protection devices.
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Item Requirements
Collective ● Use a ground ring or ground bar for the collective ground
ground cable cable.
● Do not use aluminum cables as ground cables. Adopt
measures to prevent electrification corrosion when
connecting different metal parts together.
● Use a copper busbar as the collective ground cable with a
cross-sectional area of no less than 120 mm2 (0.19 in.2), or
use the galvanized flat steel of the same resistance. Insulate
the collective ground cable from the reinforcing steel bars
of the building.
Grounding The grounding lead-in should be a maximum of 30 m (98.42
lead-in ft) long. Use the galvanized flat steel with cross-sectional area
of 40 mm x 4 mm (1.58 in. x 0.158 in.) or 50 mm x 5 mm
(1.97 in. x 0.197 in.).
4.1.14.2.2 Requirements for Power Supply
Requirements for AC Power Supply
An AC power supply system consists of power mains, uninterruptible power
supplies (UPSs), and self-supplied electric generators, and should use a centralized
power supply mode. In addition to meeting the requirements of the server load,
the AC power supply must have a simple connection line, safe operation, flexible
scheduling, and easy maintenance.
The low-voltage power supply should be 3-phase, 5-wire mode or monophase 3-
wire mode. This AC power supply should be 110 V/220 V, with a frequency of 50
Hz.
The UPS should supply the same power and operate at the same phase as the
power mains. The switching time between the UPS and mains should be less than
10 ms; otherwise, the networking devices will reboot or reset.
For power distribution capacity in the equipment room, both the working current
and fault current of the devices should be considered. Ensure that independent AC
power supplies protect independent devices. Configure the current-carrying
capacity of the protection switch of the equipment room for more than that of the
devices.
Table 4-31 lists the voltage range of the AC power supply for the devices.
Table 4-31 Voltage range of AC power supply
Item Requirements
AC power capacity to -10% to +5% of the rated voltage
support the devices
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Item Requirements
AC power capacity to -15% to +10% of the rated voltage
support the power
modules and important
buildings
Frequency of alternating -4% to +4% of the rated value
current
Voltage wave shape sine Within 5% of the rated voltage
distortion
The automated electric generator must have a standard interface that supports
telecommunication protocols, remote telecommunication, monitoring, and control.
AC power cables should meet the following specifications:
● AC neutral should have a conductor with the same cross section as the phase
line.
● AC cables should have non-flammable insulation. The layout of AC cables
should comply with local regulations. Low-voltage power distribution rooms
should comply with local regulations.
Recommendations for AC Power Supply
The following are recommendations for the AC power supply.
● If the voltage of the power mains that supply power directly to devices
exceeds the rated voltage by -10% to 5%, or exceeds the voltage range that
devices can support, a voltage regulating device or voltage stabilizing device
is required.
● If the mains do not supply power for the device directly, or if the mains
voltage exceeds the rated voltage by -15% to 10% or exceeds the input
voltage range of the DC power supply, a voltage regulating device or voltage
stabilizing device is required.
● A UPS or inverter power supply system is required to provide uninterrupted
AC power to support the telecommunication load.
● If abnormalities occur on the mains, telecommunication servers should be
equipped with a self-supplied electric generator to support the key
telecommunication load. The capacity should be not less than 150% to 200%
of the total uninterruptible power supply.
● Storage batteries are usually installed in a parallel connection of two groups.
UPS storage batteries are generally installed in one group. The redundancy
required for the UPS can rely on concatenation or parallel connection. When
an inverter or a UPS is used, the active inverter is determined by the
maximum power and a backup inverter is required.
Requirements for DC Power Supply
The equipment room should receive stable and reliable DC power. Deploy the
power equipment near the telecommunications equipment to make the DC feeder
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as short as possible. To reduce power consumption and installation cost, the loop
voltage drop from the battery port to the equipment port should be less than 3.2
V.
● A large-scale enterprise can deploy an independent power supply system on
each floor to supply power to the telecommunications equipment room on
the respective floor.
● A medium-scale enterprise can use a power room and a battery room for
centralized power supply or use distributed power supply systems.
● A small-scale enterprise can deploy an integrated power supply system in its
equipment room but must take measures to prevent corrosive gases released
from batteries from eroding circuit boards of telecommunications equipment.
Table 4-32 lists the specifications for the DC power supply.
Table 4-32 Specifications for the DC power supply
Item Requirements
DC power Greater than 1.5 times the rated current
capacity to
support the
surge current
Regulated If the AC input voltage is in the range of 85% to 110% of the
voltage rated value, and the load current is in the range of 5% to
precision 100% of the rated value, the output voltage of the rectifier
ranges from -46.0 V to -56.4 V, with the regulated voltage
precision less than or equal to 1%.
Overshoot Integral value of the DC output voltage ±5%
amplitude of
switch on/off
Peak noise ≤200 mV
voltage
Dynamic The recovery time is less than 200 ms. The overshoot is in the
response range of the integral value of the DC output voltage ±5%.
Recommendations for DC Power Supply
The following are recommendations for the DC power supply.
● Use distributed power supply mode. Use multiple DC power supply systems
and put power equipment in multiple locations.
● Adopt a standard DC power supply system, and set the output voltage to the
communications equipment within the required range.
● Improve reliability of the AC power supply system to reduce the necessary
capacity of storage batteries. For small offices, increase the capacity of
storage batteries if it is difficult to enhance reliability of the AC power supply
system.
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● The total capacity of the high-frequency switching rectifier must satisfy the
power of the communication loading and battery charging. If there are 10 or
fewer active rectifier modules, configure one backup module. If there are
more than 10 active modules, configure one backup module for every 10
active modules.
● Install storage batteries in two or more groups. The capacity is determined by
the duration for which the storage batteries must supply power. For most
offices, the batteries should be able to supply power for at least one hour.
4.1.14.3 Equipment Grounding Specifications
4.1.14.3.1 General Grounding Specifications
Table 4-33 shows the general grounding specifications.
Table 4-33 General grounding specifications
No. Description
1 The working ground and protective ground, including the shielded
ground and the lightning-proof ground of the cable distribution frame
should share the same grounding conductor.
2 The cable trays, shells, metal ventilation pipes, metal doors and windows
in the equipment room should be grounded for protection.
3 The metal parts of the equipment which are electrically floating in
normal conditions should be grounded for protection.
4 The ground cable must be connected securely to the protective ground
bar of the equipment room.
5 Do not use other equipment as part of the ground cable or electrical
connection.
4.1.14.3.2 Grounding Specifications for Equipment Room
The grounding resistance of a comprehensive communication building should be
less than or equal to one ohm. The grounding resistance of an ordinary
communication office should be less than five ohms. The grounding resistance in
an area where the earth resistance rate is high should be less than 10 ohms.
4.1.14.3.3 Grounding Specifications for Devices
Table 4-34 lists the equipment grounding specifications.
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Table 4-34 Equipment Grounding Specifications
No. Description
1 All communication devices and auxiliary devices (such as mobile base
stations, transmission and switching devices, power supply devices) in
the equipment room should be grounded for protection. Connect all
protective ground for various devices jointly to a general ground bar, and
then to the same protective ground bar in the room together with the
protective ground (PGND) of the device.
2 The PGND of the equipment is shorted to the copper ground bar
provided by the customer. The short-circuiting cable used should be a
yellow-green plastic insulated cable with a copper core and a cross-
sectional area greater than 25 sq. mm (0.039 sq. in.).
3 There are grounding terminals and grounding lugs at the lower part of
the front door, rear door and side panel of the cabinet, connected to the
grounding terminals of the cabinet framework through connection
cables with cross-sectional area of no less than 1.6 sq. mm (0.002 sq.
in.).
4 Ensure that all metal components of the cabinet conduct well. No
insulating coating should be sprayed on the connection part of the metal
components.
5 Connect the cabinets in the same row by fastening captive screws and
gaskets on the top of the cabinets. Do not spray any coating into a
rectangular area measuring 30 mm x 50 mm (1.18 in. x 1.97 in.) around
the connection hole for a captive bolt. Measures to prevent rust and
corrosion must be taken for this area. Zinc electroplating with iridescent
yellow chromate conversion coating should be applied to the gasket and
nut to ensure good electrical contact.
6 When combining cabinets of the same type, short-circuiting cables are
required to connect the ground busbars (if any) of the cabinets. The
cross-sectional area of the short-circuiting cable is 6 sq. mm (0.009 sq.
in.) and is no more than 300 mm (11.8 in.) long. Connect the two ends
of the short-circuiting cable to the ground busbar terminals of
neighboring cabinets and fix them firmly.
4.1.14.3.4 Grounding Specifications for Communications Power Supply
Table 4-35 shows the grounding specifications for communication power supplies.
Table 4-35 Grounding specifications for communication power supplies
No. Description
1 The inlet for the AC power cable at the equipment room should be
equipped with a surge protection device (C-level) with a nominal
discharge current no less than 20 kA.
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No. Description
2 The protective ground for the power supply and that for communication
equipment share the same grounding conductor. If the power supply and
the equipment are in the same equipment room, use the same
protective ground bar for them if possible.
3 Use a surge protection circuit on the AC power interface.
4 The positive of the -48 V DC power supply or negative pole of the 24 V
DC power supply should be grounded at the output of the DC power
supply.
5 The working ground and protective ground of the DC power supply
equipment should use the same grounding conductor with the protective
ground of the switching equipment. If the power supply and equipment
are in the same equipment room, use the same protection ground bar
for them if possible.
6 Add surge protection on the DC power interface.
4.1.14.3.5 Grounding Specifications for Signal Cables
Table 4-36 lists the grounding specifications for signal cables.
Table 4-36 Grounding specifications for signal cables
No. Description
1 Equip the cable outdoors with a metal jacket, well grounded at both
ends, or connect the ends of the metal jacket to the protective ground
bar of the equipment room. For cables inside the equipment room,
install surge protection devices at the interface to the equipment. The
PGND cable for the surge protection devices should be as short as
possible.
2 The incoming and outgoing signal cables to and from the office and
unused wires inside the cable should be grounded for protection.
3 The Tone & Data Access (TDA) cable must pass through the Main
Distribution Frame (MDF) with surge protective device (SPD) when
going out of the office. The cable's shield layer should be connected to
the protective ground of the MDF. The MDF should use the same
grounding conductor as the cabinet.
4 Do not route signal cables overhead.
4.1.14.3.6 Specifications for Laying Out Grounding Cables
Table 4-37 shows the specifications for the ground cable.
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Table 4-37 Specifications for laying out ground cables
No. Description
1 The grounding wire should not run parallel to or twist around the signal
cable.
2 Bury ground underground or arrange them indoors. Do not route ground
cables overhead.
3 Do not connect two cables together to extend the PGND cable, or add
any switches or fuses.
4 The PGND cable should be an alternating yellow and green plastic
insulated one with a copper core.
5 The neutral line of the AC power cable cannot be connected to the
protective ground of transmission and communication equipment in the
equipment room.
6 A PGND cable should be as short as possible, with a length of no more
than 45 m (147.64 ft).
4.1.14.4 Engineering Labels for Cables
An engineering label serves as an identifier for on-site installation and
maintenance after the installation. Labels on the cables facilitate correct and
orderly connection of cables, and easy maintenance after installation.
Engineering labels are specialized for power cables and signal cables:
● Signal cables include network cables, optical fibers, and user cables.
● Power cables include the AC power cables and DC power cables.
NO TE
Fill in labels according to specified requirements to keep consistency of labels in the
equipment room. Make a relevant statement in the self-check report.
4.1.14.4.1 Introduction to Labels
Label Materials
Features:
● Thickness: 0.09 mm (0.004 in.)
● Color: chalk white
● Material: polyester (PET)
● Ambient temperature: -29°C (-20.2°F) to +149°C (300.2°F)
● Printed by a laser printer and written with a marker
● Pass UL and CSA authentication
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Type and Structure
Label for Signal Cables
The label for signal cables is L-shaped with fixed dimensions, as shown in Figure
4-167.
Figure 4-167 Label for signal cable
To specify more clearly the position of a cable, use the dividing lines on the label.
For example, there is a dividing line between the cabinet number and the chassis
number, and another one between the chassis number and the slot number. Each
dividing line is light blue (Pantone 656c) and 1.5 mm x 0.6 mm (0.06 in. x 0.02
in.).
The cut dotted line helps to fold the label when affixed to the cable, and its size is
1 mm x 2 mm (0.04 in. x 0.08 in.).
The word "TO:" (upside down in the figure) at the lower right corner of the label
is used to identify the opposite end of the cable on which the label is affixed.
Power Cable Label
The label for power cables should be attached to the identification plate on the
cable ties that are attached to the cable. The identification plate has an embossed
area 0.2 mm x 0.6 mm (0.008 in. x 0.02 in.) around (symmetric on both sides), and
the area in the middle is for affixing the label, as shown in Figure 4-168.
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Figure 4-168 Power Cable Label
Label Printing
The contents can be printed or written on the labels. Printing is recommended for
the sake of high efficiency and eye-pleasant layout.
Template for Printing
You can obtain a template from the Huawei local office to print labels.
The template is made in Microsoft Word. Follow these instructions to use the
template:
● You can modify the contents of the template. Do not change settings of
centered characters, direction, and fonts.
● If many characters need to be filled in, decrease the font size, but make sure
that the printouts are clear and legible.
Merging Cells in the Template
To merge two or more cells, do as follows:
1. Select Edit/Select All.
2. Select Format/Borders and Shading/Borders. Select Box tab and click OK.
3. Drag the mouse to select cells to be merged and select the Table/Merge
Cells.
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Requirements on the Printer
To print labels, use a laser jet printer of any model. Before printing labels, set up
the page and try printing.
1. Try printing on ordinary paper with both sides blank. Place the blank paper
over the whole page of the label paper, and check whether the page setup
conforms to the label layout.
2. Make sure the printer properties, such as "paper size" and "direction", have
been set correctly.
– If the printout conforms to the sheet of labels, print the labels on the
label paper.
– If the printout does not conform, adjust the page setup and try printing
again until the correct printout is produced.
The method for adjusting the page setup is as follows.
1. Select File/Page Setup.
2. Select Layout and set Header and Footer as 0.
3. Select the Margins tab page. Select Left for Gutter Position and adjust the
values of Top, Bottom, Left, and Right.
NO TE
If the warning prompt as shown in Figure 4-169 appears before printing, click Ignore
to continue the printing.
Figure 4-169 Warning prompt before printing
After the page setup has been made correctly, save it for future use. This page
setup is only necessary the first time you use the template to print the labels.
Requirements for Feeding the Printer
The label paper consists of two layers and has undergone multiple processing
procedures such as printing and cutting. No matter what model of printer you use,
feed in the labels one page at a time. To avoid jamming the labels, never use the
auto-feed mode.
Feed in the label paper in the correct direction to ensure that the text is printed in
a correct position.
Requirements for the Printed Label
Make sure that the printed labels satisfy the following requirements:
● All the printouts must be on the label, and nothing should be printed on the
backing layer of the label page.
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● Contents in the cells should be aligned in the center. In a single-line printout,
the dividing lines and the word "TO:" should not be covered by printed
characters.
● When the cells are merged and the printouts are made in multiple lines, avoid
covering the word "TO:" when printing the text. Use the space bar to move
the text to the next line.
Writing Labels
Writing Tools
To make sure the printouts are clear and legible, use black markers instead of
ball-point pens to write the labels.
If no marker is available, black ball-point pens are allowed, although not
recommended. Compared with ball-point pens, waterproof markers are better.
When writing with a ball-point pen, do not leave the oil on the label, which may
contaminate the label and blur the words.
NO TE
The delivered marker has two nibs. Use the smaller nib to write the labels.
Font
For the sake of legibility, use standard block letters and numbers as shown in
Table 4-38.
Table 4-38 Standard typeface for handwriting
0 1 2 3 4 5 6 7 8
9 A B C D E F G H
I J K L M N O P Q
R S T U V W X Y Z
Determine the size of characters based on the number of letters or digits and
ensure that the characters are distinct and tidy.
Placement of text on a label is shown in Figure 4-170.
Figure 4-170 Placement of text on a label
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Attaching Labels
After printing or writing the label, remove the label from the page and attach it to
the signal cable, or the identification plate of the power cable. The methods for
attaching labels are described in the following sections.
Label for Signal Cables
● Choose the place to attach labels.
The label is attached 2 cm (0.79 in.) from the connector on a signal cable. In
special cases (for example, to avoid cable bending or affecting other cables),
other positions are allowed to attach the labels. The rectangular part with
text is attached facing right or downward, as shown in Figure 4-171. The
details are as follows:
– The identification card is to the right of the cable in vertical cabling.
– The identification card should be downward when you lay out the cable
horizontally.
Figure 4-171 Text area of the label
● Procedure for attaching labels
Figure 4-172 shows the methods and procedures for attaching labels.
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Figure 4-172 Label for signal cables
Power Cable Label
Remove the label from the backing page, and attach it to the identification plate
on the cable tie. The label should be attached to the rectangular flute on the
identification plate, and attached to only one side of the identification plate. In an
equipment room, all labels should be attached in the same way. The cable ties are
bundled at 2 cm (0.79 in.) from the connectors, and other positions are allowed in
special circumstances.
Cable ties should be bound on both ends of a cable. After the bundling, the
finished identification plate should be on top of the cable in horizontal cabling, or
on the right side of the cable in vertical cabling, as shown in Figure 4-173. The
details are as follows:
● The identification card is to the right of the cable in vertical cabling.
● The identification card is on the top of the cable in horizontal cabling. Make
sure that the label is facing out.
Figure 4-173 Binding the label for the power cable
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Contents of Engineering Labels
Contents of Labels for Power Cables
Labels for power cables are affixed on only one side of the identification plates.
On the labels, there is information (the part after the word "TO:") about the
location of the device on the other end of the cable, like the location of control
cabinet, distribution box or power socket.
Contents of Labels for Signal Cables
The two sides of the label affixed on the signal cable carry information about the
location of the ports connected to both ends of the cable. Figure 4-174 shows the
information on both sides of the labels affixed to the signal cables.
● Area 1 contains the location information of the local end of the cable.
● Area 2 (with the word "TO:") contains the location information of the
opposite end of the cable.
● Area 3 has been folded up inside the label.
Figure 4-174 Printed parts on the label for signal cables
Seen from the cabling end of the equipment, the text part of the label is on the
right side of the cable. The side with "TO:" that is facing outside carries the
location information of the opposite end; and the other side carries the location
information of the local end.
In other words, the information in Area 1 at one end is the same as the
information in Area 2 at the other end of the cable.
Precautions for Using Engineering Labels
When using labels, pay attention to the following points:
● When printing, writing, or attaching labels, keep the labels clean.
● Since the label paper is made of moistureproof material, ink-jet printers and
ink pens cannot be used to print and write labels.
● Labels should be attached neatly. New-type labels are L-shaped. If they are
pasted at incorrect locations or in the incorrect direction, the appearance of
the device is affected.
● Power cable ties should be attached in the same positions on power cables,
with identification plates on the same side.
● The positions of "up", "down", "left" or "right" are all based on the viewpoint
of the engineering person who is working on the label.
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4.1.14.4.2 Engineering Labels for Optical Fibers
These labels are affixed to the optical fibers that connect the optical interfaces on
the boards in a chassis, or on the device boxes. There are two types of labels for
optical cables:
● One is for the fiber that connects the optical interfaces on two devices.
● The other is for the fiber that connects the device and the ODF.
Labels for the Optical Fibers Connecting Devices
Meaning of the Label
Table 4-39 lists information on both sides of the labels affixed to the optical fibers
that connect two devices.
Table 4-39 Information on labels affixed to the fibers between two devices
Content Meaning Example
MN-B-C-D- MN: cabinet M: The cabinet rows from front to back are
R/T number numbered from A to Z.
N: The cabinet columns from left to right are
numbered from 01 to 99.
For example, A01 is the cabinet in row A and
column 01.
B: chassis Numbered in bottom-up order with two digits,
number for example, 01.
C: physical Numbered in top-down and left-right order
slot number starting from 01. For example, 01 is the first slot
at the top left of the chassis.
D: optical Numbered in top-down and left-right order,
interface consistent with the port sequence number on
number. the device.
R: Receiving -
interface
T: optical
transmitting
interface
Example of the Label
Figure 4-175 shows a sample label on an optical fiber.
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Figure 4-175 Sample label on an optical fiber between two devices
The meaning of the label is listed in Figure 4-175.
● "A01-01-05-01-R" indicates that the local end of the optical fiber is connected
to the optical receiving interface 01 in slot 5, chassis 01 in the cabinet in row
A, column 01 in the machine room.
● "G01-01-01-01-T" indicates that the opposite end of the optical fiber is
connected with optical transmitting interface 01 in slot 01, chassis 01 in the
cabinet in row G, column 01 in the machine room.
Labels for the Optical Fibers Connecting the Device and an ODF
Meaning of the Labels
Table 4-40 shows information on both sides of labels attached to an optical fiber
between a device and an optical distribution frame (ODF).
Table 4-40 Information on labels affixed to a fiber between a device and an ODF
Content Meaning Example
MN-B-C-D- MN: cabinet For example, A01.
R/T number
B: chassis Numbered in bottom-up order with two digits,
number for example, 01.
C: physical slot Numbered in top-down and left-right order
number starting from 01. For example, 01 is the first
slot at the top left of the chassis.
D: optical Numbered in top-down and left-right order,
interface consistent with the port sequence number on
number. the device.
R: Optical -
receiving
interface
T: optical
transmitting
interface
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Content Meaning Example
ODF-MN-B- MN: row M: The cabinet rows from front to back are
C-R/T number and numbered from A to Z.
column N: The cabinet columns from left to right are
number of an numbered from 01 to 99.
ODF
For example, G01 is the ODF of row G and
column 01.
B: row number Range from 01 to 99, for example, 01-01.
of the terminal
device
C: column
number of the
terminal
device
R: Optical -
receiving
interface
T: optical
transmitting
interface
Example of the Label
Figure 4-176 shows a sample label on an optical fiber.
Figure 4-176 Sample label on an optical fiber between the device and the ODF
Meaning of the label in Figure 4-176:
● "ODF-G01-01-01-R" indicates that the local end of the optical fiber is
connected to the optical receiving terminal in row 01, column 01 of the ODF
in row G, column 01 in the machine room.
● "A01-01-05-01-R" indicates that the opposite end of the optical fiber is
connected to optical receiving interface 1 in slot 05, chassis 01 in the cabinet
in row A, column 01 in the machine room.
4.1.14.4.3 Engineering Labels for Network Cables
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Applicable Ranges
The labels can be applied to Ethernet cables.
Label Content
Table 4-41 shows the information on both sides of the labels affixed to Ethernet
cables.
You can also decide the label content based on the actual environment. If the
device is not installed in the cabinet, for example, you can remove the cabinet
number.
Table 4-41 Information on the Ethernet cables
Content Meaning Example
MN-B-C-D MN: cabinet For example, A01 is the first cabinet in row A.
number
B: chassis Numbered in bottom-up order with two
number digits, for example, 01.
C: physical slot Numbered with two digits in top-down and
number left-right order. For example, 01.
D: network port Numbered in top-down and left-right orders.
number For example, 01.
MN-Z MN: cabinet For example, B02 is the second cabinet in
number row B.
Z: Location Fill in the location number of the terminal
number device on site. If the cable is connected to a
device in a cabinet, specify the serial
numbers of the cabinet, the chassis, and the
Ethernet interface of the device. For example,
B02-03-12. If the cable is connected to the
Network Management Station (NMS),
specify the specific location of the NMS.
The contents of the labels for network cables connecting hubs and devices or
agents and the network cables for other purposes should be specified according to
actual connections. The details are as follows:
● For a network cable connecting a hub and device, the label on the hub end
should indicate the numbers of the chassis and cabinet where the hub resides,
and the serial number on the hub. The label on the device end should indicate
the number of the chassis and cabinet where the device is located. If the
device is a standalone device, provide the specific position of the device.
● For a network cable connecting a hub and an agent or terminal, the label on
the agent or terminal end should contain the serial number of the network
interface. The definitions of the cabinet number and chassis number are the
same as those described in Table 1-28.
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● If the hub is a standalone device without a cabinet or chassis, the label should
contain specific location information that identifies the hub.
The serial number on the hub, the network interface number of the agent or
terminal, and the location of the standalone device should be specified according
to actual connections.
Label Example
Figure 4-177 shows a sample label on an Ethernet cable.
Figure 4-177 Sample label on an Ethernet cable
Meaning of the label in Figure 4-177:
● "A01-03-01-01" indicates that one end of the network cable is connected to
network interface 01 in slot 01, chassis 03 of the cabinet in row A, column 01
in the equipment room.
● "B02-03-01" indicates that another end of the network cable is connected to
network interface 01 in chassis 03 of the cabinet on row B, column 02 in the
equipment room. No slot number is given.
4.1.14.4.4 Engineering Labels for User Cables
Attach labels to both ends of a user cable to indicate the locations of the cable on
the device and main distribution frame (MDF).
Meaning of the Engineering Labels for User Cables
Table 4-42 shows the contents of the labels.
Table 4-42 Contents of the engineering labels for user cables
Content Meaning Example
MN-B-C-D MN: cabinet For example, A01 is the first cabinet in row A.
number
B: frame Numbered in the bottom-up order with two
number digits, for example, 03.
C: physical slot Numbered with two digits in top-down and
number left-right order. For example, 01.
D: cable Numbered with two digits in top-down and
number left-right order. For example, 01.
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Content Meaning Example
MDF-MN-B-C MN: row M: The rows of cabinets from front to back
number and are numbered from A to Z. N: The columns of
column number cabinets from left to right are numbered
of the MDF from 01 to 99. For example, G01 is the MDF
of Row G and Column 01.
B: row number Ranges from 01 to 99, for example, 01-01.
of the terminal
device
C: column
number of the
terminal device
Example of the Label
Figure 4-178 shows a sample label on a user cable.
Figure 4-178 Sample label on a user cable
The meaning of the label in Figure 4-178 is as follows:
● "A01-03-01-01" indicates that the local end of the user cable is connected to
port 1 in slot 1, chassis 03 of the cabinet in row A, column 01 in the
equipment room.
● "MDF-G01-01-01" indicates that the opposite end of the user cable is
connected to the terminal in row 01, column 01 of the MDF in row G, column
01 in the equipment room.
4.1.14.4.5 Engineering Labels for Power Cables
Engineering Labels for DC Power Cables
These labels are affixed to the DC power cables that provide power supply for
cabinets, including the -48 V, PGND, and BGND cables. Here, the DC power cables
also include power cables and PGND cables.
The labels for DC power cables are affixed to one side of the identification plates
on cable ties. For details of the labels, see Table 4-43.
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Table 4-43 Contents of the label
Content Meaning
MN(BC)- MN(BC): BC is written right under MN.
B--48Vn B: chassis number, numbered in bottom-up order with two
digits, for example, 01.
MN(BC)-B-
BGND n: power socket number, numbered as 1 to 3 in the bottom-
up and left-to-right orders.
MN(BC)-B- On the loaded cabinet side, only MN is used to identify the
PGND cabinet.
On the power cabinet side, MN identifies the row and column
number of the power distribution equipment like a control
cabinet and distribution box, and BC identifies the row and
column number of the -48 V connector. If there is no row
number or column number, or the connector can be identified
without them, BC can be omitted. It is unnecessary to identify
the row and column number for BGND and PGND.
The label only carries location information about the destination direction of the
power cable whereas information about the local end is unnecessary. That is, the
label only carries location information about the opposite equipment, the control
cabinet, or the distribution box. Table 1-30 lists the information on two -48 V
power supplies on the label. The information on other DC voltages, such as 24 V
and 60 V should be given in similar methods.
Make sure that labels are affixed in the correct direction. That is, after the cable
ties are bundled onto the cable, the identification plates with the labels should
face up, and the text on the labels in the same cabinet should be in the same
direction. For details, see Figure 4-179.
Figure 4-179 Example of the labels for DC power cables
The meaning of the label in Figure 4-179 is as follows:
● On the loaded cabinet side, the label "A01/B08--48V2" on the cable indicates
that the cable is -48 V DC supply, which is from the eighth connector in row B
of -48 V bus bar in the cabinet in row A, and column 1 in the equipment
room.
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● On the distribution box side, the label "B03--48V2" indicates that the cable is
-48 V DC supply, connected to DC power socket 2 in row B, column 03 in the
equipment room.
NO TE
In the power distribution box or the first power cabinet of a row in a transmission
equipment room, every terminal block on the -48 V connector bar has a numeric
identification. For example, in the above label of "A01/B08--48V2", "08" (or sometimes "8")
is the numeric identification of the terminal block.
PGND and BGND are two copper bars, on which the terminal blocks are short-
circuited. Therefore, it makes no difference which terminal is connected to them. It
is only necessary to give the row and column of the power distribution box,
instead of giving the specific serial number of the terminal block on the copper
bar. For example, if the label on the loaded cabinet side is "A01-BGND", it means
that the power cable is a BGND that connects BGND copper bar in the power
distribution box in row A, column 01 in the machine room. Information on the
labels for PGND cables should be given in a similar way.
Engineering Labels for AC Power Cables
These labels are affixed to both ends of an AC power cable that provides AC
power supply to cabinets, including 110/220 V, PGND, and BGND cables. The
110/220 V AC cables and related PGND and BGND cables are covered with an
insulating sheath, so the labels need to contain only the word "AC" and the
cabinet numbers.
The labels for AC power cables are affixed to one side of the identification plates
on cable ties. For details, see Table 4-44.
Table 4-44 Label content
Content Meaning
MN-(B)-ACn MN: serial number of the cabinet or the socket where the
power is led in
B: chassis number, numbered in bottom-up order with two
digits, for example, 01.
n: power port number, numbered as 1 to 3 in bottom-up and
left-to-right order.
Serial number of the socket where the power is led in: the
location of the socket is marked according to the actual
situation. If the sockets can be identified by row numbers and
column numbers, they can be numbered following the same
rule for the cabinets. If the sockets cannot be identified by
rows and columns, specify the detailed locations to avoid
confusion with other sockets.
The label only carries location information about the opposite equipment and the
power socket; information about the local end is unnecessary.
Make sure that labels are affixed in the correct direction. That is, after the cable
ties are bundled onto the cable, the identification plates with the labels should
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face up, and the text on the labels in the same cabinet should be in the same
direction, as shown in Figure 4-180.
Figure 4-180 Labels for AC power cables
Meaning of the label in Figure 4-180.
● On the equipment cabinet side, the label marked "A01-AC1" indicates that
the power cable is connected to the first AC power socket of row A and
column 01 in the equipment room.
● On the power socket side, the label marked "B01-AC1" indicates that the
power cable is connected to the first AC power socket in the cabinet of row B
and column 01 in the equipment room.
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V800R012C10 to V800R023C00
Hardware Guide
Issue 04
Date 2025-04-30
HUAWEI TECHNOLOGIES CO., LTD.
Copyright © Huawei Technologies Co., Ltd. 2025. All rights reserved.
No part of this document may be reproduced or transmitted in any form or by any means without prior
written consent of Huawei Technologies Co., Ltd.
Trademarks and Permissions
and other Huawei trademarks are trademarks of Huawei Technologies Co., Ltd.
All other trademarks and trade names mentioned in this document are the property of their respective
holders.
Notice
The purchased products, services and features are stipulated by the contract made between Huawei and
the customer. All or part of the products, services and features described in this document may not be
within the purchase scope or the usage scope. Unless otherwise specified in the contract, all statements,
information, and recommendations in this document are provided "AS IS" without warranties, guarantees
or representations of any kind, either express or implied.
The information in this document is subject to change without notice. Every effort has been made in the
preparation of this document to ensure accuracy of the contents, but all statements, information, and
recommendations in this document do not constitute a warranty of any kind, express or implied.
Huawei Technologies Co., Ltd.
Address: Huawei Industrial Base
Bantian, Longgang
Shenzhen 518129
People's Republic of China
Website: https://www.huawei.com
Email: support@huawei.com
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Hardware Guide Contents
Contents
1 Document Declaration........................................................................................................... 1
2 Using the Hardware Tool.......................................................................................................4
3 Hardware Description.............................................................................................................5
3.1 Chassis......................................................................................................................................................................................... 5
3.1.1 NetEngine 8000 F1A-8H20Q........................................................................................................................................... 5
3.2 Power........................................................................................................................................................................................ 53
3.2.1 NetEngine 8000 F1A-8H20Q Power Module........................................................................................................... 53
3.2.1.1 PAC1K2S12-DB (1200W AC Power Module(Back to Front, Power panel side exhaust))..................... 53
3.2.1.2 PAC1K2S12-DF (1200W AC Power Module(Front to Back,Power panel side intake)).......................... 55
3.2.1.3 PAC600S12-CB (600W AC Power Module(Back to Front, Power panel side exhaust))........................ 58
3.2.1.4 PAC600S12-CF (600W AC Power Module(Front to Back,Power panel side intake))............................. 60
3.2.1.5 PAC600S12-EB (600W AC Power Module(Back to Front, Power panel side exhaust)).........................63
3.2.1.6 PAC600S12-EF (600W AC Power Module(Front to Back,Power panel side intake))..............................65
3.2.1.7 PDC1000S12-CB (1000W DC Power Module(Back to Front,Power panel side exhaust)).................... 67
3.2.1.8 PDC1000S12-CF (1000W DC Power Module(Front to Back,Power panel side intake))........................70
3.3 Fan............................................................................................................................................................................................. 72
3.3.1 NetEngine 8000 F1A-8H20Q Fan Module................................................................................................................ 72
3.3.1.1 FAN-031A-B (Fan box(B,FAN panel side exhaust))........................................................................................... 72
3.3.1.2 FAN-031A-F (Fan Box(F,FAN panel side intake )).............................................................................................. 74
3.4 Optical Module...................................................................................................................................................................... 76
3.4.1 Understanding Pluggable Optical Modules............................................................................................................. 76
3.4.1.1 Appearance and Structure.......................................................................................................................................... 77
3.4.1.2 Types of Optical Modules............................................................................................................................................77
3.4.1.3 Instruction.........................................................................................................................................................................79
3.4.1.4 Instructions on How to Use an Optical Module..................................................................................................84
3.4.1.5 Configuring an Optical Attenuator.......................................................................................................................... 95
3.4.2 155Mbps eSFP Optical Module.................................................................................................................................... 96
3.4.2.1 155Mbps-eSFP-SMF-1550nm-80km-commercial............................................................................................... 96
3.4.2.2 155Mbps-eSFP-SMF-1310nm-15km-industry...................................................................................................... 98
3.4.2.3 155Mbps-eSFP-SMF-1310nm-40km-industry...................................................................................................... 99
3.4.2.4 155Mbps-eSFP-SMF-1550nm-80km-industry....................................................................................................100
3.4.2.5 155Mbps-eSFP-SMF-1310nm-40km-commercial.............................................................................................101
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3.4.2.6 155Mbps-eSFP-MMF-1310nm-2km-commercial............................................................................................. 103
3.4.2.7 155Mbps-eSFP-SMF-1310nm-15km-commercial.............................................................................................104
3.4.3 155Mbps eSFP BIDI Optical Module........................................................................................................................ 105
3.4.3.1 155Mbps-eSFP-SM-1310nm(Tx)/1550nm(Rx)-15km-commercial.............................................................105
3.4.3.2 155Mbps-eSFP-SM-1550nm(Tx)/1310nm(Rx)-15km-commercial.............................................................107
3.4.4 1Gbps Electrical Module............................................................................................................................................... 108
3.4.4.1 1Gbps-SFP-100m-industry (02310RAV).............................................................................................................. 108
3.4.4.2 1Gbps-SFP-100m-industry (02310VPT)............................................................................................................... 109
3.4.4.3 1Gbps-SFP-100m-industry (02314FNP)...............................................................................................................109
3.4.5 1.25Gbps eSFP Optical Module.................................................................................................................................. 110
3.4.5.1 1.25Gbps-eSFP-MMF-850nm-500m-extended.................................................................................................. 110
3.4.5.2 1.25Gbps-eSFP-SMF-1310nm-10km-industry....................................................................................................111
3.4.5.3 1.25Gbps-eSFP-SMF-1310nm-40km-industry....................................................................................................113
3.4.5.4 1.25Gbps-eSFP-MMF-850nm-500m-industry.................................................................................................... 114
3.4.5.5 1.25Gbps-eSFP-SMF-1550nm-80km-commercial.............................................................................................115
3.4.5.6 1.25Gbps-eSFP-SMF-1310nm-10km-commercial.............................................................................................116
3.4.5.7 1.25Gbps-eSFP-SMF-1310nm-40km-commercial.............................................................................................118
3.4.5.8 1.25Gbps-eSFP-SMF-1550nm-100km-commercial.......................................................................................... 119
3.4.6 1.25Gbps eSFP BIDI Optical Module........................................................................................................................ 120
3.4.6.1 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-10km-commercial(34060470)....................................120
3.4.6.2 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-10km-commercial...........................................................122
3.4.6.3 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-40km-commercial...........................................................123
3.4.6.4 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-40km-commercial...........................................................124
3.4.6.5 1.25Gbps-eSFP-SMF-1570nm(Tx)/1490nm(Rx)-80km-commercial...........................................................126
3.4.6.6 1.25Gbps-eSFP-SMF-1490nm(Tx)/1570nm(Rx)-80km-commercial...........................................................127
3.4.6.7 0.1~1.25Gbps-eSFP-SMF-1310nm(Tx)/1550nm(Rx)-40km-commercial.................................................. 128
3.4.6.8 0.1~1.25Gbps-eSFP-SMF-1550nm(Tx)/1310nm(Rx)-40km-commercial.................................................. 130
3.4.6.9 1.25Gbps-eSFP-SMF-1550nm(Tx)/1490nm(Rx)-80km-commercial...........................................................131
3.4.6.10 1.25Gbps-eSFP-SMF-1490nm(Tx)/1550nm(Rx)-80km-commercial........................................................ 133
3.4.7 1.25Gbps eSFP CWDM Optical Module.................................................................................................................. 134
3.4.7.1 1.25Gbps-eSFP-SMF-1571nm-80km-commercial.............................................................................................134
3.4.7.2 1.25Gbps-eSFP-SMF-1591nm-80km-commercial.............................................................................................135
3.4.7.3 1.25Gbps-eSFP-SMF-1551nm-80km-commercial.............................................................................................137
3.4.7.4 1.25Gbps-eSFP-SMF-1511nm-80km-commercial.............................................................................................138
3.4.7.5 1.25Gbps-eSFP-SMF-1611nm-80km-commercial.............................................................................................139
3.4.7.6 1.25Gbps-eSFP-SMF-1491nm-80km-commercial.............................................................................................140
3.4.7.7 1.25Gbps-eSFP-SMF-1531nm-80km-commercial.............................................................................................142
3.4.7.8 1.25Gbps-eSFP-SMF-1471nm-80km-commercial.............................................................................................143
3.4.8 125M~2.67Gbps eSFP DWDM Optical Module.................................................................................................... 144
3.4.8.1 125M~2.67Gbps-eSFP-SMF-1560.61nm-120km-commercial...................................................................... 144
3.4.8.2 125M~2.67Gbps-eSFP-SMF-1559.79nm-120km-commercial...................................................................... 145
3.4.8.3 125M~2.67Gbps-eSFP-SMF-1558.98nm-120km-commercial...................................................................... 147
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3.4.8.4 125M~2.67Gbps-eSFP-SMF-1558.17nm-120km-commercial...................................................................... 148
3.4.8.5 125M~2.67Gbps-eSFP-SMF-1557.36nm-120km-commercial...................................................................... 149
3.4.8.6 125M~2.67Gbps-eSFP-SMF-1556.55nm-120km-commercial...................................................................... 151
3.4.8.7 125M~2.67Gbps-eSFP-SMF-1555.75nm-120km-commercial...................................................................... 152
3.4.8.8 125M~2.67Gbps-eSFP-SMF-1554.94nm-120km-commercial...................................................................... 153
3.4.8.9 125M~2.67Gbps-eSFP-SMF-1554.13nm-120km-commercial...................................................................... 154
3.4.8.10 125M~2.67Gbps-eSFP-SMF-1553.33nm-120km-commercial.................................................................... 156
3.4.8.11 125M~2.67Gbps-eSFP-SMF-1552.52nm-120km-commercial.................................................................... 157
3.4.8.12 125M~2.67Gbps-eSFP-SMF-1551.72nm-120km-commercial.................................................................... 158
3.4.8.13 125M~2.67Gbps-eSFP-SMF-1550.92nm-120km-commercial.................................................................... 159
3.4.8.14 125M~2.67Gbps-eSFP-SMF-1550.12nm-120km-commercial.................................................................... 161
3.4.8.15 125M~2.67Gbps-eSFP-SMF-1549.32nm-120km-commercial.................................................................... 162
3.4.8.16 125M~2.67Gbps-eSFP-SMF-1548.51nm-120km-commercial.................................................................... 163
3.4.8.17 125M~2.67Gbps-eSFP-SMF-1547.72nm-120km-commercial.................................................................... 164
3.4.8.18 125M~2.67Gbps-eSFP-SMF-1546.92nm-120km-commercial.................................................................... 166
3.4.8.19 125M~2.67Gbps-eSFP-SMF-1546.12nm-120km-commercial.................................................................... 167
3.4.8.20 125M~2.67Gbps-eSFP-SMF-1545.32nm-120km-commercial.................................................................... 168
3.4.8.21 125M~2.67Gbps-eSFP-SMF-1544.53nm-120km-commercial.................................................................... 169
3.4.8.22 125M~2.67Gbps-eSFP-SMF-1543.73nm-120km-commercial.................................................................... 171
3.4.8.23 125M~2.67Gbps-eSFP-SMF-1542.94nm-120km-commercial.................................................................... 172
3.4.8.24 125M~2.67Gbps-eSFP-SMF-1542.14nm-120km-commercial.................................................................... 173
3.4.8.25 125M~2.67Gbps-eSFP-SMF-1541.35nm-120km-commercial.................................................................... 174
3.4.8.26 125M~2.67Gbps-eSFP-SMF-1540.56nm-120km-commercial.................................................................... 176
3.4.8.27 125M~2.67Gbps-eSFP-SMF-1539.77nm-120km-commercial.................................................................... 177
3.4.8.28 125M~2.67Gbps-eSFP-SMF-1538.98nm-120km-commercial.................................................................... 178
3.4.8.29 125M~2.67Gbps-eSFP-SMF-1538.19nm-120km-commercial.................................................................... 179
3.4.8.30 125M~2.67Gbps-eSFP-SMF-1537.40nm-120km-commercial.................................................................... 181
3.4.8.31 125M~2.67Gbps-eSFP-SMF-1536.61nm-120km-commercial.................................................................... 182
3.4.8.32 125M~2.67Gbps-eSFP-SMF-1535.82nm-120km-commercial.................................................................... 183
3.4.8.33 125M~2.67Gbps-eSFP-SMF-1535.04nm-120km-commercial.................................................................... 184
3.4.8.34 125M~2.67Gbps-eSFP-SMF-1534.25nm-120km-commercial.................................................................... 186
3.4.8.35 125M~2.67Gbps-eSFP-SMF-1533.47nm-120km-commercial.................................................................... 187
3.4.8.36 125M~2.67Gbps-eSFP-SMF-1532.68nm-120km-commercial.................................................................... 188
3.4.8.37 125M~2.67Gbps-eSFP-SMF-1531.90nm-120km-commercial.................................................................... 189
3.4.8.38 125M~2.67Gbps-eSFP-SMF-1531.12nm-120km-commercial.................................................................... 191
3.4.8.39 125M~2.67Gbps-eSFP-SMF-1530.33nm-120km-commercial.................................................................... 192
3.4.8.40 125M~2.67Gbps-eSFP-SMF-1529.55nm-120km-commercial.................................................................... 193
3.4.9 10Gbps SFP+ Optical Module..................................................................................................................................... 194
3.4.9.1 10Gbps-SFP+-SMF-1550nm-80km-commercial................................................................................................194
3.4.9.2 10Gbps-SFP+-SMF-1310nm-10km-industry.......................................................................................................196
3.4.9.3 10Gbps-SFP+-SMF-1550nm-40km-industry.......................................................................................................197
3.4.9.4 10Gbps-SFP+-MMF-850nm-0.3km-commercial............................................................................................... 198
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3.4.9.5 10Gbps-SFP+-SMF-1310nm-10km-commercial................................................................................................200
3.4.9.6 10Gbps-SFP+-SMF-1550nm-40km-commercial................................................................................................201
3.4.10 1.25/9.953/10.3125Gbps SFP+ Optical Module..................................................................................................202
3.4.10.1 1.25/9.953/10.3125Gbps-SFP+-SMF-1310nm-10km-commercial............................................................ 203
3.4.10.2 1.25/9.953/10.3125Gbps-SFP+-SMF-1550nm-40km-commercial............................................................ 204
3.4.11 10Gbps SFP+ CWDM Optical Module................................................................................................................... 205
3.4.11.1 10Gbps-SFP+-SMF-1511nm-70km-commercial............................................................................................. 206
3.4.11.2 10Gbps-SFP+-SMF-1471nm-70km-commercial............................................................................................. 207
3.4.11.3 10Gbps-SFP+-SMF-1491nm-70km-commercial............................................................................................. 208
3.4.11.4 10Gbps-SFP+-SMF-1531nm-70km-commercial............................................................................................. 209
3.4.11.5 10Gbps-SFP+-SMF-1551nm-70km-commercial............................................................................................. 211
3.4.11.6 10Gbps-SFP+-SMF-1571nm-70km-commercial............................................................................................. 212
3.4.11.7 10Gbps-SFP+-SMF-1591nm-70km-commercial............................................................................................. 213
3.4.11.8 10Gbps-SFP+-SMF-1611nm-70km-commercial............................................................................................. 215
3.4.12 10Gbps SFP+ BIDI Optical Module......................................................................................................................... 216
3.4.12.1 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-40km-commercial........................................................... 216
3.4.12.2 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-40km-commercial........................................................... 217
3.4.12.3 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-10km-industry.................................................................. 219
3.4.12.4 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-10km-industry.................................................................. 220
3.4.13 10Gbps SFP+ OTN Optical Module........................................................................................................................ 221
3.4.13.1 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial...........................................................................221
3.4.14 10Gbps SFP+ DWDM Optical Module...................................................................................................................223
3.4.14.1 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial...........................................................................223
3.4.15 25Gbps SFP28 Optical Module................................................................................................................................ 224
3.4.15.1 25Gbps-SFP28-MMF-850nm-0.1km-commercial (02312PDK)................................................................. 225
3.4.15.2 25Gbps-SFP28-SMF-1310nm-10km-industry (02312PDL)......................................................................... 226
3.4.15.3 25Gbps-SFP28-MMF-850nm-0.1km-commercial (34061254).................................................................. 227
3.4.15.4 25Gbps-SFP28-SMF-1310nm-10km-industry (34061618)..........................................................................228
3.4.15.5 25Gbps-SFP28-MMF-850nm-0.1km-extended............................................................................................... 230
3.4.16 25Gbps SFP28 BIDI Optical Module.......................................................................................................................231
3.4.16.1 25Gbps-SFP28-SMF-1270nm(Tx)/1330nm(Rx)-10km-commercial.........................................................231
3.4.16.2 25Gbps-SFP28-SMF-1330nm(Tx)/1270nm(Rx)-10km-commercial.........................................................233
3.4.17 40Gbps QSFP+ Optical Module............................................................................................................................... 234
3.4.17.1 40Gbps(4*10.3)-QSFP+-SMF-1271~1331nm-10km-commercial..............................................................234
3.4.17.2 40Gbps(4*10.3)-QSFP+-MMF-850nm-0.1km-commercial..........................................................................236
3.4.17.3 40Gbps(4*10.3)-QSFP+-SMF-1310nm-10km-commercial.......................................................................... 237
3.4.17.4 QSFP-40G-LX4-MM.................................................................................................................................................. 238
3.4.18 50Gbps QSFP28 Optical Module............................................................................................................................. 239
3.4.18.1 50Gbps-QSFP28-SMF-1311nm-10km-commercial....................................................................................... 239
3.4.18.2 50Gbps-QSFP28-SMF-1311nm-40km-commercial....................................................................................... 241
3.4.18.3 50Gbps-QSFP28-SMF-1295.56~1300.05nm-80km-commercial............................................................... 242
3.4.19 50Gbps QSFP28 BIDI Optical Module................................................................................................................... 244
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3.4.19.1 50Gbps-QSFP28-SMF-1331nm(Tx)/1271nm(Rx)-10km-commercial..................................................... 244
3.4.19.2 50Gbps-QSFP28-SMF-1271nm(Tx)/1331nm(Rx)-10km-commercial..................................................... 246
3.4.19.3 50Gbps-QSFP28-SMF-1295nm(Tx)/1309nm(Rx)-40km-commercial..................................................... 247
3.4.19.4 50Gbps-QSFP28-SMF-1309nm(Tx)/1295nm(Rx)-40km-commercial..................................................... 249
3.4.20 100Gbps QSFP28 Optical Module.......................................................................................................................... 251
3.4.20.1 100Gbps(4*25.7)-QSFP28-MMF-850nm-0.1km-commercial.....................................................................251
3.4.20.2 100Gbps(4*25.7)-QSFP28-SMF-1271~1331nm-2km-commercial........................................................... 253
3.4.20.3 100Gbps(4*25.7)-QSFP28-SMF-1310nm-30km(NO FEC)-40km(FEC)-commercial...........................254
3.4.20.4 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-commercial (02312BSS).....................256
3.4.20.5 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-80km-commercial............................................. 258
3.4.20.6 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-40km-commercial............................................. 259
3.4.20.7 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-commercial (02313SWA)...................261
3.4.20.8 100Gbps-QSFP28-1310nm-10km-commercial............................................................................................... 263
3.5 Cables..................................................................................................................................................................................... 264
3.5.1 NetEngine 8000 F1A-8H20Q Power Cable.............................................................................................................264
3.5.1.1 DC Power Cable........................................................................................................................................................... 264
3.5.1.2 AC Power Cable.......................................................................................................................................................... 269
3.5.2 Chassis Ground Cable.................................................................................................................................................... 273
3.5.3 Standard Serial Cable.................................................................................................................................................... 274
3.5.4 USB-to-Serial Cable........................................................................................................................................................ 276
3.5.5 Clock Cable (External Clock Mode, Delivery-Ready).......................................................................................... 277
3.5.6 Clock Cable (External Clock/External Time Mode, Prepared Onsite)........................................................... 279
3.5.7 Clock Bridging Cable...................................................................................................................................................... 281
3.5.8 Ethernet Cable..................................................................................................................................................................283
3.5.9 Fiber Jumpers................................................................................................................................................................... 286
3.6 Fiber Breakout..................................................................................................................................................................... 292
3.6.1 Breakout Fibers................................................................................................................................................................ 292
3.6.2 Breakout Boxes................................................................................................................................................................ 298
3.6.2.1 Product Overview........................................................................................................................................................ 298
3.6.2.2 10-Port-MPO-12-40-Port-LC-Breakout Box(single-mode)............................................................................299
4 Hardware Installation and Parts Replacement............................................................303
4.1 Hardware Installation and Maintenance Guide of NetEngine 8000 F1A-8H20Q........................................303
4.1.1 Hardware Installation and Usage Precautions..................................................................................................... 303
4.1.2 Introduction to the A66E Cabinet..............................................................................................................................305
4.1.3 Cabinet Accessories........................................................................................................................................................ 309
4.1.3.1 (Optional) Cabinet Stand......................................................................................................................................... 309
4.1.4 A66E Cabinet Installation.............................................................................................................................................311
4.1.4.1 Installing the Cabinet on the Concrete Floor.....................................................................................................311
4.1.4.1.1 Removing the Ground Cables and Cabinet Doors........................................................................................ 311
4.1.4.1.2 Determining the Installation Position of the Cabinets................................................................................311
4.1.4.1.3 Installing Expansion Bolts..................................................................................................................................... 313
4.1.4.1.4 Installing the Cabinet..............................................................................................................................................314
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4.1.4.1.5 Leveling the cabinet and testing the insulation............................................................................................ 315
4.1.4.1.6 Attaching the cabinets........................................................................................................................................... 316
4.1.4.1.7 Installing cabinet doors..........................................................................................................................................317
4.1.4.2 Installing the Cabinet on the ESD Floor.............................................................................................................. 318
4.1.4.2.1 Removing the Ground Cables and Cabinet Doors........................................................................................ 318
4.1.4.2.2 Determining the Installation Position of the Supports............................................................................... 319
4.1.4.2.3 Installing Expansion Bolts..................................................................................................................................... 320
4.1.4.2.4 Installing Supports................................................................................................................................................... 321
4.1.4.2.5 Installing the Cabinet..............................................................................................................................................324
4.1.4.2.6 Testing the Insulation and Installing the Front Pallet................................................................................. 326
4.1.4.2.7 Attaching the Cabinets and Restoring the ESD Floor..................................................................................328
4.1.4.2.8 Installing Cabinet Doors........................................................................................................................................ 329
4.1.5 Device Installation Process.......................................................................................................................................... 330
4.1.6 Preparation before installation...................................................................................................................................332
4.1.6.1 Reading Carefully the Safety Precautions........................................................................................................... 332
4.1.6.2 Checking the Installation Site..................................................................................................................................334
4.1.6.3 Checking the Cabinet................................................................................................................................................. 335
4.1.6.4 Preparing Installation Tools and Accessories..................................................................................................... 337
4.1.6.5 Inspecting and Cleaning Optical Fiber Connectors and Adapters.............................................................. 342
4.1.6.5.1 Overview..................................................................................................................................................................... 342
4.1.6.5.2 Protection of Optical Fiber Connectors............................................................................................................ 343
4.1.6.5.3 Tools, Equipment, and Materials........................................................................................................................ 344
4.1.6.5.4 Inspecting Optical Fiber Connectors..................................................................................................................345
4.1.6.5.5 Inspecting the Optical Fiber Link........................................................................................................................348
4.1.6.5.6 Cleaning Optical Fiber Connectors Using the Cassette Cleaner.............................................................. 350
4.1.6.5.7 Cleaning Optical Fiber Connectors Using Lens Tissue................................................................................ 351
4.1.6.5.8 Cleaning Optical Fiber Adapters Using Dustfree Absorbent Swabs....................................................... 354
4.1.6.6 Inspection of power distribution environment.................................................................................................. 356
4.1.6.6.1 Introduction to the Power Distribution System.............................................................................................356
4.1.6.6.2 DC Power Distribution Guide............................................................................................................................... 357
4.1.6.6.3 AC Power Distribution Guide............................................................................................................................... 358
4.1.6.7 Unpacking a Device.................................................................................................................................................... 361
4.1.6.7.1 Unpacking a Carton................................................................................................................................................ 361
4.1.7 Installing a Chassis in Cabinet.................................................................................................................................... 362
4.1.8 Cable Routing Planning................................................................................................................................................ 369
4.1.8.1 DC Power Cable Routing Planning........................................................................................................................ 369
4.1.8.2 AC Power Cable Routing Planning........................................................................................................................ 370
4.1.9 Installation of cables......................................................................................................................................................371
4.1.9.1 Installing Optical Fibers.............................................................................................................................................372
4.1.9.2 Installing Network Cables.........................................................................................................................................374
4.1.9.3 Installing a Cabinet Ground Cable.........................................................................................................................375
4.1.10 Post-Installation Check............................................................................................................................................... 377
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide Contents
4.1.11 Power-on Check............................................................................................................................................................ 380
4.1.12 (Optional) Checking Optical Power....................................................................................................................... 382
4.1.13 Maintenance of the device........................................................................................................................................ 384
4.1.13.1 Basic Operation Process and Precautions......................................................................................................... 384
4.1.13.2 Replacing a power module.................................................................................................................................... 386
4.1.13.2.1 Replacing the DC Power Module..................................................................................................................... 386
4.1.13.2.2 Replacing the AC Power Module......................................................................................................................388
4.1.13.3 Replacing the Fan Module..................................................................................................................................... 389
4.1.13.4 Replacing an Optical Module............................................................................................................................... 391
4.1.13.5 Replacing an Optical Cable................................................................................................................................... 396
4.1.13.6 Replacing a Network Cable................................................................................................................................... 398
4.1.14 Appendix.......................................................................................................................................................................... 399
4.1.14.1 On-site Cable Assembly and Installation.......................................................................................................... 399
4.1.14.1.1 Cable Assembly Precautions.............................................................................................................................. 399
4.1.14.1.2 Assembling Power Cables................................................................................................................................... 401
4.1.14.1.3 Assembling Ethernet Cables.............................................................................................................................. 413
4.1.14.1.4 Installing Cable Accessories............................................................................................................................... 427
4.1.14.1.5 Installing Ethernet Adapters.............................................................................................................................. 431
4.1.14.1.6 Installing Fiber Connectors.................................................................................................................................434
4.1.14.1.7 Replacing the Mold of the Crimping Tool..................................................................................................... 441
4.1.14.2 Environmental Requirements for Device Operation..................................................................................... 444
4.1.14.2.1 Environmental Requirements for Equipment Room..................................................................................444
4.1.14.2.2 Requirements for Power Supply....................................................................................................................... 452
4.1.14.3 Equipment Grounding Specifications................................................................................................................. 455
4.1.14.3.1 General Grounding Specifications....................................................................................................................455
4.1.14.3.2 Grounding Specifications for Equipment Room.......................................................................................... 455
4.1.14.3.3 Grounding Specifications for Devices............................................................................................................. 455
4.1.14.3.4 Grounding Specifications for Communications Power Supply............................................................... 456
4.1.14.3.5 Grounding Specifications for Signal Cables.................................................................................................. 457
4.1.14.3.6 Specifications for Laying Out Grounding Cables........................................................................................ 457
4.1.14.4 Engineering Labels for Cables...............................................................................................................................458
4.1.14.4.1 Introduction to Labels.......................................................................................................................................... 458
4.1.14.4.2 Engineering Labels for Optical Fibers.............................................................................................................466
4.1.14.4.3 Engineering Labels for Network Cables.........................................................................................................468
4.1.14.4.4 Engineering Labels for User Cables................................................................................................................. 470
4.1.14.4.5 Engineering Labels for Power Cables..............................................................................................................471
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. viii
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 1 Document Declaration
1 Document Declaration
Purpose
This document describes hardware features of the NetEngine 8000 F1A. It helps
intended readers obtain detailed information about each chassis, board, and cable,
and learn how to install and maintain devices.
NO TICE
The Hardware Guide includes hardware data of multiple versions. Before using this
document, check the first version supported by the hardware.
Related Version
NO TICE
The following table lists the product versions involved in this document. Before
reading this document, confirm whether your versions are included in this
document.
Product Name Version
HUAWEI NetEngine 8000 F1A Applicable to:
● V800R012C10SPC300
● V800R013C00SPC100
● V800R021C00SPC100
● V800R021C10SPC600
● V800R022C00SPC600
● V800R022C10SPC500
● V800R023C00SPC500
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 1
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 1 Document Declaration
Intended Audience
This document is intended for:
● Network planning engineers
● Hardware installation engineers
● Commissioning engineers
● On-site maintenance engineers
● System maintenance engineers
Special Declaration
● The pictures of hardware in this document are for reference only.
● The supported boards are described in the document. Whether a
customization requirement can be met is subject to the information provided
at the pre-sales interface.
● All device dimensions described in this document are designed dimensions
and do not include dimension tolerances. In the process of component
manufacturing, the actual size is deviated due to factors such as processing or
measurement.
Symbol Conventions
The symbols that may be found in this document are defined as follows.
Symbol Description
Indicates a hazard with a high level of risk which, if
not avoided, will result in death or serious injury.
Indicates a hazard with a medium level of risk
which, if not avoided, could result in death or
serious injury.
Indicates a hazard with a low level of risk which, if
not avoided, could result in minor or moderate
injury.
Indicates a potentially hazardous situation which, if
not avoided, could result in equipment damage,
data loss, performance deterioration, or
unanticipated results.
NOTICE is used to address practices not related to
personal injury.
Supplements the important information in the main
text.
NOTE is used to address information not related to
personal injury, equipment damage, and
environment deterioration.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 2
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 1 Document Declaration
Change History
● Changes in Issue 04 (2025-04-30)
This is the fourth official release.
● Changes in Issue 03 (2024-12-31)
This is the third official release.
● Changes in Issue 02 (2024-08-30)
This is the second official release.
● Changes in Issue 01 (2024-06-30)
This is the first official release.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 3
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 2 Using the Hardware Tool
2 Using the Hardware Tool
Enterprise:
In the enterprise network market, Info-Finder is a tool platform, It allows you to
search for key product information by product series and model. The key product
information includes basic information such as the software specifications, life
cycles, and hardware information, and operation and maintenance information
such as the licenses, alarms, logs, commands, and MIBs. The hardware-related
tools are as follows:
● Product image gallery: provides product photos, and network element icons
for you to produce design drawings and networking diagrams.
● Hardware configuration: automatically generates hardware configuration
diagrams after you select components are required and calculates the weight,
power consumption, and heat consumption.
● Hardware center: provides the technical specifications of devices and
components, as well as the mapping between devices, components, and
versions.
● 3D model: Using this function, you can query product images, product
overview, and component insertion/removal videos, enabling you to quickly
obtain product information in one-stop mode.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 4
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
3 Hardware Description
3.1 Chassis
3.2 Power
3.3 Fan
3.4 Optical Module
3.5 Cables
3.6 Fiber Breakout
3.1 Chassis
3.1.1 NetEngine 8000 F1A-8H20Q
Overview
Table 3-1 Basic information about the NetEngine 8000 F1A-8H20Q
Description Part Number Model First Integrated
supported fixed device
version
NetEngine 02353AES CR8B0BKP03C V800R012C00 Y
8000 0 SPC300
F1A-8H20Q
Integrated
Chassis
Components
(Port-side
Intake)
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Description Part Number Model First Integrated
supported fixed device
version
NetEngine 02353AES-00 CR8B0BKP03C V800R021C10 Y
8000 1 0 SPC600
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Intake)
NetEngine 02353AES-00 CR8B0BKP03C V800R022C10 Y
8000 6 0 SPC500
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Intake)
NetEngine 02353AGV CR8B0BKP03C V800R012C00 Y
8000 2 SPC300
F1A-8H20Q
Integrated
Chassis
Components
(Port-side
Exhaust)
NetEngine 02353AGV-00 CR8B0BKP03C V800R021C10 Y
8000 1 2 SPC600
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Exhaust)
NetEngine 02353AGV-00 CR8B0BKP03C V800R022C10 Y
8000 2 2 SPC500
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Exhaust)
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 6
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Description Part Number Model First Integrated
supported fixed device
version
NetEngine 02355KVX CR8B0BKP03 V800R022C10 Y
8000 D0 SPC500
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Intake)
NetEngine 02355KVY CR8B0BKP03 V800R022C10 Y
8000 D2 SPC500
F1A-8H20Q
Integrated
Chassis
Components(
Port-side
Exhaust)
NO TE
In specific areas, as the auxiliary materials are different, the sales BOM numbers may be
different. Different sales BOM numbers may correspond to the same description in the
device attribute table. The actual sales BOM number in an area prevails.
Appearance
Figure 3-1 Appearance of the NetEngine 8000 F1A-8H20Q (port side)
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 7
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Figure 3-2 Appearance of the NetEngine 8000 F1A-8H20Q (power side)
NO TE
Figures in the document are for reference only, and the actual appearance of the devices
may vary depending on the exact device model.
A chassis that adopts port-side air intake can house only power modules and fan modules
with the same air intake mode.
Similarly, a chassis that adopts port-side air exhaust can house only power modules and fan
modules with the same air exhaust mode.
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 8
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
desired information and filter the mapping data for more fine-grained data
display.
Slot Layout
Figure 3-3 Slot Layout of the NetEngine 8000 F1A-8H20Q
Table 3-2 Slots on the NetEngine 8000 F1A-8H20Q
Slot Type Slot ID Slot Direction Remarks
IPU 1 - Fixed ports
POWER 2 - Power supply
POWER 3 - Power supply
FAN 4 - Fan
FAN 5 - Fan
FAN 6 - Fan
FAN 7 - Fan
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Panel
Figure 3-4 Panel on the NetEngine 8000 F1A-8H20Q
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
1. Status indicator(STAT) 2. Port status 3. Breakout channel
indicator(0~55) indicator(BREAKOUT(0~
3))
4. Port status 5. Management port 6. Reset button(RST)
indicator(GE0,GE1) status indicator(L/A)
Table 3-3 Indicators on the NetEngine 8000 F1A-8H20Q
Silkscreen Name Color Status Description
STAT Status Green Steady on The device is
indicator working
properly.
Green Blinking The device is
starting up.
Red Steady on An alarm is
generated.
Orange Blinking Status in
which the
passwords
and
configurations
on the card
are being
cleared
NOTE
This indicator
status is
supported
since
V800R013C00.
- Off The system is
not powered
on or
registered.
L/A (MGMT- Management Green Steady on The link is up.
ETH) port status
indicator Green Blinking Data is being
transmitted or
received.
- Off The link is
down.
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Silkscreen Name Color Status Description
BREAKOUT Breakout Green Blink Each
(0–3) channel BREAKOUT
indicator indicator for
channels 0 to
3 is on for 5s
in sequence
to indicate
the status of
the
corresponding
channel, and
this process
repeats.
- Off No data is
transmitting
or receiving in
this channel.
GE0, GE1 Port status Green Steady on The link is up.
indicator
Green Blinking Data is being
transmitted or
received.
- Off The link is
down.
0 to 55 Green Steady on The link is up.
Green Blinking Data is being
transmitted or
received.
0~55 - Off The link is
down.
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Table 3-4 Buttons on the NetEngine 8000 F1A-8H20Q
Silkscreen Name Description
RST Reset button You can press the RST
button to reset the NE or
restore the factory
settings of the NE.
The procedure is as
follows:
To reset the NE, press
the RST button and
release it.
From V8R13C00, to
restore factory settings,
press and hold the RST
button. This operation
will clear the NE
database and system
parameter configurations
and cannot be restored.
Exercise caution when
you perform the
following operations:
1. Press and release the
RST button to restart the
NE.
2.When the STAT
indicator blinks as green
(the blinking frequency
is about 250 ms and the
time window is about 15
seconds), press and hold
the RST button.
3.Wait for no longer
than 2 minutes till the
STAT indicators blink as
orange(the time window
is 5 seconds). Then
release the RST button
immediately.
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Silkscreen Name Description
NOTE
In V800R013C00 and later
versions, the RST button
can be used to clear
configurations. If the
software version is lower
than V800R013C00, pay
attention to upgrade the
CPU EPLD version from
V800R013C00 manually
before using this function.
For the detailed operation
description, see the
corresponding chapter in
the upgrade guide
document.
1. When you press the RST
button to clear the
configuration file, the
original configuration file
will be cleared. You are
advised to periodically
back up the configuration
file.
2. When pressing the RST
button to clear the
configuration file, you only
need to pay attention to
the STAT indicators. Other
indicators may vary
depending on the product
model.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 14
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Table 3-5 Ports on the NetEngine 8000 F1A-8H20Q
Port Connector Type Description Available
Components
0~27 SFP+ Inputs and 10Gbps SFP+
outputs 10GE/GE Optical Module
optical signals. 10Gbps SFP+
1. Interfaces 0 to DWDM Optical
27 support 10GE Module
WAN, and other 10Gbps SFP+
interfaces do not CWDM Optical
support 10GE Module
WAN.
10Gbps SFP+
2. Ports 0-3, 4-7, BIDI Optical
8-11, 12-15, Module
16-19, 20-23 and
24-27 form a port 1Gbps Electrical
group, Module
respectively. The 1.25Gbps eSFP
four ports in each BIDI Optical
port group must Module
work in 10GE 1.25Gbps eSFP
WAN or 10GE CWDM Optical
LAN mode at the Module
same time. 10GE
WAN and 10GE 1.25Gbps eSFP
LAN cannot Optical Module
coexist. 125M~2.67Gbps
3. 10GE WAN eSFP DWDM
interfaces support Optical Module
only the master 155Mbps eSFP
clock. BIDI Optical
4. The following Module
models support 155Mbps eSFP
the AE 905M Optical Module
module:
CR8B0BKP03D0
and
CR8B0BKP03D2.
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Port Connector Type Description Available
Components
28~35 SFP28 Port for inputting 25Gbps SFP28
and outputting Optical Module
25GE/10GE/GE 25Gbps SFP28
optical signals BIDI Optical
NOTE Module
Ports 28–31 belong
to a port group, 10Gbps SFP+
and ports 32–35 Optical Module
belong to another 10Gbps SFP+
one. These ports
DWDM Optical
work in 25GE/
10GE auto-sensing Module
mode by default. 10Gbps SFP+
You can run the CWDM Optical
port-mode group-
id command in the Module
slot view to switch 10Gbps SFP+
the working mode BIDI Optical
to 10GE/GE auto- Module
sensing for ports in
a port group. 1Gbps Electrical
Module
1.25Gbps eSFP
BIDI Optical
Module
1.25Gbps eSFP
CWDM Optical
Module
1.25Gbps eSFP
Optical Module
125M~2.67Gbps
eSFP DWDM
Optical Module
155Mbps eSFP
BIDI Optical
Module
155Mbps eSFP
Optical Module
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Port Connector Type Description Available
Components
36~47 SFP28 Port for inputting 25Gbps SFP28
and outputting Optical Module
25GE/10GE 25Gbps SFP28
optical signals BIDI Optical
Module
10Gbps SFP+
Optical Module
10Gbps SFP+
DWDM Optical
Module
10Gbps SFP+
CWDM Optical
Module
10Gbps SFP+
BIDI Optical
Module
48~55 QSFP28 Port for inputting 100Gbps QSFP28
and outputting Optical Module
100GE/50GE/ 50Gbps QSFP28
40GE/breakout Optical Module
4x25GE/breakout
4x10GE optical 50Gbps QSFP28
signals BIDI Optical
Module
40Gbps QSFP+
Optical Module
GE0/GE1 SFP Cascading port Reserved
used for control
panel expansion
in scenarios like
virtual cluster
(reserved)
MGMT-ETH RJ45 Port for Category 5
connecting to the enhanced
NMS workstation shielded twisted
pairs
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Port Connector Type Description Available
Components
Console/AUX RJ45 Port for 8-core shielded
hybrid interface connecting to the cables
console for onsite
system
configuration. The
default baud rate
is 9600 bit/s.
(AUX hybrid
interface
reserved)
TOD clock RJ45 Port for inputting 120-ohm clock
interface and outputting cable
one-channel 1PPS
+TOD time signals
or one-channel
DCLS signals
CLK interface RJ45 Port for inputting 120-ohm clock
and outputting 2 cable
Mbit/s or 2 MHz
clock signals
USB Type A USB port NA
(reserved)
Interface Numbering Rules
On the NetEngine 8000 F1A-8H20Q, an interface is numbered in the format of
"slot number/subcard number/port number". The following part describes the
details:
● Slot number
The slot number of NetEngine 8000 F1A-8H20Q is always 0.
● Subcard number
The NetEngine 8000 F1A-8H20Q does not support subcards. Therefore, the
subcard number of the NetEngine 8000 F1A-8H20Q is fixed as 1.
● Port number
The port numbers of service interfaces on the NetEngine 8000 F1A-8H20Q
begin with 0. Port numbering depends on the number of interfaces on the
NetEngine 8000 F1A-8H20Q.
Figure 3-5 Port number
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Labels
Figure 3-6 Label position
Table 3-6 Label description
Figure Label Name Description
Chassis bar The bar code will be retrieved by the device as
code label the equipment serial number (ESN).
Multi-power This device has more than one power input.
input caution Disconnect all power inputs to power off this
device.
Product The label suggests the product name,
nameplate certification and qualification.
label
Power Supply System
The system supports DC and AC power supply in 1+1 backup mode.
The power supply system provides the fault monitoring and alarming function.
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
The two power modules work in 1+1 backup mode. The two power supply
channels in backup mode are converted by two independent power supply
modules and then provided for Control board and fans.
Figure 3-7 Power supply architecture
Heat Dissipation System
The system air channel allows air to flow from front to back or from back to front.
Figure 3-8 Front to back (NetEngine 8000 F1A-8H20Q)
Figure 3-9 Back to front (NetEngine 8000 F1A-8H20Q)
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Technical Specifications
Table 3-7 Technical specifications of the CR8B0BKP03C0 (02353AES)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Weight without packaging [kg(lb)] 6.3 kg (13.89 lb)
Weight with packaging [kg(lb)] 11.2 kg (24.69 lb)
Weight without packaging (full DC: 8.4 kg (18.52 lb)
configuration) [kg(lb)] AC: 8.75 kg (19.29 lb)
Weight with packaging (full DC: 13.58 kg(29.94 lb)
configuration) [kg(lb)] AC: 13.75 kg(30.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 20-core 2.0 GHz
Memory 16 GB
Flash memory 64 MB
Storage 4G NAND FLASH
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100 V to 240 V AC, support 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
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HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Maximum input current [A] DC: 30 A
600 W AC: 8 A
1200 W AC: 10 A
Rated output power [W] DC: 1000 W
600 W AC: 600 W
1200 W AC: 1200 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC:≥32A
AC:≥10A
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Front to back: port-side intake
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36 (V800R012C00: 28, V800R012C10
and later versions: 36)
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 22
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Front-to-rear model: –5°C to +45°C
[°C(°F)] (23°F to 113°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 23
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-8 Technical specifications of the CR8B0BKP03C0 (02353AES-001)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 24
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 6.8 kg (14.99 lb)
Weight with packaging [kg(lb)] 11.7 kg (25.79 lb)
Weight without packaging (full DC: 8.9 kg (19.62 lb)
configuration) [kg(lb)] AC: 9.2 kg (20.28 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 8-core 2.3 GHz
Memory 16 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 25
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Front to back: port-side intake
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Front-to-rear model: –5°C to +45°C
[°C(°F)] (23°F to 113°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 26
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 27
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-9 Technical specifications of the CR8B0BKP03C0 (02353AES-006)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 28
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 7 kg (15.43 lb)
Weight with packaging [kg(lb)] 11.9 kg (26.23 lb)
Weight without packaging (full DC: 8.8 kg (19.4 lb)
configuration) [kg(lb)] AC: 9.45 kg (20.83 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 16-core, 2.0 GHz
Memory 32 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 29
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Front to back: port-side intake
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Front-to-rear model: –5°C to +45°C
[°C(°F)] (23°F to 113°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 30
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 31
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-10 Technical specifications of the CR8B0BKP03C2 (02353AGV)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 32
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 6.3 kg (13.89 lb)
Weight with packaging [kg(lb)] 11.2 kg (24.69 lb)
Weight without packaging (full DC: 8.4 kg (18.52 lb)
configuration) [kg(lb)] AC: 8.75 kg (19.29 lb)
Weight with packaging (full DC: 13.58 kg(29.94 lb)
configuration) [kg(lb)] AC: 13.75 kg(30.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 20-core 2.0 GHz
Memory 16 GB
Flash memory 64 MB
Storage 4G NAND FLASH
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100 V to 240 V AC, support 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
600 W AC: 8 A
1200 W AC: 10 A
Rated output power [W] DC: 1000 W
600 W AC: 600 W
1200 W AC: 1200 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 33
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Front-end circuit breaker/fuse [A] DC:≥32A
AC:≥10A
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Back to front: port-side exhaust
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36 (V800R012C00: 28, V800R012C10
and later versions: 36)
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Rear-in front-out model: –5°C to +40°C
[°C(°F)] (23°F to 104°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 34
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 35
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-11 Technical specifications of the CR8B0BKP03C2 (02353AGV-001)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 36
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 6.8 kg (14.99 lb)
Weight with packaging [kg(lb)] 11.7 kg (25.79 lb)
Weight without packaging (full DC: 8.9 kg (19.62 lb)
configuration) [kg(lb)] AC: 9.2 kg (20.28 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 8-core 2.3 GHz
Memory 16 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 37
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Back to front: port-side exhaust
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Rear-in front-out model: –5°C to +40°C
[°C(°F)] (23°F to 104°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 38
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 39
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-12 Technical specifications of the CR8B0BKP03C2 (02353AGV-002)
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 40
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 7 kg (15.43 lb)
Weight with packaging [kg(lb)] 11.9 kg (26.23 lb)
Weight without packaging (full DC: 8.8 kg (19.4 lb)
configuration) [kg(lb)] AC: 9.45 kg (20.83 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 16-core, 2.0 GHz
Memory 32 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 41
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Back to front: port-side exhaust
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Rear-in front-out model: –5°C to +40°C
[°C(°F)] (23°F to 104°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 42
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported No
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 43
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-13 Technical specifications of the CR8B0BKP03D0
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 44
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 7 kg (15.43 lb)
Weight with packaging [kg(lb)] 11.9 kg (26.23 lb)
Weight without packaging (full DC: 8.8 kg (19.4 lb)
configuration) [kg(lb)] AC: 9.45 kg (20.83 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 16-core, 2.0 GHz
Memory 32 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 45
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Front to back: port-side intake
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Front-to-rear model: –5°C to +45°C
[°C(°F)] (23°F to 113°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 46
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported Yes
Physical port 48, 49, 50, and 51 can be
added to the same FlexE group. port-id
ranges from 56 to 95 and from 1000
to 3000. Such a FlexE group supports a
maximum of 40 FlexE clients.
Physical port 52, 53, 54, and 55 can be
added to the same FlexE group. port-id
ranges from 96 to 135 and from 1000
to 3000. Such a FlexE group supports a
maximum of 40 FlexE clients.
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 47
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Table 3-14 Technical specifications of the CR8B0BKP03D2
Item Specification
Cabinet installation standards IEC 19-inch
Dimensions without packaging (H x W 43.6 mm x 442 mm x 420 mm (1.72 in.
x D) [mm(in.)] x 17.4 in. x 16.54 in.)
Dimensions with packaging (H x W x 175 mm x 550 mm x 650 mm (6.89 in.
D) [mm(in.)] x 21.65 in. x 25.59 in.)
Chassis height [U] 1 U
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 48
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Weight without packaging [kg(lb)] 7 kg (15.43 lb)
Weight with packaging [kg(lb)] 11.9 kg (26.23 lb)
Weight without packaging (full DC: 8.8 kg (19.4 lb)
configuration) [kg(lb)] AC: 9.45 kg (20.83 lb)
Weight with packaging (full DC: 14.08 kg(31.04 lb)
configuration) [kg(lb)] AC: 14.2 kg(31.31 lb)
Typical power consumption (with 325 W
configuration) [W]
Typical heat dissipation (with 1054.44 BTU/hour
configuration) [BTU/hour]
MTBF [year] DC: 25.52
AC: 25.65
MTTR [hour] 0.5 hour
Availability 0.99999
CPU 16-core, 2.0 GHz
Memory 32 GB
Flash memory 64 MB
Storage 16G M.2 flash
Power supply mode ● DC
● AC/HVDC
Rated input voltage [V] DC: -48 V/-60 V
AC: 100–240 V AC, supporting 240 V
HVDC
Input voltage range [V] DC: –40 V to –72 V
AC: 90 V to 290 V
Maximum input current [A] DC: 30 A
AC: 8 A
Rated output power [W] DC: 1000 W
AC: 600 W
Maximum input cable size [mm²] DC: 4 mm² (1 m to 14 m), 6 mm² (15
m to 21 m), 10 mm² (22 m to 35 m)
AC: 2.5 mm²
Front-end circuit breaker/fuse [A] DC: ≥ 32 A
AC: ≥ 10 A
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 49
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Types of fans Pluggable
Heat dissipation mode Air cooling
Airflow direction Back to front: port-side exhaust
Noise at normal temperature (acoustic < 72 dB (meeting the ETSI 72 dBA
power) [dB(A)] standard)
Number of slots 7
Number of service board slots 1
Switching capacity 2.4 Tbit/s
Maximum number of physical ports on 56
the entire device
Maximum number of 100GE ports 8
Maximum number of 50GE ports 8
Maximum number of 40GE ports 8
Maximum number of 25GE ports 52 (28 to 47: 20 25GE ports; 48 to 55:
split into 32 25GE ports)
Maximum number of 10GE ports 80 (0 to 47: 48 10GE ports; 48 to 55:
split into 32 10GE ports)
Maximum number of GE ports 36
Maximum number of FE ports 28
Maximum number of electrical ports 28
Redundant power supply 1+1
Redundant fans 3+1, normal operation at 40°C (104°F)
for a short term after a fan fails
Long-term operating temperature Rear-in front-out model: –5°C to +40°C
[°C(°F)] (23°F to 104°F)
Restriction on the operating ≤ 0.5°C/min (32.9°F/min), non-
temperature variation rate [°C(°F)] condensing
Storage temperature [°C(°F)] –40°C to +70°C (–40°F to +158 °F)
Long-term operating relative humidity 5% RH to 90% RH, non-condensing
[RH]
Short-term operating relative humidity 5% RH to 95% RH, non-condensing
[RH]
Storage relative humidity [RH] 5% RH to 95% RH, non-condensing
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 50
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Long-term operating altitude [m(ft.)] ≤ 4000 m (13123.2 ft.) (For the
altitude in the range of 1800 m to
4000 m [5905.44 ft. to 13123.2 ft.], the
operating temperature of the device
must decrease by 1°C [1.8°F] for every
220 m [721.78 ft.].)
Storage altitude [m(ft.)] < 5000 m (16404.2 ft.)
Breakout supported Yes. Only 100GE interfaces support
interface breakout.
To enable interface breakout, run the
port split command.
Interface rate auto-sensing supported Yes
0–27: 10GE ports, supporting 10GE/GE
auto-sensing;
28–35: 25GE ports, supporting 25GE/
10GE auto-sensing in 25GE mode and
10GE/GE auto-sensing in 10GE auto-
sensing mode;
36–47: 25GE ports, supporting 25GE/
10GE auto-sensing;
48–55: 100GE ports, supporting 40GE/
50GE/100GE auto-sensing.
FlexE supported Yes
Physical port 48, 49, 50, and 51 can be
added to the same FlexE group. port-id
ranges from 56 to 95 and from 1000
to 3000. Such a FlexE group supports a
maximum of 40 FlexE clients.
Physical port 52, 53, 54, and 55 can be
added to the same FlexE group. port-id
ranges from 96 to 135 and from 1000
to 3000. Such a FlexE group supports a
maximum of 40 FlexE clients.
MACsec supported Yes
Ports 0 to 31 support MACsec.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 51
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
RTU supported Yes
Ports 0 to 27:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 10GE mode,
their bandwidth is limited to 100
Mbit/s by default. To change the port
bandwidth mode, load the
corresponding RTU license.
Ports 28 to 35:
When these ports work in GE mode,
their bandwidth is not limited.
When these ports work in 25GE/10GE
mode, their bandwidth is limited to
100 Mbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
Ports 36 to 47:
These ports are limited to a bandwidth
of 100 Mbit/s by default. To change
the port bandwidth mode, load the
corresponding RTU license.
Ports 48 to 55:
These ports are limited to a bandwidth
of 50 Gbit/s by default. To change the
port bandwidth mode, load the
corresponding RTU license.
To check the list of RTU licenses
supported by the device and the
loading method, use the License Query
tool or see the related license usage
guide.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 52
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
NO TE
● About condensation
The ability of air to contain moisture reduces as the temperature decreases. There is a
relationship between temperature and relative humidity. As the temperature decreases,
the air becomes more saturated with moisture, meaning the relative humidity increases.
But at a low enough temperature (called the dew point), the air can no longer contain
moisture, which is then precipitated as liquid water. Such water on the surface of
relevant equipment is called condensation.
● Hazards of condensation
When condensation mixes with dust inside the equipment, it forms conductive channels
that affect the electrical insulation of the equipment. As a result, a non-conductive area
of the equipment can become conductive, causing the equipment to malfunction.
● Conditions that cause condensation
Condensation is related to temperature changes and humidity. It occurs when the
temperature continues to decrease below the dew point at a given humidity. For
example, given that the relative humidity is 50% RH and the temperature is 25°C (77°F),
condensation occurs when the temperature decreases below 13.9°C (57.02°F).
3.2 Power
3.2.1 NetEngine 8000 F1A-8H20Q Power Module
3.2.1.1 PAC1K2S12-DB (1200W AC Power Module(Back to Front, Power panel
side exhaust))
Overview
Table 3-15 Basic information about the PAC1K2S12-DB
Item Details
Description 1200W AC Power Module(Back to
Front, Power panel side exhaust)
Part Number 02131672
Model PAC1K2S12-DB
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 53
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Appearance
Figure 3-10 Appearance of the PAC1K2S12-DB
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02131672&productModel=PAC1K2S12-DB#matchRelation
Panel
Table 3-16 Indicators on the PAC1K2S12-DB
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 54
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Table 3-17 Ports on the PAC1K2S12-DB
Port Description
AC power cable connector Connects to the AC power cable
Technical Specifications
Table 3-18 Technical specifications of the PAC1K2S12-DB
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.87 kg(1.92 lb)
Number of inputs 1
Rated input voltage [V] 100 V to 240 V AC, support 240 V
HVDC
Input voltage range [V] 90 V to 290 V AC
Maximum input current [A] 10 A
Rated output voltage [V] 12 V
Rated output current [A] 100 A (input >176V AC)
67 A (input <176V AC)
Rated output power [W] 1200 W (input >176V AC)
800 W (input <176V AC)
Power supply efficiency 0.9
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.2 PAC1K2S12-DF (1200W AC Power Module(Front to Back,Power panel
side intake))
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 55
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Overview
Table 3-19 Basic information about the PAC1K2S12-DF
Item Details
Description 1200W AC Power Module(Front to
Back,Power panel side intake)
Part Number 02131674
Model PAC1K2S12-DF
Appearance
Figure 3-11 Appearance of the PAC1K2S12-DF
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02131674&productModel=PAC1K2S12-DF#matchRelation
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 56
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Panel
Table 3-20 Indicators on the PAC1K2S12-DF
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-21 Ports on the PAC1K2S12-DF
Port Description
AC power cable connector Connects to the AC power cable
Technical Specifications
Table 3-22 Technical specifications of the PAC1K2S12-DF
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.87 kg(1.92 lb)
Number of inputs 1
Rated input voltage [V] 100 V to 240 V AC, support 240 V
HVDC
Input voltage range [V] 90 V to 290 V AC
Maximum input current [A] 10 A
Rated output voltage [V] 12 V
Rated output current [A] 100 A (input >176V AC)
67 A (input <176V AC)
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 57
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Item Specification
Rated output power [W] 1200 W (input >176V AC)
800 W (input <176V AC)
Power supply efficiency 0.9
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.3 PAC600S12-CB (600W AC Power Module(Back to Front, Power panel
side exhaust))
Overview
Table 3-23 Basic information about the PAC600S12-CB
Item Details
Description 600W AC Power Module(Back to
Front, Power panel side exhaust)
Part Number 02312FFU
Model PAC600S12-CB
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 58
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Appearance
Figure 3-12 Appearance of the PAC600S12-CB
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02312FFU&productModel=PAC600S12-CB#matchRelation
Panel
Table 3-24 Indicators on the PAC600S12-CB
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 59
HUAWEI NetEngine 8000 F1A Series
Hardware Guide 3 Hardware Description
Silkscreen Name Color Status Description
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-25 Ports on the PAC600S12-CB
Port Description
AC power cable connector Connects to the AC power cable.
Technical Specifications
Table 3-26 Technical specifications of the PAC600S12-CB
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.95 kg (2.09 lb)
Rated input voltage [V] 100V to 240V AC, support 240V HVDC
Input voltage range [V] 90 V to 290 V
Maximum input current [A] 8 A
Rated output voltage [V] 12 V
Rated output current [A] 50 A
Rated output power [W] 600 W
Power supply efficiency 0.91
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.4 PAC600S12-CF (600W AC Power Module(Front to Back,Power panel
side intake))
Issue 04 (2025-04-30) Copyright © Huawei Technologies Co., Ltd. 60
HUAWEI NetEngine 8000 F1A Series
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Overview
Table 3-27 Basic information about the PAC600S12-CF
Item Details
Description 600W AC Power Module(Front to
Back,Power panel side intake)
Part Number 02312KNA
Model PAC600S12-CF
Appearance
Figure 3-13 Appearance of the PAC600S12-CF
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keyword=02312KNA&productModel=PAC600S12-CF#matchRelation
Panel
Table 3-28 Indicators on the PAC600S12-CF
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-29 Ports on the PAC600S12-CF
Port Description
AC power cable connector Connects to the AC power cable.
Technical Specifications
Table 3-30 Technical specifications of the PAC600S12-CF
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.95 kg (2.09 lb)
Rated input voltage [V] 100V to 240V AC, support 240V HVDC
Input voltage range [V] 90 V to 290 V
Maximum input current [A] 8 A
Rated output voltage [V] 12 V
Rated output current [A] 50 A
Rated output power [W] 600 W
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Item Specification
Power supply efficiency 0.91
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.5 PAC600S12-EB (600W AC Power Module(Back to Front, Power panel
side exhaust))
Overview
Table 3-31 Basic information about the PAC600S12-EB
Item Details
Description 600W AC Power Module(Back to
Front, Power panel side exhaust)
Part Number 02312FFU-002
Model PAC600S12-EB
Appearance
Figure 3-14 Appearance of the PAC600S12-EB
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The huge hardware mapping data is migrated to the Info-Finder hardware center,
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The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02312FFU-002&productModel=PAC600S12-EB#matchRelation
Panel
Table 3-32 Indicators on the PAC600S12-EB
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-33 Ports on the PAC600S12-EB
Port Description
AC power cable connector Connects to the AC power cable.
Technical Specifications
Table 3-34 Technical specifications of the PAC600S12-EB
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.985 kg (2.17 lb)
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Item Specification
Rated input voltage [V] 100V to 240V AC, support 240V HVDC
Input voltage range [V] 90 V to 290 V
Maximum input current [A] 8 A
Rated output voltage [V] 12 V
Rated output current [A] 50 A
Rated output power [W] 600 W
Power supply efficiency 0.91
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.6 PAC600S12-EF (600W AC Power Module(Front to Back,Power panel
side intake))
Overview
Table 3-35 Basic information about the PAC600S12-EF
Item Details
Description 600W AC Power Module(Front to
Back,Power panel side intake)
Part Number 02313RMT
Model PAC600S12-EF
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Appearance
Figure 3-15 Appearance of the PAC600S12-EF
Version Mapping
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where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
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display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02313RMT&productModel=PAC600S12-EF#matchRelation
Panel
Table 3-36 Indicators on the PAC600S12-EF
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
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Silkscreen Name Color Status Description
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-37 Ports on the PAC600S12-EF
Port Description
AC power cable connector Connects to the AC power cable.
Technical Specifications
Table 3-38 Technical specifications of the PAC600S12-EF
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.985 kg (2.17 lb)
Rated input voltage [V] 100V to 240V AC, support 240V HVDC
Input voltage range [V] 90 V to 290 V
Maximum input current [A] 8 A
Rated output voltage [V] 12 V
Rated output current [A] 50 A
Rated output power [W] 600 W
Power supply efficiency 0.91
Power dissipation Mode Built-in fan
Type of power cables C13 cable
3.2.1.7 PDC1000S12-CB (1000W DC Power Module(Back to Front,Power
panel side exhaust))
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Overview
Table 3-39 Basic information about the PDC1000S12-CB
Item Details
Description 1000W DC Power Module(Back to
Front,Power panel side exhaust)
Part Number 02312JVG
Model PDC1000S12-CB
Appearance
Figure 3-16 Appearance of the PDC1000S12-CB
Version Mapping
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The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
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enterprise: https://info.support.huawei.com/info-finder/search-center/en/
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keyword=02312JVG&productModel=PDC1000S12-CB#matchRelation
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Panel
Table 3-40 Indicators on the PDC1000S12-CB
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-41 Ports on the PDC1000S12-CB
Port Description
NEG(-) Connects to the negative pole of the
DC power cable.
RTN(+) Connects to the positive pole of the
DC power cable.
Technical Specifications
Table 3-42 Technical specifications of the PDC1000S12-CB
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.87 kg(1.92 lb)
Rated input voltage [V] –48 V/–60 V
Input voltage range [V] –40 V to –72 V
Maximum input current [A] 30 A
Rated output voltage [V] 12 V
Rated output current [A] 83.3 A
Rated output power [W] 1000 W
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Item Specification
Power supply efficiency 0.88
Power dissipation Mode Built-in fan
3.2.1.8 PDC1000S12-CF (1000W DC Power Module(Front to Back,Power
panel side intake))
Overview
Table 3-43 Basic information about the PDC1000S12-CF
Item Details
Description 1000W DC Power Module(Front to
Back,Power panel side intake)
Part Number 02312KAB
Model PDC1000S12-CF
Appearance
Figure 3-17 Appearance of the PDC1000S12-CF
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Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02312KAB&productModel=PDC1000S12-CF#matchRelation
Panel
Table 3-44 Indicators on the PDC1000S12-CF
Silkscreen Name Color Status Description
STAT Working Green Steady on the power
status input is
indicator normal.
- Off the power
module is
switched off
or the
hardware of
the power
module is
faulty.
Table 3-45 Ports on the PDC1000S12-CF
Port Description
NEG(-) Connects to the negative pole of the
DC power cable.
RTN(+) Connects to the positive pole of the
DC power cable.
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Technical Specifications
Table 3-46 Technical specifications of the PDC1000S12-CF
Item Specification
Dimensions without packaging (H x W 39.8 mm x 90 mm x 214.5 mm (1.57
x D) [mm(in.)] in. x 3.54 in. x 8.44 in.)
Weight without packaging [kg(lb)] 0.87 kg(1.92 lb)
Rated input voltage [V] –48 V/–60 V
Input voltage range [V] –40 V to –72 V
Maximum input current [A] 30 A
Rated output voltage [V] 12 V
Rated output current [A] 83.3 A
Rated output power [W] 1000 W
Power supply efficiency 0.88
Power dissipation Mode Built-in fan
3.3 Fan
3.3.1 NetEngine 8000 F1A-8H20Q Fan Module
3.3.1.1 FAN-031A-B (Fan box(B,FAN panel side exhaust))
Overview
Table 3-47 Basic information about the FAN-031A-B
Item Details
Description Fan box(B,FAN panel side exhaust)
Part Number 02352CAB
Model FAN-031A-B
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Appearance
Figure 3-18 Appearance of the FAN-031A-B
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where you can easily obtain hardware mapping information.
The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
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keyword=02352CAB&productModel=FAN-031A-B#matchRelation
Panel
Table 3-48 Indicators on the FAN-031A-B
Silkscreen Name Color Status Description
FAN Fan status Green steady The board is
indicator working
properly
Red steady The fan
module is
faulty
Green off The fan
module is not
powered on
or encounters
a hardware
error
Technical Specifications
Table 3-49 Technical specifications of the FAN-031A-B
Item Specification
Dimensions without packaging (H x W 40 mm x 40 mm x 100.3 mm (1.57 in.
x D) [mm(in.)] x 1.57 in. x 3.95 in.)
Weight without packaging [kg(lb)] 0.15 kg (0.33 lb)
Number of fans 1
Typical power consumption [W] 4.8 W
3.3.1.2 FAN-031A-F (Fan Box(F,FAN panel side intake ))
Overview
Table 3-50 Basic information about the FAN-031A-F
Item Details
Description Fan Box(F,FAN panel side intake )
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Item Details
Part Number 02352CAA
Model FAN-031A-F
Appearance
Figure 3-19 Appearance of the FAN-031A-F
Version Mapping
The huge hardware mapping data is migrated to the Info-Finder hardware center,
where you can easily obtain hardware mapping information.
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The Info-Finder hardware center incorporates comprehensive hardware
information and mapping data by sales regions, allowing you to quickly find
desired information and filter the mapping data for more fine-grained data
display.
enterprise: https://info.support.huawei.com/info-finder/search-center/en/
enterprise/routers/netengine-8000-pid-252772223/hardwarecenter?
keyword=02352CAA&productModel=FAN-031A-F#matchRelation
Panel
Table 3-51 Indicators on the FAN-031A-F
Silkscreen Name Color Status Description
FAN Fan status Green steady The board is
indicator working
properly
Red steady The fan
module is
faulty
Green off The fan
module is not
powered on
or encounters
a hardware
error
Technical Specifications
Table 3-52 Technical specifications of the FAN-031A-F
Item Specification
Dimensions without packaging (H x W 40 mm x 40 mm x 100.3 mm (1.57 in.
x D) [mm(in.)] x 1.57 in. x 3.95 in.)
Weight without packaging [kg(lb)] 0.15 kg (0.33 lb)
Number of fans 1
Typical power consumption [W] 4.8 W
3.4 Optical Module
3.4.1 Understanding Pluggable Optical Modules
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3.4.1.1 Appearance and Structure
Figure1 shows the structure of an optical module.
Figure 3-20 Optical module structure
1. Handle 2. Receiver 3. Transmitter 4. Shell
5. Label 6. Dust cap 7. Spring 8. Module
connector
3.4.1.2 Types of Optical Modules
Optical modules are available in various types to meet diversified requirements.
● Classified by transmission rates
Currently, the transmission rates of optical modules cover a wide range.
According to different transmission rates, optical modules can be classified
into 400 Gbit/s optical modules, 200 Gbit/s optical modules, 100 Gbit/s optical
modules, 40 Gbit/s optical modules, 25 Gbit/s optical modules, and 10 Gbit/s
optical modules, 2.5 Gbit/s optical modules, 1.25 Gbit/s optical modules, 1000
Mbit/s optical modules, 155 Mbit/s optical modules, and 100 Mbit/s optical
modules.
● Classified by encapsulation types
The higher transmission rate an optical module provides, the more complex
structure it has. According to the encapsulation type, optical modules are
classified into SFP, eSFP, SFP+, XFP, SFP28, QSFP28, QSFP+, CXP, CFP, CSFP, and
QSFP-DD.
– SFP: small form-factor pluggable.
– eSFP: enhanced small form-factor pluggable. An eSFP module is an SFP
module that supports monitoring of voltage, temperature, bias current,
transmit optical power, and receive optical power. Currently, SFP modules
also have the preceding functions. Therefore, eSFP and SFP optical
modules are both called SFP optical modules.
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– SFP+: small form-factor pluggable plus. An SPF+ optical module is an SFP
module with a higher rate. SFP+ modules are more sensitive to
electromagnetic interference (EMI) because they have a higher rate.
Compared with SFP modules, SFP+ optical modules use more springs and
tighter SFP+ optical module cages.
– XFP: 10G small form-factor pluggable. X is the Roman numeral 10,
meaning that all XFP optical modules provide a transmission rate of 10
Gbit/s. XFP optical modules are wider and longer than SFP+ optical
modules.
– SFP28: small form-factor pluggable 28. The size of an SFP28 optical
module is the same as that of an SFP+ optical module. An SFP28 port can
use a 25G SFP28 optical module or 10G SFP+ optical module.
– QSFP28: quad small form-factor pluggable 28. The size of a QSFP28
optical module is the same as that of a QSFP+ optical module. A QSFP28
port can use either a 100G QSFP28 optical module or a 40G QSFP+
optical module.
– QSFP+: quad small form-factor pluggable plus. A QSFP+ optical module
supports the MPO connector and is larger than an SFP+ optical module.
– QSFP-DD: quad small form factor pluggable-double density. A QSFP-DD
optical module is a high-speed pluggable module defined by the QSFP-
DD MSA group.
– CXP: extended-capability form-factor pluggable. A CXP optical module is
a hot-pluggable high-density parallel optical module, which provides 12
channels of traffic in each of the Tx and Rx directions. It applies only to
short-distance multimode links.
– CFP: centum form-factor pluggable, a new standard for high-speed, hot-
pluggable optical transceivers that support data communication and
telecommunication applications. The dimensions of a CFP optical module
are 13.6 mm x 144.75 mm x 82 mm (0.54 in. x 5.70 in. x 3.23 in.).
– CSFP: compact small form-factor pluggable. A CSFP optical module is a
compact SFP transceiver with two 100 Mbit/s or 1 Gbit/s single-fiber
bidirectional transceivers inside a standard SFP form factor. Its compact
and low-power design allows the system supplier to double port density
and access channel quantity for the LPU. This type of optical module is
mainly used in scenarios where one CSFP optical module connects to two
BIDI SFP optical modules. It is essential to ensure that the transmit and
receive wavelengths are consistent and the transmission distances are the
same.
● Classified by physical layer standards
Different physical layer standards are defined to allow data transmission in
different modes. Therefore, different types of optical modules are produced to
comply with these standards. For details, see Standards compliance of the
specific optical module.
● Classified by modes
Optical fibers are classified into single-mode and multimode fibers. Therefore,
optical modules are also classified into single-mode and multimode modules
to support different optical fibers.
– Single-mode optical modules are used with single-mode fibers. Single-
mode fibers support a wide band and large transmission capacity, and are
used for long-distance transmission.
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– Multimode optical modules are used with multimode fibers. Multimode
fibers have lower transmission performance than single-mode fibers
because of modal dispersion, but their costs are also lower. They are used
for small-capacity, short-distance transmission.
Wavelength division multiplexing modules differ from other optical modules in
center wavelengths. A common optical module has a center wavelength of 850
nm, 1310 nm, or 1550 nm, whereas a wavelength division multiplexing module
transmits lights with different center wavelengths. Wavelength division
multiplexing modules are classified into two types: coarse wavelength division
multiplexing (CWDM) and dense wavelength division multiplexing (DWDM).
Within the same band, DWDM modules are available in more types and use
wavelength resources more efficiently than CWDM modules. DWDM and CWDM
modules allow lights with different center wavelengths to be transmitted on one
fiber without interfering each other. Therefore, a passive multiplexer can be used
to combine the lights into one channel, which is then split into multiple channels
by a demultiplexer on the remote end. This reduces the optical fibers required.
DWDM and CWDM modules are used for long-distance transmission.
The transmit power of a long-distance optical module is often larger than its
overload power. Therefore, when using such optical modules, select optical fibers
of an appropriate length to ensure that the actual receive power is smaller than
the overload power. If the optical fibers connected to a long-distance optical
module are too short, use an optical attenuator to reduce the receive power on
the remote optical module. Otherwise, the remote optical module may be burnt.
3.4.1.3 Instruction
The following lists some common optical modules, which may not be supported
by this product. The figures are for reference only.
Table 3-53 Commonly used optical modules
Encaps Interface Appearance
ulatio type
n type
SFP LC Single-fiber-bidirectional transceiver
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Encaps Interface Appearance
ulatio type
n type
eSFP LC Two-fiber bidirectional
Single-fiber-bidirectional transceiver
SFP+ LC Two-fiber bidirectional
Single-fiber-bidirectional transceiver
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Encaps Interface Appearance
ulatio type
n type
XFP LC Two-fiber bidirectional
Single-fiber-bidirectional transceiver
SFP28 LC Two-fiber bidirectional
Single-fiber-bidirectional transceiver
QSFP2 LC/MPO Two-fiber bidirectional
8
Single-fiber-bidirectional transceiver
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Encaps Interface Appearance
ulatio type
n type
QSFP+ LC/MPO
CXP MPO
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Encaps Interface Appearance
ulatio type
n type
CFP LC/MPO CFP
CFP2
CFP4
CFP8
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Encaps Interface Appearance
ulatio type
n type
CSFP LC
QSFP- LC
DD
3.4.1.4 Instructions on How to Use an Optical Module
This section describes instructions on how to use an optical module.
NO TE
Only optical modules matching Huawei products can be used. These optical modules are
strictly tested by Huawei. If non-matching optical modules are used, device requirements
may fail to be met, and services may fail to run properly. To replace optical modules, see
Parts Replacement-Replacing an Optical Module.
ESD Measures
Before touching any optical module, wear an ESD wrist strap or ESD gloves. Take
full ESD measures when installing optical apparatus such as optical modules
indoors or outdoors.
Figure 3-21 Methods of wearing ESD gloves
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Figure 3-22 Methods of wearing an ESD wrist strap
Placing Optical Apparatus and Fibers
Do not touch pins or connecting fingers with bare hands. Handle the optical fibers
gently. Use two fingers to hold the fiber connector instead of grasping the fiber or
the fiber cover.
Do not apply axial or lateral fiber wallop bumps on the fiber. Do not fold, twist, or
crush the tail fiber. Do not drag the tail fiber or press the coupling point of the tail
fiber. Figure 3-23 shows how to properly place optical apparatus and fibers.
Figure 3-23 Methods of placing optical apparatus and fibers
NO TE
During installation, ensure that an optical fiber is coiled into a loop with a diameter of at
least 6 cm (0.20 ft).
Uninstalling Optical Apparatus
● Release the latch and slowly take out the optical apparatus. Do not drag the
optical fiber to forcibly take out the optical module. Ensure that the optical
fiber is connected to and removed from the optical interface horizontally.
Before taking out an optical module, remove its optical fiber and release its
latch first.
Figure 3-24 Closed latch
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Figure 3-25 Open latch
● The black plastic latch shown by (1) in Figure 3-26 is the unlocking device for
the 155 Mbit/s electrical interface optical module. Hold the two sides of the
optical module to remove it, as shown by (2) in Figure 3-26.
Figure 3-26 Removing a 155 Mbit/s electrical interface optical module
Do not remove the black plastic latch when removing the 155 Mbit/s
electrical interface optical module.
If the black plastic latch falls off, use an auxiliary tool, such as a pair of
tweezers, to press the cage buckle, as shown in the following figure. Then,
hold the two sides of the electrical interface optical module to remove it.
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● If the CFP2 optical module is used, its unlocking device is a spring clip, as
shown by (1) in Figure 3-27. Before removing such an optical module, release
the latch first.
Figure 3-27 Removing a CFP2 optical module
● When removing a CFP optical module, loosen the two screw rods of the
module and then remove the module slowly. Do not directly drag the optical
fiber to pull out the optical module or forcibly pull out the optical module.
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CA UTION
The QSFP28 and QSFP-DD modules will get very hot during operation. To
prevent injuries, do not touch the module shells when removing the modules.
Precautions for Loosened Optical Modules
● When installing an optical module, force it into position. If a crack sound is
heard or a slight tremor is felt, it indicates that the latch boss is secured.
When the latch boss is not secured, the connecting finger is unstably
connected to the connector on the board, and the link may become up. On
the condition that the optical module tremors or collides with another object,
however, the optical module will be loosened or the optical signals will be
temporarily cut off.
● When inserting the optical module, make sure that the tab is closed. (At this
time, the latch boss locks the optical module.) After the optical module is
inserted, try pulling it out to see if it is installed in position. If the optical
module cannot be pulled out, it is secured.
● If you cannot push the optical module into an optical module cage any
longer, the optical module is in good contact with the board connector.
● When installing a CFP optical module, push the module panel horizontally
into the connector using even force with both thumbs. After the module is
inserted, push the module slightly to ensure that it has reached the stop
position.
● After the CFP optical module is securely inserted, tighten the two screw rods
of the module alternately. To prevent the module from getting loosened due
to vibration or collision, you are advised to use a screwdriver to tighten the
screw rods.
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Precautions for Receptacle Contamination
● Clean tissues must be prepared for deployment on site. You need to clean the
optical connector before inserting it in the receptacle. This protects the
receptacle against the contamination.
NO TE
Use at least three cleaning tissues. Wipe the end of an optical connector horizontally
in one direction, and then move the connector end to the unused part of the cleaning
tissue to continue. Generally, one cleaning tissue is used for cleaning an optical
connector.
● To prevent contamination, the optical module should be covered with either a
dust cap or an optical connector.
Cover an optical module with a dust cap.
Cover an optical module with an optical connector
● Lay the optical fibers on the optical distribution frame (ODF) or coil them up
in a fiber management tray. Make sure that the optical fibers are not
squeezed.
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● If a receptacle or an optical connector has not been used for a long time and
has not been covered with a dust cap, you should clean it before using it. A
cotton swab is used to clean a receptacle, and a cleaning tissue is used to
clean an optical connector.
NO TE
During the cleaning process, insert the cotton swab and turn it slowly in the
receptacle. Do not use too much force, because the receptacle may be damaged.
● If, for no apparent reason, optical signals are lost during the operation of a
device, use the preceding method to clean the receptacle or the optical
connector. This will eliminate contamination as the cause of the signal loss.
Precautions for Overload-caused Burnt Optical Modules
● When using an OTDR to test the connectivity or the attenuation of optical
signals, disconnect the optical connector from the optical module. Otherwise,
the optical module may be burnt.
● When performing a self-loop test, use an optical attenuator. Do not loosen
the optical connector.
● It is required that a long-distance optical module have an input optical power
of less than -7 dBm. If the input optical power is larger than -7 dBm, you
need to add an optical attenuator. For example, if the transmitting optical
power is X dBm and the optical attenuation is Y dB, the receiving optical
power is X-Y, which must be smaller than -7dBm (X-Y<-7 dBm).
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Inspecting Optical Fiber Connectors
The Ethernet port rate is increasing and the quality requirement for optical fibers
and optical cables is higher. Table 3-54 describes requirements for the loss of
optical fiber connectors according to the national standard (GBT50312-2016).
Table 3-54 Maximum attenuation of the optical fiber connector
Type Maximum attenuation of an optical fiber
connector (dB)
Fiber splicing connector 0.3
Optical mechanical connector 0.3
Optical connector 0.75
NO TE
Fiber cores are connected through connectors, such as the ODF, optical attenuator, and
flange, in splicing and mechanical modes.
Table 3-55 describes requirements for the reflection of the optical fiber connector
when Ethernet ports (such as 200G and 50G) use PAM4 encoding to double the
rate. More connectors bring lower requirements for the reflection.
Table 3-55 Maximum reflection of connectors
Number of Optical Fiber Maximum Reflection of Each Connector
Connectors (dB)
1 -22
2 -29
4 -33
6 -35
8 -37
10 -39
The loss and reflection values of optical fiber connectors are tested and processed
as follows:
1. After the optical fiber at the peer end is disconnected, use the OTDR meter to
test the local end. Check whether the loss and reflection of each link and
node are normal. (The loss of a fiber splicing connector should be less than
0.3 dB, the loss of a connector should be less than 0.75 dB, and the reflection
of a connector should be less than -30 dB.) If the test result is not within the
required range, process the abnormal port.
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2. Locate the equipment room where the port resides based on the distance
between abnormal points in the OTDR test result. Preliminarily determine the
port location, disconnect the port, and perform an OTDR test on the port that
reports alarms. Check whether the distance is consistent with that in the
previous test. If not, continue to test other ports.
3. After the abnormal port is found, test the port using a fiber microscope. If the
port is dirty, clean it.
4. After the port is cleaned, restore the port, and ensure that the connector is
tightened. Perform an OTDR test on the port to check whether loss and
reflection of each link and node are normal.
5. If the fault persists, replace the flange and perform an OTDR test on the port
that reports alarms to check whether loss and reflection of each link and
node are normal.
6. If the fault persists, replace the optical fiber and perform an OTDR test on the
port that reports alarms to check whether loss and reflection of each link and
node are normal.
7. If multiple abnormal points exist on the link, repeat steps 2 to 6.
Other Precautions
● The optical connector should be horizontally inserted in the receptacle to
avoid damages to the receptacle.
● Mixed use of multi-mode and single-mode optical fibers is prohibited.
Otherwise, faults such as signal loss may occur.
Method of distinguishing optical modules in single mode and multi-mode.
Table 3-56 Method of distinguishing optical modules in single mode and
multi-mode
Item Single Mode Multi-mode
Transmission distance 10 km or longer Below 0.5 km
Wavelength Non-850 nm 850 nm
Information on the SM MM
label
50G Optical Module Installation Guide
1. Precautions for optical module installation
(1) If a cabinet with a door is used, a sufficient distance must be reserved between
the optical module and the cabinet door to prevent the puller or patch cord from
bumping on the door.
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(2) Long-distance optical modules must be equipped with optical attenuators for
self-loops. For a 50GBase-ER (40 km) long-distance optical module, the receive
optical power damage threshold is lower than the average minimum transmit
optical power, making the module prone to damage caused by self-loops.
Therefore, the module must be equipped with an optical attenuator for self-loops.
(3) When optical path quality is tested using an OTDR, optical fibers must be
removed from the associated optical module. This is because the OTDR's transmit
optical power is far greater than the optical power damage threshold at the
receive end of an optical module.
2. Method of checking an optical path
Figure 3-28 Method of checking an optical path
3. Method of cleaning the end faces of an optical fiber
Before cleaning the end faces of an optical fiber that is in use, ensure that the
optical fiber has no optical signals. To achieve this, shut down the ports at both
ends of the fiber. Then, clean the end faces and insert the optical fiber back into
the corresponding port.
To clean the end faces of an optical fiber that is not in use, remove the dust-proof
cap from the fiber connector (or the patch cord connector of the involved optical
component), and put the dust-proof cap into a dedicated cleaning kit. After the
cleaning is complete, re-install the dust-proof cap.
● Use the untouched part of a lint-free wipe to wipe the connector end face
along one direction.
● If the end face of an optical fiber cannot be cleaned due to serious
contamination, use a lint-free wipe dipped with cleanser to wipe the end face
along one direction. Then, use a dry lint-free wipe to clean the end face.
Ensure that the end face is dry before using the optical fiber.
● After the cleaning is complete, immediately install a dust-proof cap for any
optical fiber connector that is not in use.
4. Precautions for using a lint-free wipe to clean the end face of an optical
fiber
● Use a smooth surface of the lint-free wipe for cleaning.
● Ensure that the optical fiber connector is vertical to the lint-free wipe during
cleaning.
● Wipe the end face along the direction of the lint-free wipe's grain.
● Wipe the end face along one direction only.
● Any part of a lint-free wipe can be used only once, and a small piece of lint-
free wipe can be used to clean only one connector.
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5. Method of using lint-free swabs to clean the optical port of an optical
module
Remove the dust-proof cap from the optical port of the optical module, and put
the dust-proof cap into a dedicated cleaning kit.
● Select a proper lint-free swab based on the type of the optical port to be
cleaned. (For SC optical ports, use lint-free swabs with a diameter of 2.5 mm;
for LC and MTRJ optical ports, use lint-free swabs with a diameter of 1.25
mm.) Dip the lint-free swab into cleanser, insert it into the inside of the
optical port, and clean the optical port by rotating the swab 360 degrees in
one direction along the inner wall of the optical port.
● Insert a dry lint-free swab of the same type into the inside of the optical port
and clean the optical port by rotating the swab 360 degrees in one direction
along the inner wall of the optical port.
● Cap the optical port after the cleaning is complete.
6. Precautions for using lint-free swabs to clean the optical port of an optical
module
● When cleaning the optical port of an optical module, clean the end faces of
associated optical fibers to prevent the optical fibers from dirtying the optical
port.
● In general, each lint-free swab can be used for cleaning only once. If a used
lint-free swab is confirmed clean and can be reused, it can be used for a
maximum of three times. For example, a lint-free swab that is ever used to
dry an optical port can be used for a maximum of three times.
7. Safety precautions
● Electrostatic protection: Active optical and electrical components are
extremely sensitive to electrostatic. Therefore, take strict measures to protect
against electrostatic. For example, wear ESD gloves during operations and
touch only the shell of the involved component.
● Laser protection: Do not look into optical ports without eye protection when
reseating a module.
8. Discrete reflectance
Focus on the reflection indicators of each node during link deployment. The
discrete reflection indicators must meet the IEEE standards.
Table 3-57 Maximum discrete reflectance of QSFP28 50G defined by IEEE
Number of QSFP28 50G-FR QSFP28 50G-LR QSFP28 50G-ER
discrete (Maximum value (Maximum value (Maximum value
reflectances of each discrete of each discrete of each discrete
greater than –55 reflectance) reflectance) reflectance)
dB
1 -25 dB -22 dB -19 dB
2 -31 dB -29 dB -27 dB
4 -35 dB -33 dB -32 dB
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Number of QSFP28 50G-FR QSFP28 50G-LR QSFP28 50G-ER
discrete (Maximum value (Maximum value (Maximum value
reflectances of each discrete of each discrete of each discrete
greater than –55 reflectance) reflectance) reflectance)
dB
6 -38 dB -35 dB -35 dB
8 -40 dB -37 dB -37 dB
10 -41 dB -39 dB -39 dB
3.4.1.5 Configuring an Optical Attenuator
This section describes how to configure an optical attenuator.
Calculating the Optical Attenuation
You can calculate the optical attenuation based on the actual optical power.
Table 3-58 Description of parameters for calculating optical attenuation
Name Description
P(in)min Worst sensitivity.
P(out)max Maximum transmit optical power.
S Transmission distance.
A Attenuation coefficient. Note that the
attenuation coefficient is related to
optical fiber types and wavelengths. By
default, the attenuation coefficient of
a 1310-nm wavelength in a G.652
fiber is 0.45 dBm/km or 0.4 dBm/km;
the attenuation coefficient of a 1550-
nm wavelength in a G.652 fiber is
0.235 dBm/km or 0.25 dBm/km.
P(in)max Maximum receive optical power, that
is, minimum overload point.
The principle for determining whether an attenuator needs to be configured at a
transmission point is as follows:
If P(out)max – S x Attenuation coefficient > P(in)max, an attenuator needs to be
configured. The optical attenuation is calculated in the following formula: T=
P(out)max - S x Attenuation coefficient - P(in)max.
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Table 3-59 Reference for configuring an attenuator
BOM Descriptio P(out) P(out) P(in) P(in)
Number n max min min max
34060276 eSFP,1310n -8 dBm -15 dBm -31 dBm -8 dBm
m,STM1,LC
,SM,15km
NO TE
● If P(in)max of an optical module equals P(out)max, you do not need to configure an
attenuator.
● You can choose the 5 dBm and 10 dBm attenuators for optical modules on the device.
BOM Number and Description of Attenuators
Table 3-60 BOM number and description of attenuators
BOM Number Description
45030021 Fixed Optical
Attenuator,1260nm~1620nm-5dB-LC/
PC-45dB
45030022 Fixed Optical
Attenuator,1260nm~1620nm-10dB-LC/
PC-45dB
NO TE
This table is for reference only. BOM numbers of attenuators vary with configuration
documents.
3.4.2 155Mbps eSFP Optical Module
3.4.2.1 155Mbps-eSFP-SMF-1550nm-80km-commercial
Table 3-61 155Mbps-eSFP-SMF-1550nm-80km-commercial specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1550nm-80km-
commercial
Part Number 34060282
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Item Value
Model eSFP-FE-LH80-SM1550
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1480 nm - 1580 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1263 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -34 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -10 dBm
Overload power (OMA) [dBm] -
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3.4.2.2 155Mbps-eSFP-SMF-1310nm-15km-industry
Table 3-62 155Mbps-eSFP-SMF-1310nm-15km-industry specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1310nm-15km-
industry
Part Number 34060307
Model eSFP-1310nm-I-1
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 15 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1261 nm - 1360 nm
Maximum Tx optical power (AVG) -8 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -15 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -31 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.2.3 155Mbps-eSFP-SMF-1310nm-40km-industry
Table 3-63 155Mbps-eSFP-SMF-1310nm-40km-industry specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1310nm-40km-
industry
Part Number 34060308
Model eSFP-1310nm-L-1.1
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1263 nm - 1360 nm
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Item Value
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1263 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -34 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -10 dBm
Overload power (OMA) [dBm] -
3.4.2.4 155Mbps-eSFP-SMF-1550nm-80km-industry
Table 3-64 155Mbps-eSFP-SMF-1550nm-80km-industry specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1550nm-80km-
industry
Part Number 34060309
Model eSFP-1550nm-L-1.2
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
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Item Value
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1480 nm - 1580 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1263 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -34 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -10 dBm
Overload power (OMA) [dBm] -
3.4.2.5 155Mbps-eSFP-SMF-1310nm-40km-commercial
Table 3-65 155Mbps-eSFP-SMF-1310nm-40km-commercial specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1310nm-40km-
commercial
Part Number S4015715
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Item Value
Model eSFP-FE-LH40-SM1310
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1263 nm - 1360 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1263 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -34 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -10 dBm
Overload power (OMA) [dBm] -10 dBm
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3.4.2.6 155Mbps-eSFP-MMF-1310nm-2km-commercial
Table 3-66 155Mbps-eSFP-MMF-1310nm-2km-commercial specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-MMF-1310nm-2km-
commercial
Part Number S4015731
Model SFP-FE-SX-MM1310
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options -
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 2 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1270 nm - 1380 nm
Maximum Tx optical power (AVG) -14 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -19 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 10 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1270 nm - 1380 nm
Rx sensitivity (AVG) [dBm] -30 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -14 dBm
Overload power (OMA) [dBm] -14 dBm
3.4.2.7 155Mbps-eSFP-SMF-1310nm-15km-commercial
Table 3-67 155Mbps-eSFP-SMF-1310nm-15km-commercial specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SMF-1310nm-15km-
commercial
Part Number S4015755
Model eSFP-FE-LX-SM1310
Form factor eSFP
Application standard ITU-T G.957, STM-1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 15 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1261 nm - 1360 nm
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Item Value
Maximum Tx optical power (AVG) -8 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -15 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -8 dBm
3.4.3 155Mbps eSFP BIDI Optical Module
3.4.3.1 155Mbps-eSFP-SM-1310nm(Tx)/1550nm(Rx)-15km-commercial
Table 3-68 155Mbps-eSFP-SM-1310nm(Tx)/1550nm(Rx)-15km-commercial
specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SM-1310nm(Tx)/
1550nm(Rx)-15km-commercial
Part Number 02310QNG
Model OSC015B01
Form factor eSFP
Application standard IEEE 802.3, 100BASE-BX10-U
Connector type LC
Optical fiber type SMF
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Item Value
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 15 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) -8 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -14 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -32 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.3.2 155Mbps-eSFP-SM-1550nm(Tx)/1310nm(Rx)-15km-commercial
Table 3-69 155Mbps-eSFP-SM-1550nm(Tx)/1310nm(Rx)-15km-commercial
specifications
Item Value
Basic Information
Module name 155Mbps-eSFP-SM-1550nm(Tx)/
1310nm(Rx)-15km-commercial
Part Number 02310QNH
Model OSC015B02
Form factor eSFP
Application standard IEEE 802.3, 100BASE-BX10-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s
Target transmission distance [km] 15 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1480 nm - 1580 nm
Maximum Tx optical power (AVG) -8 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -14 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
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Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -32 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.4 1Gbps Electrical Module
3.4.4.1 1Gbps-SFP-100m-industry (02310RAV)
Table 3-70 1Gbps-SFP-100m-industry specifications
Item Value
Basic Information
Module name 1Gbps-SFP-100m-industry
Part Number 02310RAV
Model OEGD01N01
Form factor SFP
Application standard IEEE 802.3, 1000Base-T
Connector type RJ45
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 10 Mbit/s
100 Mbit/s
1000 Mbit/s
Target transmission distance [km] 0.1 km
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3.4.4.2 1Gbps-SFP-100m-industry (02310VPT)
Table 3-71 1Gbps-SFP-100m-industry specifications
Item Value
Basic Information
Module name 1Gbps-SFP-100m-industry
Part Number 02310VPT
Model OEGD01N02
Form factor SFP
Application standard IEEE 802.3, 1000Base-T
Connector type RJ45
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 10 Mbit/s
100 Mbit/s
1000 Mbit/s
Target transmission distance [km] 0.1 km
3.4.4.3 1Gbps-SFP-100m-industry (02314FNP)
Table 3-72 1Gbps-SFP-100m-industry specifications
Item Value
Basic Information
Module name 1Gbps-SFP-100m-industry
Part Number 02314FNP
Model OEGD01N03
Form factor SFP
Application standard IEEE 802.3, 1000Base-T
Connector type RJ45
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Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 10 Mbit/s
100 Mbit/s
1000 Mbit/s
Target transmission distance [km] 0.1 km
3.4.5 1.25Gbps eSFP Optical Module
3.4.5.1 1.25Gbps-eSFP-MMF-850nm-500m-extended
Table 3-73 1.25Gbps-eSFP-MMF-850nm-500m-extended specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-MMF-850nm-500m-
extended
Part Number 34060286
Model eSFP-850nm-1000Base-Sx/FC200 MM
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-SX
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] -20°C to 85°C(-4°F to 185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 0.5 km(OM1)
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 770 nm - 860 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9.5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 760 nm - 860 nm
Rx sensitivity (AVG) [dBm] -17 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 0 dBm
Overload power (OMA) [dBm] -
3.4.5.2 1.25Gbps-eSFP-SMF-1310nm-10km-industry
Table 3-74 1.25Gbps-eSFP-SMF-1310nm-10km-industry specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm-10km-
industry
Part Number 34060290
Model eSFP(S)-1310nm-1000Base-Lx
Form factor eSFP
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Item Value
Application standard IEEE 802.3, 1000BASE-LX10
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) -3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -19 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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3.4.5.3 1.25Gbps-eSFP-SMF-1310nm-40km-industry
Table 3-75 1.25Gbps-eSFP-SMF-1310nm-40km-industry specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm-40km-
industry
Part Number 34060320
Model eSFP-1310nm-Lx-40Km
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-EX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1275 nm - 1350 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1275 nm - 1350 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
3.4.5.4 1.25Gbps-eSFP-MMF-850nm-500m-industry
Table 3-76 1.25Gbps-eSFP-MMF-850nm-500m-industry specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-MMF-850nm-500m-
industry
Part Number 34060321
Model eSFP-850nm-1000Base-Sx
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-SX
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 0.5 km
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 770 nm - 860 nm
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Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9.5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 760 nm - 860 nm
Rx sensitivity (AVG) [dBm] -17 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 0 dBm
Overload power (OMA) [dBm] -
3.4.5.5 1.25Gbps-eSFP-SMF-1550nm-80km-commercial
Table 3-77 1.25Gbps-eSFP-SMF-1550nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1550nm-80km-
commercial
Part Number 34060360
Model eSFP-1550nm-1000Base-Zx/FC100
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-ZX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
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Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1500 nm - 1580 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
The interface standard is Huawei-specific.
3.4.5.6 1.25Gbps-eSFP-SMF-1310nm-10km-commercial
Table 3-78 1.25Gbps-eSFP-SMF-1310nm-10km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm-10km-
commercial
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Item Value
Part Number S4016067
Model OSG010N05
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-LX10
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1270 nm - 1355 nm
Maximum Tx optical power (AVG) -3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1270 nm - 1355 nm
Rx sensitivity (AVG) [dBm] -20 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -3 dBm
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3.4.5.7 1.25Gbps-eSFP-SMF-1310nm-40km-commercial
Table 3-79 1.25Gbps-eSFP-SMF-1310nm-40km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm-40km-
commercial
Part Number S4016954
Model OSG040002
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-EX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1275 nm - 1350 nm
Maximum Tx optical power (AVG) 0 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
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Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -3 dBm
3.4.5.8 1.25Gbps-eSFP-SMF-1550nm-100km-commercial
Table 3-80 1.25Gbps-eSFP-SMF-1550nm-100km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1550nm-100km-
commercial
Part Number 34060295
Model eSFP-GE-ZX100-SM1550
Form factor eSFP
Application standard IEEE 802.3, 1000BASE-ZX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 100 km
Transmitter Optical Characteristics
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Item Value
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1500 nm - 1580 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -30 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
NOTE
The interface standard is Huawei-specific.
3.4.6 1.25Gbps eSFP BIDI Optical Module
3.4.6.1 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-10km-
commercial(34060470)
Table 3-81 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-10km-
commercial(34060470) specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm(Tx)/
1490nm(Rx)-10km-
commercial(34060470)
Part Number 34060470
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Item Value
Model SFP-GE-LX-SM1310-BIDI
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX10-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) -3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -9 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1500 nm
Rx sensitivity (AVG) [dBm] -19.5 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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NOTE
Used in pair with 34060475.
3.4.6.2 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-10km-commercial
Table 3-82 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1490nm(Tx)/
1310nm(Rx)-10km-commercial
Part Number 34060475
Model SFP-GE-LX-SM1490-BIDI
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX10-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1490 nm
Tx operating wavelength range [nm] 1480 nm - 1500 nm
Maximum Tx optical power (AVG) -3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
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Item Value
Minimum Tx optical power (AVG) -9 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -19.5 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
Used in pair with 34060470.
3.4.6.3 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-40km-commercial
Table 3-83 1.25Gbps-eSFP-SMF-1310nm(Tx)/1490nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1310nm(Tx)/
1490nm(Rx)-40km-commercial
Part Number 34060539
Model OGEBIDI41
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX40-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
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Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) 3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1500 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -23 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
Used in pair with 34060540.
3.4.6.4 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-40km-commercial
Table 3-84 1.25Gbps-eSFP-SMF-1490nm(Tx)/1310nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1490nm(Tx)/
1310nm(Rx)-40km-commercial
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Item Value
Part Number 34060540
Model OGEBIDI40
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX40-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1490 nm
Tx operating wavelength range [nm] 1480 nm - 1500 nm
Maximum Tx optical power (AVG) 3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -23 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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NOTE
Used in pair with 34060539.
3.4.6.5 1.25Gbps-eSFP-SMF-1570nm(Tx)/1490nm(Rx)-80km-commercial
Table 3-85 1.25Gbps-eSFP-SMF-1570nm(Tx)/1490nm(Rx)-80km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1570nm(Tx)/
1490nm(Rx)-80km-commercial
Part Number 34060595
Model OGEBIDI80
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX80-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1570 nm
Tx operating wavelength range [nm] 1560 nm - 1580 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
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Item Value
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1500 nm
Rx sensitivity (AVG) [dBm] -26 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
Used in pair with 34060596.
3.4.6.6 1.25Gbps-eSFP-SMF-1490nm(Tx)/1570nm(Rx)-80km-commercial
Table 3-86 1.25Gbps-eSFP-SMF-1490nm(Tx)/1570nm(Rx)-80km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1490nm(Tx)/
1570nm(Rx)-80km-commercial
Part Number 34060596
Model OGEBIDI81
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX80-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1490 nm
Tx operating wavelength range [nm] 1480 nm - 1500 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1560 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -26 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
Used in pair with 34060595.
3.4.6.7 0.1~1.25Gbps-eSFP-SMF-1310nm(Tx)/1550nm(Rx)-40km-commercial
Table 3-87 0.1~1.25Gbps-eSFP-SMF-1310nm(Tx)/1550nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 0.1~1.25Gbps-eSFP-SMF-1310nm(Tx)/
1550nm(Rx)-40km-commercial
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Item Value
Part Number 34060638
Model eSFP-1310/1550-L1.1-BIDI
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX40-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] -5°C to 70°C(23°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 0.1~1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -3 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1580 nm
Rx sensitivity (AVG) [dBm] -25 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
When an optical module is used on the OptiX PTN equipment, the rate of the optical
module cannot exceed 155 Mbit/s.
3.4.6.8 0.1~1.25Gbps-eSFP-SMF-1550nm(Tx)/1310nm(Rx)-40km-commercial
Table 3-88 0.1~1.25Gbps-eSFP-SMF-1550nm(Tx)/1310nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 0.1~1.25Gbps-eSFP-SMF-1550nm(Tx)/
1310nm(Rx)-40km-commercial
Part Number 34060639
Model eSFP-1550/1310-L1.1-BIDI
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX40-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] -5°C to 70°C(23°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 0.1~1.25 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1580 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
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Item Value
Minimum Tx optical power (AVG) -3 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] -25 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
When an optical module is used on the OptiX PTN equipment, the rate of the optical
module cannot exceed 155 Mbit/s.
3.4.6.9 1.25Gbps-eSFP-SMF-1550nm(Tx)/1490nm(Rx)-80km-commercial
Table 3-89 1.25Gbps-eSFP-SMF-1550nm(Tx)/1490nm(Rx)-80km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1550nm(Tx)/
1490nm(Rx)-80km-commercial
Part Number 02314RDH
Model SFP-GE-BIDI-80km-SM1550
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX80-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
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Item Value
Security standard TUV; EN 60825-1, EN 62368-1;
NRTL: CAN/CSA C22.2 NO.62368-1-12
* UL 62368-1;
FDA: 21CFR 1040.10 and 1040.11,
Notice NO.56.
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1540 nm - 1560 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1480 nm - 1500 nm
Rx sensitivity (AVG) [dBm] -26 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
It is used with 02314RDK in pairs.
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3.4.6.10 1.25Gbps-eSFP-SMF-1490nm(Tx)/1550nm(Rx)-80km-commercial
Table 3-90 1.25Gbps-eSFP-SMF-1490nm(Tx)/1550nm(Rx)-80km-commercial
specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1490nm(Tx)/
1550nm(Rx)-80km-commercial
Part Number 02314RDK
Model SFP-GE-BIDI-80km-SM1490
Form factor eSFP
Application standard IEEE 802.3ah, 1000Base-BX80-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C (32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard TUV; EN 60825-1, EN 62368-1;
NRTL: CAN/CSA C22.2 NO.62368-1-12
* UL 62368-1;
FDA: 21CFR 1040.10 and 1040.11,
Notice NO.56.
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1490 nm
Tx operating wavelength range [nm] 1480 nm - 1500 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -2 dBm
[dBm]
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Item Value
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1540 nm - 1560 nm
Rx sensitivity (AVG) [dBm] -26 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
It is used with 02314RDH in pairs.
3.4.7 1.25Gbps eSFP CWDM Optical Module
3.4.7.1 1.25Gbps-eSFP-SMF-1571nm-80km-commercial
Table 3-91 1.25Gbps-eSFP-SMF-1571nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1571nm-80km-
commercial
Part Number 34060476
Model eSFP-LH80-SM1571
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1571 nm
Tx operating wavelength range [nm] 1564.5 nm - 1577.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.2 1.25Gbps-eSFP-SMF-1591nm-80km-commercial
Table 3-92 1.25Gbps-eSFP-SMF-1591nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1591nm-80km-
commercial
Part Number 34060477
Model eSFP-LH80-SM1591
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Item Value
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1591 nm
Tx operating wavelength range [nm] 1584.5 nm - 1597.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
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3.4.7.3 1.25Gbps-eSFP-SMF-1551nm-80km-commercial
Table 3-93 1.25Gbps-eSFP-SMF-1551nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1551nm-80km-
commercial
Part Number 34060478
Model eSFP-LH80-SM1551
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1551 nm
Tx operating wavelength range [nm] 1544.5 nm - 1557.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.4 1.25Gbps-eSFP-SMF-1511nm-80km-commercial
Table 3-94 1.25Gbps-eSFP-SMF-1511nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1511nm-80km-
commercial
Part Number 34060479
Model eSFP-LH80-SM1511
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1511 nm
Tx operating wavelength range [nm] 1504.5 nm - 1517.5 nm
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Item Value
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.5 1.25Gbps-eSFP-SMF-1611nm-80km-commercial
Table 3-95 1.25Gbps-eSFP-SMF-1611nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1611nm-80km-
commercial
Part Number 34060480
Model eSFP-LH80-SM1611
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
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Item Value
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1611 nm
Tx operating wavelength range [nm] 1604.5 nm - 1617.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.6 1.25Gbps-eSFP-SMF-1491nm-80km-commercial
Table 3-96 1.25Gbps-eSFP-SMF-1491nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1491nm-80km-
commercial
Part Number 34060481
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Hardware Guide 3 Hardware Description
Item Value
Model eSFP-LH80-SM1491
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1491 nm
Tx operating wavelength range [nm] 1484.5 nm - 1497.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
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3.4.7.7 1.25Gbps-eSFP-SMF-1531nm-80km-commercial
Table 3-97 1.25Gbps-eSFP-SMF-1531nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1531nm-80km-
commercial
Part Number 34060482
Model eSFP-LH80-SM1531
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1531 nm
Tx operating wavelength range [nm] 1524.5 nm - 1537.5 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.7.8 1.25Gbps-eSFP-SMF-1471nm-80km-commercial
Table 3-98 1.25Gbps-eSFP-SMF-1471nm-80km-commercial specifications
Item Value
Basic Information
Module name 1.25Gbps-eSFP-SMF-1471nm-80km-
commercial
Part Number 34060483
Model eSFP-LH80-SM1471
Form factor eSFP
Application standard ITU-T G.957, STM-16
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1471 nm
Tx operating wavelength range [nm] 1464.5 nm - 1477.5 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
3.4.8 125M~2.67Gbps eSFP DWDM Optical Module
3.4.8.1 125M~2.67Gbps-eSFP-SMF-1560.61nm-120km-commercial
Table 3-99 125M~2.67Gbps-eSFP-SMF-1560.61nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1560.61nm-120km-commercial
Part Number 34060366
Model eSFP-LH120-SM192.10
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
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Hardware Guide 3 Hardware Description
Item Value
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1560.61 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.2 125M~2.67Gbps-eSFP-SMF-1559.79nm-120km-commercial
Table 3-100 125M~2.67Gbps-eSFP-SMF-1559.79nm-120km-commercial
specifications
Item Value
Basic Information
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Item Value
Module name 125M~2.67Gbps-eSFP-
SMF-1559.79nm-120km-commercial
Part Number 34060372
Model eSFP-LH120-SM192.20
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1559.79 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
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Item Value
Overload power (OMA) [dBm] -
3.4.8.3 125M~2.67Gbps-eSFP-SMF-1558.98nm-120km-commercial
Table 3-101 125M~2.67Gbps-eSFP-SMF-1558.98nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1558.98nm-120km-commercial
Part Number 34060373
Model eSFP-LH120-SM192.30
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1558.98 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
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Item Value
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.4 125M~2.67Gbps-eSFP-SMF-1558.17nm-120km-commercial
Table 3-102 125M~2.67Gbps-eSFP-SMF-1558.17nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1558.17nm-120km-commercial
Part Number 34060374
Model eSFP-LH120-SM192.40
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
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Item Value
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1558.17 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.5 125M~2.67Gbps-eSFP-SMF-1557.36nm-120km-commercial
Table 3-103 125M~2.67Gbps-eSFP-SMF-1557.36nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1557.36nm-120km-commercial
Part Number 34060375
Model eSFP-LH120-SM192.50
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
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Item Value
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1557.36 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.6 125M~2.67Gbps-eSFP-SMF-1556.55nm-120km-commercial
Table 3-104 125M~2.67Gbps-eSFP-SMF-1556.55nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1556.55nm-120km-commercial
Part Number 34060376
Model eSFP-LH120-SM192.60
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1556.55 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.7 125M~2.67Gbps-eSFP-SMF-1555.75nm-120km-commercial
Table 3-105 125M~2.67Gbps-eSFP-SMF-1555.75nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1555.75nm-120km-commercial
Part Number 34060377
Model eSFP-LH120-SM192.70
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1555.75 nm
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Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.8 125M~2.67Gbps-eSFP-SMF-1554.94nm-120km-commercial
Table 3-106 125M~2.67Gbps-eSFP-SMF-1554.94nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1554.94nm-120km-commercial
Part Number 34060378
Model eSFP-LH120-SM192.80
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1554.94 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.9 125M~2.67Gbps-eSFP-SMF-1554.13nm-120km-commercial
Table 3-107 125M~2.67Gbps-eSFP-SMF-1554.13nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1554.13nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060379
Model eSFP-LH120-SM192.90
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1554.13 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.10 125M~2.67Gbps-eSFP-SMF-1553.33nm-120km-commercial
Table 3-108 125M~2.67Gbps-eSFP-SMF-1553.33nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1553.33nm-120km-commercial
Part Number 34060380
Model eSFP-LH120-SM193.00
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1553.33 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.11 125M~2.67Gbps-eSFP-SMF-1552.52nm-120km-commercial
Table 3-109 125M~2.67Gbps-eSFP-SMF-1552.52nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1552.52nm-120km-commercial
Part Number 34060381
Model eSFP-LH120-SM193.10
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1552.52 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.12 125M~2.67Gbps-eSFP-SMF-1551.72nm-120km-commercial
Table 3-110 125M~2.67Gbps-eSFP-SMF-1551.72nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1551.72nm-120km-commercial
Part Number 34060382
Model eSFP-LH120-SM193.20
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1551.72 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.13 125M~2.67Gbps-eSFP-SMF-1550.92nm-120km-commercial
Table 3-111 125M~2.67Gbps-eSFP-SMF-1550.92nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1550.92nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060383
Model eSFP-LH120-SM193.30
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550.92 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.14 125M~2.67Gbps-eSFP-SMF-1550.12nm-120km-commercial
Table 3-112 125M~2.67Gbps-eSFP-SMF-1550.12nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1550.12nm-120km-commercial
Part Number 34060384
Model eSFP-LH120-SM193.40
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550.12 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.15 125M~2.67Gbps-eSFP-SMF-1549.32nm-120km-commercial
Table 3-113 125M~2.67Gbps-eSFP-SMF-1549.32nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1549.32nm-120km-commercial
Part Number 34060385
Model eSFP-LH120-SM193.50
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1549.32 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.16 125M~2.67Gbps-eSFP-SMF-1548.51nm-120km-commercial
Table 3-114 125M~2.67Gbps-eSFP-SMF-1548.51nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1548.51nm-120km-commercial
Part Number 34060386
Model eSFP-LH120-SM193.60
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1548.51 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.17 125M~2.67Gbps-eSFP-SMF-1547.72nm-120km-commercial
Table 3-115 125M~2.67Gbps-eSFP-SMF-1547.72nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1547.72nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060387
Model eSFP-LH120-SM193.70
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1547.72 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.18 125M~2.67Gbps-eSFP-SMF-1546.92nm-120km-commercial
Table 3-116 125M~2.67Gbps-eSFP-SMF-1546.92nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1546.92nm-120km-commercial
Part Number 34060388
Model eSFP-LH120-SM193.80
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1546.92 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.19 125M~2.67Gbps-eSFP-SMF-1546.12nm-120km-commercial
Table 3-117 125M~2.67Gbps-eSFP-SMF-1546.12nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1546.12nm-120km-commercial
Part Number 34060389
Model eSFP-LH120-SM193.90
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1546.12 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.20 125M~2.67Gbps-eSFP-SMF-1545.32nm-120km-commercial
Table 3-118 125M~2.67Gbps-eSFP-SMF-1545.32nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1545.32nm-120km-commercial
Part Number 34060390
Model eSFP-LH120-SM194.00
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1545.32 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.21 125M~2.67Gbps-eSFP-SMF-1544.53nm-120km-commercial
Table 3-119 125M~2.67Gbps-eSFP-SMF-1544.53nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1544.53nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060391
Model eSFP-LH120-SM194.10
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1544.53 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.22 125M~2.67Gbps-eSFP-SMF-1543.73nm-120km-commercial
Table 3-120 125M~2.67Gbps-eSFP-SMF-1543.73nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1543.73nm-120km-commercial
Part Number 34060392
Model eSFP-LH120-SM194.20
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1543.73 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.23 125M~2.67Gbps-eSFP-SMF-1542.94nm-120km-commercial
Table 3-121 125M~2.67Gbps-eSFP-SMF-1542.94nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1542.94nm-120km-commercial
Part Number 34060393
Model eSFP-LH120-SM194.30
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1542.94 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.24 125M~2.67Gbps-eSFP-SMF-1542.14nm-120km-commercial
Table 3-122 125M~2.67Gbps-eSFP-SMF-1542.14nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1542.14nm-120km-commercial
Part Number 34060394
Model eSFP-LH120-SM194.40
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1542.14 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.25 125M~2.67Gbps-eSFP-SMF-1541.35nm-120km-commercial
Table 3-123 125M~2.67Gbps-eSFP-SMF-1541.35nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1541.35nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060395
Model eSFP-LH120-SM194.50
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1541.35 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.26 125M~2.67Gbps-eSFP-SMF-1540.56nm-120km-commercial
Table 3-124 125M~2.67Gbps-eSFP-SMF-1540.56nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1540.56nm-120km-commercial
Part Number 34060396
Model eSFP-LH120-SM194.60
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1540.56 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.27 125M~2.67Gbps-eSFP-SMF-1539.77nm-120km-commercial
Table 3-125 125M~2.67Gbps-eSFP-SMF-1539.77nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1539.77nm-120km-commercial
Part Number 34060397
Model eSFP-LH120-SM194.70
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1539.77 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.28 125M~2.67Gbps-eSFP-SMF-1538.98nm-120km-commercial
Table 3-126 125M~2.67Gbps-eSFP-SMF-1538.98nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1538.98nm-120km-commercial
Part Number 34060398
Model eSFP-LH120-SM194.80
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1538.98 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.29 125M~2.67Gbps-eSFP-SMF-1538.19nm-120km-commercial
Table 3-127 125M~2.67Gbps-eSFP-SMF-1538.19nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1538.19nm-120km-commercial
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Hardware Guide 3 Hardware Description
Item Value
Part Number 34060399
Model eSFP-LH120-SM194.90
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1538.19 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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Hardware Guide 3 Hardware Description
3.4.8.30 125M~2.67Gbps-eSFP-SMF-1537.40nm-120km-commercial
Table 3-128 125M~2.67Gbps-eSFP-SMF-1537.40nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1537.40nm-120km-commercial
Part Number 34060400
Model eSFP-LH120-SM195.00
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1537.4 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Hardware Guide 3 Hardware Description
Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.31 125M~2.67Gbps-eSFP-SMF-1536.61nm-120km-commercial
Table 3-129 125M~2.67Gbps-eSFP-SMF-1536.61nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1536.61nm-120km-commercial
Part Number 34060401
Model eSFP-LH120-SM195.10
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1536.61 nm
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Hardware Guide 3 Hardware Description
Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.32 125M~2.67Gbps-eSFP-SMF-1535.82nm-120km-commercial
Table 3-130 125M~2.67Gbps-eSFP-SMF-1535.82nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1535.82nm-120km-commercial
Part Number 34060402
Model eSFP-LH120-SM195.20
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Hardware Guide 3 Hardware Description
Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1535.82 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.33 125M~2.67Gbps-eSFP-SMF-1535.04nm-120km-commercial
Table 3-131 125M~2.67Gbps-eSFP-SMF-1535.04nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1535.04nm-120km-commercial
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Item Value
Part Number 34060403
Model eSFP-LH120-SM195.30
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1535.04 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.34 125M~2.67Gbps-eSFP-SMF-1534.25nm-120km-commercial
Table 3-132 125M~2.67Gbps-eSFP-SMF-1534.25nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1534.25nm-120km-commercial
Part Number 34060404
Model eSFP-LH120-SM195.40
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1534.25 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.35 125M~2.67Gbps-eSFP-SMF-1533.47nm-120km-commercial
Table 3-133 125M~2.67Gbps-eSFP-SMF-1533.47nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1533.47nm-120km-commercial
Part Number 34060405
Model eSFP-LH120-SM195.50
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1533.47 nm
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Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.36 125M~2.67Gbps-eSFP-SMF-1532.68nm-120km-commercial
Table 3-134 125M~2.67Gbps-eSFP-SMF-1532.68nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1532.68nm-120km-commercial
Part Number 34060406
Model eSFP-LH120-SM195.60
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1532.68 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.37 125M~2.67Gbps-eSFP-SMF-1531.90nm-120km-commercial
Table 3-135 125M~2.67Gbps-eSFP-SMF-1531.90nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1531.90nm-120km-commercial
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Item Value
Part Number 34060407
Model eSFP-LH120-SM195.70
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1531.9 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
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3.4.8.38 125M~2.67Gbps-eSFP-SMF-1531.12nm-120km-commercial
Table 3-136 125M~2.67Gbps-eSFP-SMF-1531.12nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1531.12nm-120km-commercial
Part Number 34060408
Model eSFP-LH120-SM195.80
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1531.12 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.39 125M~2.67Gbps-eSFP-SMF-1530.33nm-120km-commercial
Table 3-137 125M~2.67Gbps-eSFP-SMF-1530.33nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1530.33nm-120km-commercial
Part Number 34060409
Model eSFP-LH120-SM195.90
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1530.33 nm
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Item Value
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.8.40 125M~2.67Gbps-eSFP-SMF-1529.55nm-120km-commercial
Table 3-138 125M~2.67Gbps-eSFP-SMF-1529.55nm-120km-commercial
specifications
Item Value
Basic Information
Module name 125M~2.67Gbps-eSFP-
SMF-1529.55nm-120km-commercial
Part Number 34060410
Model eSFP-LH120-SM196.00
Form factor eSFP
Application standard SONET OC-48 LR-2, Gigabit Ethernet
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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Item Value
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 155 Mbit/s ~ 2.67 Gbit/s
Target transmission distance [km] 120 km
Transmitter Optical Characteristics
Center wavelength [nm] 1529.55 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1520 nm - 1570 nm
Rx sensitivity (AVG) [dBm] -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -8 dBm
Overload power (OMA) [dBm] -
3.4.9 10Gbps SFP+ Optical Module
3.4.9.1 10Gbps-SFP+-SMF-1550nm-80km-commercial
Table 3-139 10Gbps-SFP+-SMF-1550nm-80km-commercial specifications
Item Value
Basic Information
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Hardware Guide 3 Hardware Description
Item Value
Module name 10Gbps-SFP+-SMF-1550nm-80km-
commercial
Part Number 02310PVU
Model OSX080N04
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ZR/ZW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1565 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 9 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1565 nm
Rx sensitivity (AVG) [dBm] -24 dBm
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Item Value
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
NOTE
The interface standard is Huawei-specific. Self-loop is not supported. An optical attenuator
must be added if self-loop is required.
3.4.9.2 10Gbps-SFP+-SMF-1310nm-10km-industry
Table 3-140 10Gbps-SFP+-SMF-1310nm-10km-industry specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1310nm-10km-
industry
Part Number 34060599
Model OSX010N05
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-LR/LW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1355 nm
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Item Value
Maximum Tx optical power (AVG) 0.5 dBm
[dBm]
Maximum Tx optical power (OMA) -5.2 dBm
[dBm]
Minimum Tx optical power (AVG) -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1355 nm
Rx sensitivity (AVG) [dBm] -14.4 dBm
Rx sensitivity (OMA) [dBm] -12.6 dBm
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] -
3.4.9.3 10Gbps-SFP+-SMF-1550nm-40km-industry
Table 3-141 10Gbps-SFP+-SMF-1550nm-40km-industry specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1550nm-40km-
industry
Part Number 34060684
Model OSX040N05
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
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Item Value
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1565 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -1.7 dBm
[dBm]
Minimum Tx optical power (AVG) -4.7 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1530 nm - 1565 nm
Rx sensitivity (AVG) [dBm] -15.8 dBm
Rx sensitivity (OMA) [dBm] -14.1 dBm
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -
NOTE
Self-loop is not supported. An optical attenuator must be added if self-loop is required.
3.4.9.4 10Gbps-SFP+-MMF-850nm-0.3km-commercial
Table 3-142 10Gbps-SFP+-MMF-850nm-0.3km-commercial specifications
Item Value
Basic Information
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Hardware Guide 3 Hardware Description
Item Value
Module name 10Gbps-SFP+-MMF-850nm-0.3km-
commercial
Part Number S4017482
Model OSX040N03
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-SR/SW
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 0.3 km(OM3)
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) -1 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -7.3 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -9.9 dBm
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Item Value
Rx sensitivity (OMA) [dBm] -11.1 dBm
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -1 dBm
3.4.9.5 10Gbps-SFP+-SMF-1310nm-10km-commercial
Table 3-143 10Gbps-SFP+-SMF-1310nm-10km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1310nm-10km-
commercial
Part Number S4017483
Model OSX001002
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-LR/LW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1355 nm
Maximum Tx optical power (AVG) 0.5 dBm
[dBm]
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Item Value
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1355 nm
Rx sensitivity (AVG) [dBm] -14.4 dBm
Rx sensitivity (OMA) [dBm] -12.6 dBm
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] 0.5 dBm
3.4.9.6 10Gbps-SFP+-SMF-1550nm-40km-commercial
Table 3-144 10Gbps-SFP+-SMF-1550nm-40km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1550nm-40km-
commercial
Part Number S4017484
Model OMXD30002
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1565 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -4.7 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1530 nm - 1565 nm
Rx sensitivity (AVG) [dBm] -15.8 dBm
Rx sensitivity (OMA) [dBm] -14.1 dBm
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -1 dBm
NOTE
Self-loop is not supported. An optical attenuator must be added if self-loop is required.
3.4.10 1.25/9.953/10.3125Gbps SFP+ Optical Module
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3.4.10.1 1.25/9.953/10.3125Gbps-SFP+-SMF-1310nm-10km-commercial
Table 3-145 1.25/9.953/10.3125Gbps-SFP+-SMF-1310nm-10km-commercial
specifications
Item Value
Basic Information
Module name 1.25/9.953/10.3125Gbps-SFP+-
SMF-1310nm-10km-commercial
Part Number 34061042
Model OSX010N13
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-LR/LW,
1000BASE-LX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] GE: 10 km
10GE: 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1360 nm
Maximum Tx optical power (AVG) GE: 0.5 dBm
[dBm] 10GE: 0.5 dBm
Maximum Tx optical power (OMA) -
[dBm]
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Minimum Tx optical power (AVG) GE: -8.2 dBm
[dBm] 10GE: -8.2 dBm
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] GE: 9 dB
10GE: 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1360 nm
Rx sensitivity (AVG) [dBm] GE: -19 dBm
10GE: -14.4 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] 0.5 dBm
3.4.10.2 1.25/9.953/10.3125Gbps-SFP+-SMF-1550nm-40km-commercial
Table 3-146 1.25/9.953/10.3125Gbps-SFP+-SMF-1550nm-40km-commercial
specifications
Item Value
Basic Information
Module name 1.25/9.953/10.3125Gbps-SFP+-
SMF-1550nm-40km-commercial
Part Number 34061043
Model OSX040N12
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW,
1000BASE-LX
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
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Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 1.25 Gbit/s
9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] GE: 40 km
10GE: 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1550 nm
Tx operating wavelength range [nm] 1530 nm - 1565 nm
Maximum Tx optical power (AVG) GE: 4 dBm
[dBm] 10GE: 4 dBm
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) GE: -4.7 dBm
[dBm] 10GE: -4.7 dBm
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] GE: 9 dB
10GE: 3.0 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1530 nm - 1565 nm
Rx sensitivity (AVG) [dBm] GE: -15.8 dBm
10GE: -15.8 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -1 dBm
3.4.11 10Gbps SFP+ CWDM Optical Module
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3.4.11.1 10Gbps-SFP+-SMF-1511nm-70km-commercial
Table 3-147 10Gbps-SFP+-SMF-1511nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1511nm-70km-
commercial
Part Number 34060686
Model OSX070001
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1511 nm
Tx operating wavelength range [nm] 1504.5 nm - 1517.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
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Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.2 10Gbps-SFP+-SMF-1471nm-70km-commercial
Table 3-148 10Gbps-SFP+-SMF-1471nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1471nm-70km-
commercial
Part Number 34060687
Model OSX070002
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1471 nm
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Item Value
Tx operating wavelength range [nm] 1464.5 nm - 1477.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.3 10Gbps-SFP+-SMF-1491nm-70km-commercial
Table 3-149 10Gbps-SFP+-SMF-1491nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1491nm-70km-
commercial
Part Number 34060688
Model OSX070003
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1491 nm
Tx operating wavelength range [nm] 1484.5 nm - 1497.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.4 10Gbps-SFP+-SMF-1531nm-70km-commercial
Table 3-150 10Gbps-SFP+-SMF-1531nm-70km-commercial specifications
Item Value
Basic Information
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Item Value
Module name 10Gbps-SFP+-SMF-1531nm-70km-
commercial
Part Number 34060689
Model OSX070004
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1531 nm
Tx operating wavelength range [nm] 1524.5 nm - 1537.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
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Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.5 10Gbps-SFP+-SMF-1551nm-70km-commercial
Table 3-151 10Gbps-SFP+-SMF-1551nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1551nm-70km-
commercial
Part Number 34060690
Model OSX070005
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1551 nm
Tx operating wavelength range [nm] 1544.5 nm - 1557.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
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Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.6 10Gbps-SFP+-SMF-1571nm-70km-commercial
Table 3-152 10Gbps-SFP+-SMF-1571nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1571nm-70km-
commercial
Part Number 34060691
Model OSX070006
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1571 nm
Tx operating wavelength range [nm] 1564.5 nm - 1577.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -23 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.11.7 10Gbps-SFP+-SMF-1591nm-70km-commercial
Table 3-153 10Gbps-SFP+-SMF-1591nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1591nm-70km-
commercial
Part Number 34060692
Model OSX070007
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Item Value
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1591 nm
Tx operating wavelength range [nm] 1584.5 nm - 1597.5 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -21 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
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3.4.11.8 10Gbps-SFP+-SMF-1611nm-70km-commercial
Table 3-154 10Gbps-SFP+-SMF-1611nm-70km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1611nm-70km-
commercial
Part Number 34060693
Model OSX070008
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-X
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 70 km
Transmitter Optical Characteristics
Center wavelength [nm] 1611 nm
Tx operating wavelength range [nm] 1604.5 nm - 1617.4 nm
Maximum Tx optical power (AVG) 4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
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Receiver Optical Characteristics
Rx operating wavelength range [nm] 1460 nm - 1620 nm
Rx sensitivity (AVG) [dBm] -21 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -7 dBm
Overload power (OMA) [dBm] -
3.4.12 10Gbps SFP+ BIDI Optical Module
3.4.12.1 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-40km-commercial
Table 3-155 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1270nm(Tx)/
1330nm(Rx)-40km-commercial
Part Number 02311JNF
Model OSX040B10
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-BX-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C (32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
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Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1270 nm
Tx operating wavelength range [nm] 1260 nm - 1280 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1320 nm - 1340 nm
Rx sensitivity (AVG) [dBm] -18 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
NOTE
1. Ensure that the optical power on the receive side is less than or equal to –5 dBm. If the
optical power does not meet the requirement, add an optical attenuator. Do not use short-
distance optical fibers for direct connection.
3.4.12.2 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-40km-commercial
Table 3-156 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1330nm(Tx)/
1270nm(Rx)-40km-commercial
Part Number 02311JNQ
Model OSX040B11
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Item Value
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-BX40-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1330 nm
Tx operating wavelength range [nm] 1320 nm - 1340 nm
Maximum Tx optical power (AVG) 5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) 0 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1280 nm
Rx sensitivity (AVG) [dBm] -18 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -9 dBm
Overload power (OMA) [dBm] -
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NOTE
1. Ensure that the optical power on the receive side is less than or equal to –5 dBm. If the
optical power does not meet the requirement, add an optical attenuator. Do not use short-
distance optical fibers for direct connection.
3.4.12.3 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-10km-industry
Table 3-157 10Gbps-SFP+-SMF-1270nm(Tx)/1330nm(Rx)-10km-industry
specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1270nm(Tx)/
1330nm(Rx)-10km-industry
Part Number 34060544-002
Model OSX010B10
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-BX10-U
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1270 nm
Tx operating wavelength range [nm] 1260 nm - 1280 nm
Maximum Tx optical power (AVG) 0.5 dBm
[dBm]
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Item Value
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -5.2 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1320 nm - 1340 nm
Rx sensitivity (AVG) [dBm] -14.4 dBm
Rx sensitivity (OMA) [dBm] -10.3 dBm
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] -
3.4.12.4 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-10km-industry
Table 3-158 10Gbps-SFP+-SMF-1330nm(Tx)/1270nm(Rx)-10km-industry
specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-SMF-1330nm(Tx)/
1270nm(Rx)-10km-industry
Part Number 34060546-002
Model OSX010B11
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-BX10-D
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1330 nm
Tx operating wavelength range [nm] 1320 nm - 1340 nm
Maximum Tx optical power (AVG) 0.5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -5.2 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1280 nm
Rx sensitivity (AVG) [dBm] -14.4 dBm
Rx sensitivity (OMA) [dBm] -12.6 dBm
Overload power (AVG) [dBm] 0.5 dBm
Overload power (OMA) [dBm] -
3.4.13 10Gbps SFP+ OTN Optical Module
3.4.13.1 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial
Table 3-159 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial specifications
Item Value
Basic Information
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Item Value
Module name 10Gbps-SFP+-
SMF-1528nm~1568nm-40km-
commercial
Part Number 02314MED
Model OSX040C01
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW, ITUT
G.709
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(10GE)
<1x10E-4(OTU2, OTU2e)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-INF-8077i
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
11.1 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] -
Tx operating wavelength range [nm] 1529.163 nm - 1567.133 nm
Maximum Tx optical power (AVG) 3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -1 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1260 nm - 1600 nm
Rx sensitivity (AVG) [dBm] -16 dBm(EOL)(@ BER 1E-12,
9.95Gbps~10.7Gbps)
-19 dBm(EOL)(@ BER 2E-03, 11.3Gbps,
dispersion 800ps/nm, at room
temperature and OSNR > 31dB)
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -
3.4.14 10Gbps SFP+ DWDM Optical Module
3.4.14.1 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial
Table 3-160 10Gbps-SFP+-SMF-1528nm~1568nm-40km-commercial specifications
Item Value
Basic Information
Module name 10Gbps-SFP+-
SMF-1528nm~1568nm-40km-
commercial
Part Number 02314MED
Model OSX040C01
Form factor SFP+
Application standard IEEE 802.3ae, 10GBASE-ER/EW, ITUT
G.709
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(10GE)
<1x10E-4(OTU2, OTU2e)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-INF-8077i
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 9.953 Gbit/s
10.3125 Gbit/s
11.1 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] -
Tx operating wavelength range [nm] 1529.163 nm - 1567.133 nm
Maximum Tx optical power (AVG) 3 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -1 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 8.2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1600 nm
Rx sensitivity (AVG) [dBm] -16 dBm(EOL)(@ BER 1E-12,
9.95Gbps~10.7Gbps)
-19 dBm(EOL)(@ BER 2E-03, 11.3Gbps,
dispersion 800ps/nm, at room
temperature and OSNR > 31dB)
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] -1 dBm
Overload power (OMA) [dBm] -
3.4.15 25Gbps SFP28 Optical Module
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3.4.15.1 25Gbps-SFP28-MMF-850nm-0.1km-commercial (02312PDK)
Table 3-161 25Gbps-SFP28-MMF-850nm-0.1km-commercial specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-MMF-850nm-0.1km-
commercial
Part Number 02312PDK
Model SFP28-25G-850nm-0.1km-MM
Form factor SFP28
Application standard IEEE802.3-2012, 25GBASE-SR
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <5x10E-5
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 0.1 km
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) 2.4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.4 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 2 dB
Receiver Optical Characteristics
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Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -10.3 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 2.4 dBm
Overload power (OMA) [dBm] -
3.4.15.2 25Gbps-SFP28-SMF-1310nm-10km-industry (02312PDL)
Table 3-162 25Gbps-SFP28-SMF-1310nm-10km-industry specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-SMF-1310nm-10km-
industry
Part Number 02312PDL
Model SFP28-25G-1310nm-10km-SM
Form factor SFP28
Application standard IEEE 802.3 cc, 25GBASE-LR, 10GBASE-
LR
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
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Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1295 nm - 1325 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -7 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1295 nm - 1325 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -11.3 dBm
Overload power (AVG) [dBm] 2 dBm
Overload power (OMA) [dBm] -
3.4.15.3 25Gbps-SFP28-MMF-850nm-0.1km-commercial (34061254)
Table 3-163 25Gbps-SFP28-MMF-850nm-0.1km-commercial specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-MMF-850nm-0.1km-
commercial
Part Number 34061254
Model OMXD30011
Form factor SFP28
Application standard IEEE802.3-2012, 25GBASE-SR
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <5x10E-5
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Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 0.1 km
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) 2.4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.4 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -10.3 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 2.4 dBm
Overload power (OMA) [dBm] -
3.4.15.4 25Gbps-SFP28-SMF-1310nm-10km-industry (34061618)
Table 3-164 25Gbps-SFP28-SMF-1310nm-10km-industry specifications
Item Value
Basic Information
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Item Value
Module name 25Gbps-SFP28-SMF-1310nm-10km-
industry
Part Number 34061618
Model SFP28-25G-1310nm-10km-SM
Form factor SFP28
Application standard IEEE 802.3 by-2016, 25GBASE-LR,
10GBASE-LR
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1295 nm - 1325 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -7 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1295 nm - 1325 nm
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Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -11.3 dBm
Overload power (AVG) [dBm] 2 dBm
Overload power (OMA) [dBm] -
3.4.15.5 25Gbps-SFP28-MMF-850nm-0.1km-extended
Table 3-165 25Gbps-SFP28-MMF-850nm-0.1km-extended specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-MMF-850nm-0.1km-
extended
Part Number 34061631
Model SFP28-25G-850nm-0.1km-MM
Form factor SFP28
Application standard IEEE 802.3 by-2016, 25GBASE-SR,
10GBASE-SR
Connector type LC
Optical fiber type MMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] -20°C to 75°C(-4°F to 167°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 0.1 km
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
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Item Value
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) 2.4 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -8.4 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -10.3 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] 2.4 dBm
Overload power (OMA) [dBm] -
3.4.16 25Gbps SFP28 BIDI Optical Module
3.4.16.1 25Gbps-SFP28-SMF-1270nm(Tx)/1330nm(Rx)-10km-commercial
Table 3-166 25Gbps-SFP28-SMF-1270nm(Tx)/1330nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-SMF-1270nm(Tx)/
1330nm(Rx)-10km-commercial
Part Number 02312TVC
Model SFP28-25G-BIDI-10km-SM-3
Form factor SFP28
Application standard IEEE 802.3 by-2016, 25GBASE-LR,
10GBASE-LR
Connector type LC
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Optical fiber type SMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1270 nm
Tx operating wavelength range [nm] 1260 nm - 1280 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -4 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1320 nm - 1340 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -12 dBm
Overload power (AVG) [dBm] 2 dBm
Overload power (OMA) [dBm] -
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3.4.16.2 25Gbps-SFP28-SMF-1330nm(Tx)/1270nm(Rx)-10km-commercial
Table 3-167 25Gbps-SFP28-SMF-1330nm(Tx)/1270nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 25Gbps-SFP28-SMF-1330nm(Tx)/
1270nm(Rx)-10km-commercial
Part Number 02312TXG
Model SFP28-25G-BIDI-10km-SM-4
Form factor SFP28
Application standard IEEE 802.3 by-2016, 25GBASE-LR,
10GBASE-LR
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5(24.33024G,25.78125G)
<1x10E-12(9.8304G,10.1376G,10.3125
G)
Working case temperature [°C(°F)] –40°C to +85°C(–40°F to +185°F)
DDM options SFF-8472
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 25.78125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1330 nm
Tx operating wavelength range [nm] 1320 nm - 1340 nm
Maximum Tx optical power (AVG) 2 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) -4 dBm
[dBm]
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Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1280 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -12 dBm
Overload power (AVG) [dBm] 2 dBm
Overload power (OMA) [dBm] -
3.4.17 40Gbps QSFP+ Optical Module
3.4.17.1 40Gbps(4*10.3)-QSFP+-SMF-1271~1331nm-10km-commercial
Table 3-168 40Gbps(4*10.3)-QSFP+-SMF-1271~1331nm-10km-commercial
specifications
Item Value
Basic Information
Module name 40Gbps(4*10.3)-QSFP+-
SMF-1271~1331nm-10km-commercial
Part Number 02310WUT
Model OMXD30009
Form factor QSFP+
Application standard IEEE 802.3ba, 40GBASE-LR4
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8436
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 41.25 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1271 nm
1291 nm
1311 nm
1331 nm
Tx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
1284.5 nm - 1297.5 nm
1304.5 nm - 1317.5 nm
1324.5 nm - 1337.5 nm
Maximum Tx optical power (AVG) per lane: 2.3 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 3.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -7 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -4 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
1284.5 nm - 1297.5 nm
1304.5 nm - 1317.5 nm
1324.5 nm - 1337.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -11.5 dBm
Overload power (AVG) [dBm] per lane: 2.3 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value.
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3.4.17.2 40Gbps(4*10.3)-QSFP+-MMF-850nm-0.1km-commercial
Table 3-169 40Gbps(4*10.3)-QSFP+-MMF-850nm-0.1km-commercial
specifications
Item Value
Basic Information
Module name 40Gbps(4*10.3)-QSFP+-
MMF-850nm-0.1km-commercial
Part Number 02310WUU
Model OMXD30010
Form factor QSFP+
Application standard IEEE 802.3ba, 40GBASE-SR4
Connector type MPO-12
Optical fiber type MMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8436
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 41.25 Gbit/s
Target transmission distance [km] 0.1 km(OM3)
0.15 km(OM4)
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) per lane: 0.5 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 3 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -7.6 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -5.6 dBm
[dBm]
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Minimum extinction ratio [dB] 3 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -9.5 dBm
Overload power (AVG) [dBm] per lane: 0.5 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value.
3.4.17.3 40Gbps(4*10.3)-QSFP+-SMF-1310nm-10km-commercial
Table 3-170 40Gbps(4*10.3)-QSFP+-SMF-1310nm-10km-commercial
specifications
Item Value
Basic Information
Module name 40Gbps(4*10.3)-QSFP+-
SMF-1310nm-10km-commercial
Part Number 02311NUA
Model OSM010N11
Form factor QSFP+
Application standard IEEE 802.3ba, 40GBASE-LR4
Connector type MPO-12
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8436
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 4x9.95328 Gbit/s
4x10.3125 Gbit/s
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Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1260 nm - 1355 nm
Maximum Tx optical power (AVG) per lane: 0.5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) per lane: -8.2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1260 nm - 1355 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -12.6 dBm
Overload power (AVG) [dBm] per lane: 0.5 dBm
Overload power (OMA) [dBm] -
3.4.17.4 QSFP-40G-LX4-MM
Table 3-171 QSFP-40G-LX4-MM specifications
Item Value
Basic Information
Module name QSFP-40G-LX4-MM
Part Number 02314MWG
Model OMMD15N01
Form factor QSFP+
Application standard 40GBASE-LX4
Connector type LC
Optical fiber type MMF
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Item Value
Working case temperature [°C(°F)] 0°C to 70°C (32°F to 158°F)
Transmission rate [bit/s] 40Gbit/s
Target transmission distance [km] 150m
Transmitter Optical Characteristics
Center wavelength [nm] 1271nm,1291nm,1311nm,1331nm
Maximum Tx optical power (AVG) 3.5 dBm
[dBm]
Minimum Tx optical power (OMA) -4.0 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx sensitivity (OMA) [dBm] -10.5 dBm
Overload power (AVG) [dBm] 3.5 dBm
NOTE
Application limitations:
- In actual applications, the number of conversion connectors for the optical fiber link
cannot exceed 4.
- This module is sensitive to fiber link contamination. During deployment, ensure that the
fiber endface meets the fiber application standard. For details, see the single-mode
connector requirements under the ceramic ferrule endface requirements of fibers in section
"Cable -Optical Jumper."
3.4.18 50Gbps QSFP28 Optical Module
3.4.18.1 50Gbps-QSFP28-SMF-1311nm-10km-commercial
Table 3-172 50Gbps-QSFP28-SMF-1311nm-10km-commercial specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1311nm-10km-
commercial
Part Number 02311YNR
Model OSL010N01
Form factor QSFP28
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Item Value
Application standard IEEE 802.3cd, 50GBASE-LR
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
CE Class B
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1311 nm
Tx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Maximum Tx optical power (AVG) 4.2 dBm
[dBm]
Maximum Tx optical power (OMA) 4 dBm
[dBm]
Minimum Tx optical power (AVG) -4.5 dBm
[dBm]
Minimum Tx optical power (OMA) -1.5 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Rx sensitivity (AVG) [dBm] -8.9 dBm
Rx sensitivity (OMA) [dBm] -8.9 dBm
Overload power (AVG) [dBm] 4.2 dBm
Overload power (OMA) [dBm] -
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NOTE
1. The optical power calculation is based on the OMA value. If the module needs to reach
the nominal data, the board FEC function must be enabled.
2. The optical power read by the device is the average optical power, not the OMA optical
power.
3. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.18.2 50Gbps-QSFP28-SMF-1311nm-40km-commercial
Table 3-173 50Gbps-QSFP28-SMF-1311nm-40km-commercial specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1311nm-40km-
commercial
Part Number 02312AXF
Model QSFP28-50G-1311nm-40km-SM
Form factor QSFP28
Application standard IEEE 802.3cd, 50GBASE-ER
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
CE Class B
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1311 nm
Tx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
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Maximum Tx optical power (AVG) 8 dBm
[dBm]
Maximum Tx optical power (OMA) 9 dBm
[dBm]
Minimum Tx optical power (AVG) 1.5 dBm
[dBm]
Minimum Tx optical power (OMA) 4.5 dBm
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -15 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value.
If the module needs to reach the nominal data, the board FEC function must be enabled.
1. To keep the optical module running stably for a long time, set the receive optical power
less than -4 dBm. (According to IEEE 802.3, if the receive optical power exceeds -2.3 dBm,
the optical module may be permanently damaged.)
2. Before connecting the optical module, you are advised to use the optical power meter to
measure the receive optical power (P). If P is less than -4 dBm, the optical module can be
directly connected. If P is greater than -4 dBm, add an appropriate attenuator at the receive
end to ensure that P is less than -4 dBm. Alternatively, add an appropriate attenuator (the
recommended value is no less than 10 dB) before the optical module is connected, and
then adjust the attenuator according to the actual situation to prevent the module from
being damaged.
3. If the pigtail loopback or short-distance connection of the optical module is used, the
attenuator must be added. It is recommended that the attenuator be greater than or equal
to 10 dB.
4. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.18.3 50Gbps-QSFP28-SMF-1295.56~1300.05nm-80km-commercial
Table 3-174 50Gbps-QSFP28-SMF-1295.56~1300.05nm-80km-commercial
specifications
Item Value
Basic Information
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Item Value
Module name 50Gbps-QSFP28-
SMF-1295.56~1300.05nm-80km-
commercial
Part Number 02312MLF
Model QSFP28-50G-1310nm-80km-SM
Form factor QSFP28
Application standard Huawei Define
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 51.5625 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
Maximum Tx optical power (AVG) per lane: 6.5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) per lane: 2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
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Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
Rx sensitivity (AVG) [dBm] per lane: -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] per lane: -3.5 dBm
Overload power (OMA) [dBm] -
NOTE
1. The optical power is subject to the OMA. To achieve the nominal optical power, the FEC
function must be enabled on the board and G.652 fibers must be used.
2. The optical power of the optical module read on the device is the average optical power,
not the OMA optical power.
3. This module can be connected only to optical modules with the same BOM number.
3.4.19 50Gbps QSFP28 BIDI Optical Module
3.4.19.1 50Gbps-QSFP28-SMF-1331nm(Tx)/1271nm(Rx)-10km-commercial
Table 3-175 50Gbps-QSFP28-SMF-1331nm(Tx)/1271nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1331nm(Tx)/
1271nm(Rx)-10km-commercial
Part Number 02312EVV
Model QSFP28-50G-BIDI-10km-SM-1
Form factor QSFP28
Application standard IEEE 802.3bm-2015, 50GBASE-BR10
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(after FEC)
<2x10E-4(before FEC)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
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Item Value
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1331 nm
Tx operating wavelength range [nm] 1324.5 nm - 1337.5 nm
Maximum Tx optical power (AVG) 4.2 dBm
[dBm]
Maximum Tx optical power (OMA) 4 dBm
[dBm]
Minimum Tx optical power (AVG) -4.5 dBm
[dBm]
Minimum Tx optical power (OMA) -1.5 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -8.9 dBm
Overload power (AVG) [dBm] 4.2 dBm
Overload power (OMA) [dBm] -
NOTE
1. The optical power calculation is based on the OMA value. If the module needs to reach
the nominal data, the board FEC function must be enabled.
2. The optical power read by the device is the average optical power, not the OMA optical
power.
3. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
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3.4.19.2 50Gbps-QSFP28-SMF-1271nm(Tx)/1331nm(Rx)-10km-commercial
Table 3-176 50Gbps-QSFP28-SMF-1271nm(Tx)/1331nm(Rx)-10km-commercial
specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1271nm(Tx)/
1331nm(Rx)-10km-commercial
Part Number 02312EVW
Model QSFP28-50G-BIDI-10km-SM-2
Form factor QSFP28
Application standard IEEE 802.3bm-2015, 50GBASE-BR10
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(after FEC)
<2x10E-4(before FEC)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1271 nm
Tx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
Maximum Tx optical power (AVG) 4.2 dBm
[dBm]
Maximum Tx optical power (OMA) 4 dBm
[dBm]
Minimum Tx optical power (AVG) -4.5 dBm
[dBm]
Minimum Tx optical power (OMA) -1.5 dBm
[dBm]
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Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1324.5 nm - 1337.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] -8.9 dBm
Overload power (AVG) [dBm] 4.2 dBm
Overload power (OMA) [dBm] -
NOTE
1. The optical power calculation is based on the OMA value. If the module needs to reach
the nominal data, the board FEC function must be enabled.
2. The optical power read by the device is the average optical power, not the OMA optical
power.
3. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.19.3 50Gbps-QSFP28-SMF-1295nm(Tx)/1309nm(Rx)-40km-commercial
Table 3-177 50Gbps-QSFP28-SMF-1295nm(Tx)/1309nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1295nm(Tx)/
1309nm(Rx)-40km-commercial
Part Number 02312EVX
Model QSFP28-50G-BIDI-40km-SM-2
Form factor QSFP28
Application standard IEEE 802.3bm-2015, 50GBASE-BR40
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(after FEC)
<2x10E-4(before FEC)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
Maximum Tx optical power (AVG) 8 dBm
[dBm]
Maximum Tx optical power (OMA) 9 dBm
[dBm]
Minimum Tx optical power (AVG) 1.5 dBm
[dBm]
Minimum Tx optical power (OMA) 4.5 dBm
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] -15 dBm
Rx sensitivity (OMA) [dBm] -13.5 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
The optical power calculation is based on the OMA value. If the module needs to reach the
nominal data, the board FEC function must be enabled.
The optical power read by the device is the average optical power, not the OMA optical
power.
1. To keep the optical module running stably for a long time, set the receive optical power
less than -4 dBm. (According to IEEE 802.3, if the receive optical power exceeds -2.3 dBm,
the optical module may be permanently damaged.)
2. Before connecting the optical module, you are advised to use the optical power meter to
measure the receive optical power (P). If P is less than -4 dBm, the optical module can be
directly connected. If P is greater than -4 dBm, add an appropriate attenuator at the receive
end to ensure that P is less than -4 dBm. Alternatively, add an appropriate attenuator (the
recommended value is no less than 10 dB) before the optical module is connected, and
then adjust the attenuator according to the actual situation to prevent the module from
being damaged.
3. If the pigtail loopback or short-distance connection of the optical module is used, the
attenuator must be added. It is recommended that the attenuator be greater than or equal
to 10 dB.
4. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.19.4 50Gbps-QSFP28-SMF-1309nm(Tx)/1295nm(Rx)-40km-commercial
Table 3-178 50Gbps-QSFP28-SMF-1309nm(Tx)/1295nm(Rx)-40km-commercial
specifications
Item Value
Basic Information
Module name 50Gbps-QSFP28-SMF-1309nm(Tx)/
1295nm(Rx)-40km-commercial
Part Number 02312EVY
Model QSFP28-50G-BIDI-40km-SM-1
Form factor QSFP28
Application standard IEEE 802.3bm-2015, 50GBASE-BR40
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12(after FEC)
<2x10E-4(before FEC)
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
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Item Value
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 53.125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1309 nm
Tx operating wavelength range [nm] 1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) 8 dBm
[dBm]
Maximum Tx optical power (OMA) 9 dBm
[dBm]
Minimum Tx optical power (AVG) 1.5 dBm
[dBm]
Minimum Tx optical power (OMA) 4.5 dBm
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
Rx sensitivity (AVG) [dBm] -15 dBm
Rx sensitivity (OMA) [dBm] -13.5 dBm
Overload power (AVG) [dBm] -3 dBm
Overload power (OMA) [dBm] -
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Item Value
NOTE
The optical power calculation is based on the OMA value. If the module needs to reach the
nominal data, the board FEC function must be enabled.
The optical power read by the device is the average optical power, not the OMA optical
power.
1. To keep the optical module running stably for a long time, set the receive optical power
less than -4 dBm. (According to IEEE 802.3, if the receive optical power exceeds -2.3 dBm,
the optical module may be permanently damaged.)
2. Before connecting the optical module, you are advised to use the optical power meter to
measure the receive optical power (P). If P is less than -4 dBm, the optical module can be
directly connected. If P is greater than -4 dBm, add an appropriate attenuator at the receive
end to ensure that P is less than -4 dBm. Alternatively, add an appropriate attenuator (the
recommended value is no less than 10 dB) before the optical module is connected, and
then adjust the attenuator according to the actual situation to prevent the module from
being damaged.
3. If the pigtail loopback or short-distance connection of the optical module is used, the
attenuator must be added. It is recommended that the attenuator be greater than or equal
to 10 dB.
4. When this type of optical module is used to interconnect with a WDM device, the 1+1
protection switching duration on the client side of the WDM device is longer than 50 ms.
3.4.20 100Gbps QSFP28 Optical Module
3.4.20.1 100Gbps(4*25.7)-QSFP28-MMF-850nm-0.1km-commercial
Table 3-179 100Gbps(4*25.7)-QSFP28-MMF-850nm-0.1km-commercial
specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
MMF-850nm-0.1km-commercial
Part Number 02311NTY
Model OMND10N13
Form factor QSFP28
Application standard IEEE 802.3bm, 100GBASE-SR4
Connector type MPO-12
Optical fiber type MMF
Bit error ratio (BER) <5x10E-5
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
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DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 0.07 km(OM3)
0.1 km(OM4)
Transmitter Optical Characteristics
Center wavelength [nm] 850 nm
Tx operating wavelength range [nm] 840 nm - 860 nm
Maximum Tx optical power (AVG) per lane: 2.4 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 3 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -8.4 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -6.4 dBm
[dBm]
Minimum extinction ratio [dB] 2 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 840 nm - 860 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -10.3 dBm
Overload power (AVG) [dBm] per lane: 2.4 dBm
Overload power (OMA) [dBm] -
NOTE
1. If the module needs to reach the nominal data, the board FEC function must be enabled.
2. The BER 5x10E - 5 is the data that is not enabled by FEC, so that 1x10E - 12 can be
reached after FEC .
3. The optical power calculation is based on the OMA value. The optical power read by the
device is the average optical power, not the OMA optical power.
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3.4.20.2 100Gbps(4*25.7)-QSFP28-SMF-1271~1331nm-2km-commercial
Table 3-180 100Gbps(4*25.7)-QSFP28-SMF-1271~1331nm-2km-commercial
specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1271~1331nm-2km-commercial
Part Number 02311QDH
Model OSN020N15
Form factor QSFP28
Application standard 100G CWDM4 MSA
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 2 km
Transmitter Optical Characteristics
Center wavelength [nm] 1271 nm
1291 nm
1311 nm
1331 nm
Tx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
1284.5 nm - 1297.5 nm
1304.5 nm - 1317.5 nm
1324.5 nm - 1337.5 nm
Maximum Tx optical power (AVG) per lane: 2.5 dBm
[dBm]
Maximum Tx optical power (OMA) -
[dBm]
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Minimum Tx optical power (AVG) per lane: -6.5 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 3.5 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1264.5 nm - 1277.5 nm
1284.5 nm - 1297.5 nm
1304.5 nm - 1317.5 nm
1324.5 nm - 1337.5 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -10 dBm
Overload power (AVG) [dBm] per lane: 2.5 dBm
Overload power (OMA) [dBm] -
NOTE
1. If the module needs to reach the nominal data, the board FEC function must be enabled.
2. The BER 5x10E - 5 is the data that is not enabled by FEC, so that 1x10E - 12 can be
reached after FEC .
3.4.20.3 100Gbps(4*25.7)-QSFP28-SMF-1310nm-30km(NO FEC)-40km(FEC)-
commercial
Table 3-181 100Gbps(4*25.7)-QSFP28-SMF-1310nm-30km(NO FEC)-40km(FEC)-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1310nm-30km(NO
FEC)-40km(FEC)-commercial
Part Number 02312AUE
Model OSN030N05
Form factor QSFP28
Application standard IEEE 802.3ba, 100GBASE-ER4
Connector type LC
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Item Value
Optical fiber type SMF
Bit error ratio (BER) <5x10E-5
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 40 km(FEC)
30 km(NO FEC)
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 2.9 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 4.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -2.5 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: 0.1 dBm
[dBm]
Minimum extinction ratio [dB] 8 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] -
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Item Value
Rx sensitivity (OMA) [dBm] per lane: -21.4 dBm
Overload power (AVG) [dBm] per lane: -3.5 dBm
Overload power (OMA) [dBm] -
NOTE
1. If the module needs to reach 40 km, the board FEC function must be enabled. Otherwise,
it can reach only 30 km.
2. The BER 5x10E - 5 is the data obtained with FEC not enabled. After FEC is enabled, 1x10E
- 12 can be reached.
3. In 30 km application, the BER can reach 1x10E - 12.
4. The optical power calculation is based on the OMA value. The optical power read by the
device is the average value, not the OMA optical power.
3.4.20.4 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-
commercial (02312BSS)
Table 3-182 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1295.56~1309.14nm-10km-
commercial
Part Number 02312BSS
Model OSN010N24
Form factor QSFP28
Application standard IEEE 802.3ba, 100GBASE-LR4
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 500 V
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Item Value
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 4.5 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 4.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -4.3 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -1.3 dBm
[dBm]
Minimum extinction ratio [dB] 4 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -8.6 dBm
Overload power (AVG) [dBm] per lane: 4.5 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value. The optical power read by the
device is the average optical power, not the OMA optical power.
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3.4.20.5 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-80km-
commercial
Table 3-183 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-80km-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1295.56~1309.14nm-80km-
commercial
Part Number 02312NCX
Model QSFP28-100G-1310-80km-SM
Form factor QSFP28
Application standard Huawei Define
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 80 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 6.5 dBm
[dBm]
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Item Value
Maximum Tx optical power (OMA) -
[dBm]
Minimum Tx optical power (AVG) per lane: 2 dBm
[dBm]
Minimum Tx optical power (OMA) -
[dBm]
Minimum extinction ratio [dB] 6 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] per lane: -28 dBm
Rx sensitivity (OMA) [dBm] -
Overload power (AVG) [dBm] per lane: -3.5 dBm
Overload power (OMA) [dBm] -
NOTE
1. To achieve the nominal value, the FEC function must be enabled on the board and G.652
fibers must be used.
2. The BER 5x10E-5 is the data when FEC is disabled. After FEC is enabled, the BER can
reach 1x10E-12.
3. When the optical module is used for 80 km transmission, it must be interconnected with
Huawei optical modules of the same model.
3.4.20.6 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-40km-
commercial
Table 3-184 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-40km-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1295.56~1309.14nm-40km-
commercial
Part Number 02312NVQ
Model QSFP28-100G-1310-40km-SM
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Item Value
Form factor QSFP28
Application standard IEEE 802.3 100GBASE-ER4
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 40 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 2.9 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 4.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -2.9 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: 0.1 dBm
[dBm]
Minimum extinction ratio [dB] 8 dB
Receiver Optical Characteristics
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Item Value
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] per lane: -20.9 dBm
Rx sensitivity (OMA) [dBm] per lane: -21.4 dBm
Overload power (AVG) [dBm] per lane: -3.5 dBm
Overload power (OMA) [dBm] -
NOTE
When an optical module is installed on an interface, the FEC function on the interface is
disabled by default. Pay attention to the FEC status of the peer interface during
interconnection.
3.4.20.7 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-
commercial (02313SWA)
Table 3-185 100Gbps(4*25.7)-QSFP28-SMF-1295.56~1309.14nm-10km-
commercial specifications
Item Value
Basic Information
Module name 100Gbps(4*25.7)-QSFP28-
SMF-1295.56~1309.14nm-10km-
commercial
Part Number 02313SWA
Model OSN010N24
Form factor QSFP28
Application standard IEEE 802.3ba, 100GBASE-LR4
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-12
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
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Item Value
ESD(HBM1) [V] 500 V
Transmission rate [bit/s] 103.125 Gbit/s
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1295.56 nm
1300.05 nm
1304.58 nm
1309.14 nm
Tx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Maximum Tx optical power (AVG) per lane: 4.5 dBm
[dBm]
Maximum Tx optical power (OMA) per lane: 4.5 dBm
[dBm]
Minimum Tx optical power (AVG) per lane: -4.3 dBm
[dBm]
Minimum Tx optical power (OMA) per lane: -1.3 dBm
[dBm]
Minimum extinction ratio [dB] 4 dB
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1294.53 nm - 1296.59 nm
1299.02 nm - 1301.09 nm
1303.54 nm - 1305.63 nm
1308.09 nm - 1310.19 nm
Rx sensitivity (AVG) [dBm] -
Rx sensitivity (OMA) [dBm] per lane: -8.6 dBm
Overload power (AVG) [dBm] per lane: 4.5 dBm
Overload power (OMA) [dBm] -
NOTE
The optical power calculation is based on the OMA value. The optical power read by the
device is the average optical power, not the OMA optical power.
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3.4.20.8 100Gbps-QSFP28-1310nm-10km-commercial
Table 3-186 100Gbps-QSFP28-1310nm-10km-commercial specifications
Item Value
Basic Information
Module name 100Gbps-QSFP28-1310nm-10km-
commercial
Part Number 02314GYE
Model OSN010N22
Form factor QSFP28
Application standard IEEE 802.3cd, 100GBASE-LR1
Connector type LC
Optical fiber type SMF
Bit error ratio (BER) <1x10E-4
Working case temperature [°C(°F)] 0°C to 70°C(32°F to 158°F)
DDM options SFF-8636
Environment standard RoHS
Security standard FCC Class B, IEC 60825-1 Class 1
CE Class B
ESD(HBM1) [V] 1000 V
Transmission rate [bit/s] 106.25 Gbit/s(PAM4)
Target transmission distance [km] 10 km
Transmitter Optical Characteristics
Center wavelength [nm] 1310 nm
Tx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Maximum Tx optical power (AVG) 4.8 dBm
[dBm]
Maximum Tx optical power (OMA) 4.8 dBm
[dBm]
Minimum Tx optical power (AVG) -1.9 dBm
[dBm]
Minimum Tx optical power (OMA) -1.9 dBm
[dBm]
Minimum extinction ratio [dB] 3.5 dB
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Item Value
Receiver Optical Characteristics
Rx operating wavelength range [nm] 1304.5 nm - 1317.5 nm
Rx sensitivity (AVG) [dBm] -6.1 dBm
Rx sensitivity (OMA) [dBm] -6.1 dBm
Overload power (AVG) [dBm] 4.8 dBm
Overload power (OMA) [dBm] -
NOTE
1. The optical power is subject to the OMA optical power. To reach the nominal value, the
FEC function of the optical module must be enabled.
2. The optical power of an optical module displayed on the device is the average optical
power, not the OMA optical power.
3. When this type of optical module is used to interconnect with WDM equipment, the
WDM client-side 1+1 protection switching time is greater than 50 ms.
3.5 Cables
3.5.1 NetEngine 8000 F1A-8H20Q Power Cable
This section describes the structure and technical specifications of the power cable.
3.5.1.1 DC Power Cable
This section describes the structure and technical specifications of the DC power
cable.
NO TICE
Cables are delivered according to default configurations. If there are special
requirements, purchase cables locally.
If the power distribution frame (PDF) is more than 25 m away from a device,
install a PDF as close as possible to the device.
Overview
The DC power cable connects a device to the power module to supply power to
the device.
NO TE
The following cable colors are for reference only. The actual cable colors depend on the
requirements of the target country or customer.
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Appearance
Figure 3-29 DC power cable
Figure 3-30 DC power connector
Figure 3-31 OT terminal
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Hardware Guide 3 Hardware Description
Figure 3-32 Heat-shrink tubing
Technical Specifications
Table 3-187 Specifications of the DC power cable
Dis Part Mo Description Co Co Ca Nu Fireproof
tan Num del nn nn bl mb Level
ce ber ect ec e er
fro or to Le of
m 1 r 2 ng Co
the th res
PD
F
to
the
De
vic
e
Sho 2503 - Electronic|Electric - - - - IEC
rter 0701 Cable,450V/750V,H07Z- 60332-1,
tha K VM-1, Dca-
n UL3386,4mm^2,Blue,45 s2a2d2
or A,LSZH Cable,VDE,UL
equ
al 2503 - Electronic|Electric - - - - IEC
to 0700 Cable,450V/750V,H07Z- 60332-1,
15 K VM-1, Dca-
m UL3386,4mm^2,Black,4 s2a2d2
5A,LSZH Cable,VDE,UL
2503 - Electronic|Electric - - - - IEC
0735 Cable,450V/750V,H07Z- 60332-1,
K VM-1, Dca-
UL3386,4mm^2,Gray,45 s2a2d2
A,LSZH Cable,VDE,UL
2503 - Electronic|Electric - - - - IEC
0730 Cable,450V/750V,H07Z- 60332-1,
K VM-1, Dca-
UL3386,4mm^2,Red,45 s2a2d2
A,LSZH Cable,VDE,UL
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Dis Part Mo Description Co Co Ca Nu Fireproof
tan Num del nn nn bl mb Level
ce ber ect ec e er
fro or to Le of
m 1 r 2 ng Co
the th res
PD
F
to
the
De
vic
e
2503 - Electronic|Electric - - - - IEC
2787 Cable,1100V,Y(FR- 60332-1,
-001 LSH),4mm^2,Blue,45A,F IEC
or India,BIS 60332-3-22
2503 - Electronic|Electric - - - - IEC
2787 Cable,1100V,Y(FR- 60332-1,
LSH),4mm^2,Black,45A, IEC
For India,BIS 60332-3-22
Lon 2503 - Electronic|Electric - - - - IEC
ger 0697 Cable,450V/750V,H07Z- 60332-1,
tha K VM-1, Dca-
n UL3386,6mm^2,Blue,58 s2a2d2
15 A,LSZH Cable,VDE,UL
m
but 2503 - Electronic|Electric - - - - IEC
sho 0703 Cable,450V/750V,H07Z- 60332-1,
rter K VM-1, Dca-
tha UL3386,6mm^2,Black,5 s2a2d2
n 8A,LSZH Cable,VDE,UL
or 2503 - Electronic|Electric - - - - IEC
equ 0717 Cable,450V/750V,H07Z- 60332-1,
al K VM-1, Dca-
to UL3386,6mm^2,Gray,58 s2a2d2
25 A,LSZH Cable,VDE,UL
m
2503 - Electronic|Electric - - - - IEC
0731 Cable,450V/750V,H07Z- 60332-1,
K VM-1, Dca-
UL3386,6mm^2,Red,58 s2a2d2
A,LSZH Cable,VDE,UL
2503 - Electronic|Electric - - - - IEC
2788 Cable,1100V,Y(FR- 60332-1,
-001 LSH),6mm^2,Blue,58A,F IEC
or India,BIS 60332-3-22
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Dis Part Mo Description Co Co Ca Nu Fireproof
tan Num del nn nn bl mb Level
ce ber ect ec e er
fro or to Le of
m 1 r 2 ng Co
the th res
PD
F
to
the
De
vic
e
2503 - Electronic|Electric - - - - IEC
2788 Cable,1100V,Y(FR- 60332-1,
LSH),6mm^2,Black,58A, IEC
For India,BIS 60332-3-22
Table 3-188 Specifications of the DC power connector
Part Mode Description Terminal Type
Nu l
mbe
r
1419 - Easy Power -
1175 Connector,2Pin,48V,40A,Straight
female,1.5mm^2~10mm^2,Small-
sized Easy Power,with pull ring
Table 3-189 Specifications of ground cables
Par Mod Description Conn Conn Cab Nu Fireproof
t el ector ector le m Level
Nu 1 2 Len be
mb gth r
er of
Co
res
250 - Electronic|Electric OT OT 15 - IEC
306 Cable,450V/750V,H07Z-K termi termi m 60332-1,
99 UL3386,6mm^2,Yellow/ nal nal VM-1,
Green,58A,LSZH Dca-
Cable,VDE,UL s2a2d2
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Hardware Guide 3 Hardware Description
Par Mod Description Conn Conn Cab Nu Fireproof
t el ector ector le m Level
Nu 1 2 Len be
mb gth r
er of
Co
res
250 - Electronic|Electric OT OT 15 - IEC
327 Cable,1100V,Y(FR- termi termi m 60332-1,
88- LSH),6mm^2,Yellow/ nal nal IEC
002 Green,58A,For India,BIS 60332-3-
22
Table 3-190 Specifications of ground cable terminals
Part Mode Description Terminal Type
Nu l
mbe
r
0223 - Package of Terminal for Naked Crimping
2UD Single Input 6mm^2 Terminal,OT,6mm^2,M4,Tin
U Grounding Cable(Include Plating,Insulated Ring
Backup) Terminal,12~10AWG,yellow
Naked Crimping
Connector,OT2,6mm^2,M4,Tin
Plating
Naked Crimping
Terminal,OT,6mm^2,M8,Tin
Plating,Insulated Ring
Terminal,12~10AWG,yellow
Naked Crimping
Terminal,OT,6mm^2,M6,Tin
Plating,Insulated Ring
Terminal,12~10AWG,yellow
3.5.1.2 AC Power Cable
This section describes the structure and technical specifications of the AC-input
power cable.
NO TICE
If no special requirements are imposed on power cables, power cables are
delivered according to default configurations. Otherwise, power cables need to be
purchased locally.
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Hardware Guide 3 Hardware Description
Overview
An AC power cable is used to connect to the AC power module of a device to
supply power to the device.
NO TE
Cables must be in compliance with standards of the destination country or region. The
actual cable type depends on the requirements of the target country or customer.
Appearance
Figure 3-33 Connector C13 (PDU)
Figure 3-34 Connector C13 (wall-mounted)
Figure 3-35 Heat shrink tubing
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Technical Specifications
Table 3-191 Technical specifications of AC power cables in different countries or
regions (PDU)
Part Description Connecto Conne Leng Numb
Num r X1 ctor th er of
ber X2 Cores
0405 Power Cords Cable,China AC C14SM C13SF 1.5 m 3
0188 Power cores
250V10A,1.5m,C14SM,227IEC53(
RVV)1.0mm2(3C),C13SF,PDU
Cable
0405 Power Cords Cable,Europe AC C14SM C13SF 1.8 m 3
G019 250V10A,1.8m,C14SM,H05VV-F- cores
3*1.00mm2,C13SF,PDU Cable
0405 Power cord,Europe AC C14SM C13SF 3 m 3
G019 250V10A,3.0m,C14SM,H05VV-F- cores
-002 3*1.00^2,C13SF,250V,10A,PDU
Cable
0405 Power Cords Cable,North C14SM C13SF 1.8 m 3
G029 America AC Power cores
250V10A,1.8m,C14SM,SJT
18AWG(3C),C13SF,PDU Cable
0405 Power Cords Cable,Japan AC C14SM C13SF 1.8 m 3
G02D Power cores
250V12A,1.8m,C14SM,HVCTF
1.25mm2(3C),C13SF,PDU Cable
0405 Power Cords Cable,Australia AC C14SM C13SF 1.8 m 3
G02F Power cores
250V10A,1.8m,C14SM,H05VV-
F-1.0mm2(3C),C13SF,PDU Cable
0405 Power Cords Cable,Korea AC C14SM C13SF 1.8 m 3
G02H Power cores
250V10A,1.8m,C14SM,H05VV-
F-1.0mm2(3C),C13SF,PDU Cable
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Table 3-192 Technical specifications of AC power cables in different countries or
regions (wall-mounted)
Part Description Connecto Conne Leng Numb
Num r X1 ctor th er of
ber X2 Cores
0404 Power Cords Cable,China AC PISM C13SF 3m 3
1104 Power cores
250V10A,3.0m,PISM,227IEC53-1.0
mm2(3C),C13SF,Black
0402 Power Cable,America AC Power PBSM C13SF 3m 3
0728 Cable,125V10A,3.0m,PBSM,18SJ cores
T(3C),C13SF,Black
0404 Power cord,Europe AC Power PFSM C13SF 3m 3
1056 Cable,250V10A,3.0m,PFSM, cores
(H05VVF
1.0mm2(3C)),C13SF,250V,10A,BLa
ck
0404 Power Cable,Britain AC Power PGAM C13SF 3m 3
0890 Cable cores
250V10A,3.0m,PGAM ,H05VV-
F-1.0mm2(3C),C13SF,Black
0404 Power Cable,Japan AC Power PBSM C13SF 3m 3
0887 Cable cores
125V12A,3.0m,PBSM,HVCTF-1.25
mm2(3C),C13SF,Black
0404 Power cord,BS546 PM-IAM C13SF 3m 3
0889 250V10A,3.0m,PM-IAM,H05VV- cores
F-1.5mm2(3C),C13SF,250V,10A,Bl
ack
0404 Power Cords Cable,Australia AC PISM C13SF 3m 3
0888 Power Cable,250V cores
10A,3.0m,PISM,H05VV-
F-1.0mm2(3C),C13SF,Black
0404 Power Cable,Switzerland AC PJSM C13SF 3m 3
1119 Power Cable cores
250V10A,3.0m,PJSM ,H05VV-
F-1.0mm2(3C),C13SF,Black
0404 Power Cable,Italy AC Power PLSM C13SF 3m 3
1120 Cable cores
250V10A,3.0m,PLSM,H05VV-
F-1.0mm2(3C),C13SF,Black
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Part Description Connecto Conne Leng Numb
Num r X1 ctor th er of
ber X2 Cores
0404 Power Cords Cable,Argentina AC PISM C13SF 3m 3
7785 Power cores
250V10A,3.0m,PISM,H05VV-
F-1.0mm2(3C),C13SF,Black
0415 Power Cable,Brazil AC Power PNSM C13SF 3m 3
0258 Cable cores
250V10A,3.0m,PNSM ,H05VV-
F-1.0mm2(3C),C13SF,Black
0405 Power Cords Cable,Korea AC PFSM C13SF 3m 3
G028 Power cores
250V10A,3m,PFSM,H05VV-F
3*1.0mm2(3C),C13SF,Black
0405 Power Cords Cable,Denmark AC PKSM C13SF 3m 3
G02K Power cores
250V10A,3m,PKSM,H05VV-
F-3*1.0mm2(3C),C13SF,Black
0405 Power Cords Cable,India AC PM-IIAM C13SF 3m 3
1035 Power 250V10A,3.0m,PM-IIAM,IS cores
694-1.0mm2(3C), C13
SF,250V,10A,Black
0405 Power cord,South Africa AC PMAM C13SF 3m 3
1080 Power cores
250V10A,3m,PMAM,H05VV-
F-1.0mm2(3C),C13SF,250V,10A,Bl
ack
0405 Power cord,Taiwan, China AC PBSM C13SF 3m 3
2137 125V11A,3.0m,PBSM,HVCTF cores
3*1.25mm2,C13SF,125V,11A,Black,
BSMI
3.5.2 Chassis Ground Cable
Overview
One end of a chassis ground cable is connected to the ground screw on the right-
side cabinet column, and the other end is connected to the ground screw on the
chassis.
Appearance
Figure1 shows the appearance of chassis ground cable.
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Hardware Guide 3 Hardware Description
Figure 3-36 Appearance of chassis ground cable.
1. OT one-hole naked crimping connector
Connection
A ground cable grounds a device to protect it from lightning and electromagnetic
interference. A ground cable is connected to a chassis in the following way:
● The OT bare crimp terminal X1 connects to the ground point on the chassis.
● The OT bare crimp terminal X2 connects to the ground bar of the cabinet.
Technical Specifications
Table 3-193 Technical specifications of chassis ground cable
Dev Part Mo Description Con Connec Le Fire
ice Nu del nec tor X2 ngt Rating
Mo mb tor h
del er X1
Net 250 - Electronic|Electric OT OT 15 IEC
Engi 306 Cable,450V/750V,H07Z-K Ter Termina m 60332-
ne 99 UL3386,6mm^2,Yellow/ min l 1,
800 Green,58A,LSZH al VM-1
0 Cable,VDE,UL
F1A
-8H
20Q
3.5.3 Standard Serial Cable
This section describes the structure and technical specifications of the standard
serial cable.
Introduction
One end of the standard serial cable is a DB9 connector that is connected to the
serial port of a computer, and the other end is an RJ45 connector that is
connected to the standard console port of a router.
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Appearance
Figure 3-37 shows the structure of a standard serial cable, and Table 3-194
describes the cable connections.
Figure 3-37 Standard serial cable (04040838 - Single Cable,Serial
Cable,3m,D9F,CC2P0.32PWG1U,MP8-VI,S3026V)
1 DB9 female 2 Network interface RJ45 W communication cable
Table 3-194 Connections of the standard serial cable
Start Point End Point Color
X1.2 X2.3 Black
X1.3 X2.6 Brown
X1.5 X2.5 Red
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Technical Specifications
Table 3-195 Technical specifications of a standard serial cable and a serial adapter
cable
Par Mod Description Connect Connector Cable Le Nu Fir
t el or X1 X2 Type ng mb e
Nu th er Rat
mb of ing
er Co
res
040 - Single D9F MP8-VI Twiste 3m 2 -
408 Cable,Serial d-Pair cor
38 Cable,3m,D9 Cable, es/
F,CC2P0.32P UL246 pai
WG1U,MP8- 4,0.32 r
VI,S3026V mm,28
AWG,2
Pairs,P
ANTO
NE
WARM
GRAY
1U
3.5.4 USB-to-Serial Cable
This section describes the structure and technical specifications of the USB-to-
serial cable.
Overview
The USB-to-serial cable uses a USB port to connect to a client device at one end
and uses two RJ45 connector-based serial ports (one standard and one non-
standard) to connect to a router at the other end. The pin assignments of the two
serial ports are different. For details, see Table 3-196.
Structure
Figure 3-38 Structure of the USB-to-serial cable
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Pin Assignments
Table 3-196 Pin assignments of the USB-to-serial cable
Wire Rela Core Cabl Start Conv End Cabl Core Rela Wire
No. tions Wire e Pin erter Pin e Wire tions No.
hip Colo Desc Desc Colo hip
r ripti ripti r
on on
W3- Twist Whit +5 V X1.1 USB- X2.6 RS23 Blue Twist W1-
Main ed e DC to- 2_RX ed Labe
Labe RS23 l 1
l Blue Data X1.2 2 X2.3 RS23 Whit (RS2
- conv 2_TX e 32)
Twist Oran Data X1.3 erter X2.5 GND Oran -
ed ge + ge
Whit GND X1.4 X3.5 RS23 Blue Twist W2-
e 2_RX ed Labe
l 2
- - - - - X3.8 RS23 Whit (Spe
2_TX e cial
- - - - - X3.4 GND Oran - RS23
ge 2)
Technical Specifications
Table 3-197 Technical specifications of the USB-to-serial cable
Part Description Connect Connect Cable
Number or X1 or X2 Length
0407185 Traditional Signal Cable,USB-to- USB-A MP8-II 1.5 m
1 Ethernet cable,1.5m,USB- (Male)
A(Male),CC2P0.48B(S),2*MP8-II
NO TICE
To use the USB-to-serial cable, you need to download the corresponding driver at
https://www.wch-ic.com/products/CH340.html? and configure the driver as
required.
3.5.5 Clock Cable (External Clock Mode, Delivery-Ready)
This section describes the structure and technical specifications of the clock cable.
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Introduction
The external clock cables can be connected to the CLK, and CLK/TOD interfaces on
a device.
Structure
The 120-ohm trunk cable adopts the RJ45 connector. Figure 3-39 shows the
structure of the 120-ohm trunk cable.
Figure 3-39 120-ohm trunk cable
Pin Assignment
Table 3-198 Pin assignments of the 120-ohm trunk cable
Connector X1 Connector X2 Color Relation
1 4 White Pair
2 5 Blue
3 6 Orange -
4 1 White Pair
5 2 Green
6 3 Brown -
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Technical Specifications
Table 3-199 Technical specifications of the 120-ohm trunk cable
Par Mo Description Co Co Cable Le Nu Fire
t del nne nn Type ng mb Ratin
Nu cto ect th er g
mb r or of
er X1 X2 Cor
es
040 - Trunk MP MP Twisted 3 2 IEC
404 Cable,3m,120ohm,1E1,0. 8-II 8-II -Pair m cor 60332
97 4mm,MP8- Cable,1 es/ -1
II,120CC4P0.4P430U(S), 20ohm, pair
MP8-II SEYVP,0
.4mm,2
040 - Trunk MP MP 6AWG, 15 2 IEC
402 Cable,15m,120ohm,1E1,0 8-II 8-II 4Pairs, m cor 60332
61 .4mm,MP8- Panton es/ -1
II,120CC4P0.4P430U(S), e 430U pair
MP8-II
3.5.6 Clock Cable (External Clock/External Time Mode,
Prepared Onsite)
Overview
A clock cable is used to connect the clock interface on a router to that on another
device. If equipped with only one main control board, a router can receive one-
channel 2 Mbit/s clock signals, one-channel 2 MHz clock signals, one-channel
DCLS time signals, or one-channel 1PPS+TOD time signals from the upstream
device and provides one-channel 2 Mbit/s clock signals, one-channel 2 MHz clock
signals, one-channel DCLS time signals, or one-channel 1PPS+TOD time signals to
the downstream device. If equipped with two main control boards, a router can
receive two-channel 2 Mbit/s clock signals, two-channel 2 MHz clock signals, two-
channel DCLS time signals, or two-channel 1PPS+TOD time signals from the
upstream device and provides two-channel 2 Mbit/s clock signals, two-channel 2
MHz clock signals, two-channel DCLS time signals, or two-channel 1PPS+TOD
time signals to the downstream device.
The clock cable features RJ45 connectors at both ends: one is used to connect to
the clock interface on the front panel of a main control board, and the other is
used to connect to the clock interface on an external device.
An RJ45 connector is used together with the 120-ohm trunk cable.
NO TE
The wire sequence of a trunk cable used as a clock cable differs from that of an ordinary
twisted pair cable.
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Appearance
The 120-ohm clock cable uses the RJ45 connector. The following figure shows the
cable structure.
Figure 3-40 Appearance of the 120-ohm clock cable connector
Pin Assignments
Table 3-200 Pin assignments of the 120-ohm clock cable
Pin Rela Description
tion
ship External Clock External Time External Time Mode
Mode Mode (DCLS)
(1PPS + Time
Information)
X1.1 Twis Receive Not defined Not defined
ted negative for
CLK signals
X1.2 Receive positive Not defined Not defined
for CLK signals
X1.3 Twis Not defined Negative for IPPS Negative for DCLS
ted signals signals
X1.6 Not defined Positive for IPPS Positive for DCLS
signals signals
X1.4 Twis Transmit Ground end Ground end
ted negative for
CLK signals
X1.5 Transmit Ground end Ground end
positive for CLK
signals
X1.7 Twis Not defined Negative for time Not defined
ted information
X1.8 Not defined Positive for time Not defined
information
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Technical Specifications
Table 3-201 Technical specifications of the 120-ohm clock cable
Part Mod Description Con Connect Num Firepro
Nu el nect or X2 ber of
mbe or of Level
r X1 Core
s
1408 - Network Interface - - - -
0097 Connector,8-Bit
8PIN,Shielded,Crystal Model
Connector,24-26AWG,Leads
Single Solide Cable,For OEM
Matching 25050057
2505 - Twisted-Pair - - 2 IEC603
0057 Cable,100ohm,Category cores 32-1
5e,FTP,0.52mm,24AWG,8Core /pair
s,4Pairs,PANTONE 430U,Use
with Plug:14080097
3.5.7 Clock Bridging Cable
Overview
The clock bridging cable used by a device is the 120-ohm-to-75-ohm clock cable.
Structure
Figure 3-41 shows the structure of the 120-ohm-to-75-ohm clock cable.
Figure 3-41 Structure of a clock bridging cable
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Pin Assignments
Table 3-202 Pin assignments of clock bridging cables
120-ohm Cable 75-ohm
Cable
Connector Pin Core Wire Cable Relations Core Wire
Color Description hip No.
X1.1 Orange Receive Twisted W1
negative for the
120-ohm
external clock
X1.2 White Receive positive
for the 120-
ohm external
clock
X1.4 Blue Transmit Twisted W2
negative for the
120-ohm
external clock
X1.5 White Transmit
positive for the
120-ohm
external clock
X1.3 Green Not defined Twisted W3
X1.6 White Not defined
X1.7 White Not defined Twisted W4
X1.8 Brown Not defined
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Technical Specifications
Table 3-203 Technical specifications of a clock bridging cable
Part Mo Description Conn Con Cabl N Firepr
Nu del ector nect e u oof
mb X1 or Len m Level
er X2 gth be
r
of
C
or
es
040 T-1- Signal Cable,120ohm To MP8- - 30 - -
447 Sh- 75ohm Clock II m
26 RJ45 Cable,30m,MP8-II,
-30 (120CC4P0.4P430U(S)
+4*(SYV75-2/0.34(S))
3.5.8 Ethernet Cable
Overview
Ethernet cables are also known as network cables and can be classified into
straight-through cables and crossover cables according to the connection sequence
of the copper wire cores in the cables.
An Ethernet service interface can detect whether a straight-through or crossover
cable is plugged in, meaning it will work automatically with either cable type.
Therefore, you can choose either cable type as needed for your network setup.
NO TE
Ethernet cables need to be made onsite.
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Appearance
Figure 3-42 Appearance of the Ethernet cable
Pin Assignments
Table 3-204 Pin assignments of the straight-through cable
Connector X1 Pin Connector X2 Pin Color Relationship
X1.1 X2.1 White/Orange Twisted
X1.2 X2.2 Orange
X1.3 X2.3 White/Green Twisted
X1.6 X2.6 Green
X1.4 X2.4 Blue Twisted
X1.5 X2.5 White/Blue
X1.7 X2.7 White/Brown Twisted
X1.8 X2.8 Brown
Table 3-205 Pin assignments of the crossover cable
Connector X1 Pin Connector X2 Pin Color Relationship
X1.1 X2.3 White/Orange Twisted
X1.2 X2.6 Orange
X1.3 X2.1 White/Green Twisted
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Connector X1 Pin Connector X2 Pin Color Relationship
X1.6 X2.2 Green
X1.4 X2.4 Blue Twisted
X1.5 X2.5 White/Blue
X1.7 X2.7 White/Brown Twisted
X1.8 X2.8 Brown
Technical Specifications
Table 3-206 Technical specifications of the straight-through cable
Descr Twisted-Pair Cable,100ohm,Category
iptio 5e,FTP,0.52mm,24AWG,8Cores,4Pairs,PANTONE 430U
n
Conn Network Interface Connector,8PIN,8-Bit,Shielded,Crystal Plug,AWG24–
ector 26,Solid-Core Cable with Inner Conductor
X1
Conn Network Interface Connector,8PIN,8-Bit,Shielded,Crystal Plug,AWG24–
ector 26,Solid-Core Cable with Inner Conductor
X2
Cabl 1 m, 3 m, 5 m, 10 m, 20 m, 30 m
e
Leng
th
Inner 0.52 mm
Diam
eter
Num 2 cores/pair
ber
of
Cores
Table 3-207 Technical specifications of the crossover cable
Descr Twisted-Pair Cable,100ohm,Category
iptio 5e,FTP,0.52mm,24AWG,8Cores,4Pairs,PANTONE 430U
n
Conn Network Interface Connector,8PIN,8-Bit,Shielded,Crystal Plug,AWG24–
ector 26,Solid-Core Cable with Inner Conductor
X1
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Conn Network Interface Connector,8PIN,8-Bit,Shielded,Crystal Plug,AWG24–
ector 26,Solid-Core Cable with Inner Conductor
X2
Cabl 2 m, 3 m, 5 m, 10 m, 20 m, 30 m
e
Leng
th
Inner 0.52 mm
Diam
eter
Num 2 cores/pair
ber
of
Cores
3.5.9 Fiber Jumpers
Overview
A fiber jumper consists of one or more optical fibers of a certain length and the
optical connectors at both ends. A fiber jumper connects an optical module to a
fiber terminal box.
NO TE
The MPO-MPO optical fibers for routers use type B connectors (Key Up/Key Up).
Comply with the following rules when selecting fiber jumpers:
1. Determine the length of fiber jumpers based on the onsite cabling distance.
2. Determine the fiber type based on the optical module type.
– Use a multimode fiber jumper for a multimode optical module.
– Use a single-mode fiber jumper for a single-mode optical module.
3. Determine the optical connector type based on the port type.
Ensure that the optical connector at each end of a fiber jumper is of the same
type as the port to which it will be connected.
NO TICE
The optical transmission module of the multi-transverse mode needs to be
connected to the multimode fiber. The optical transmitting module of the single-
longitudinal mode or multi-longitudinal mode needs to be connected to the
single-mode fiber.
Optical Fibers
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Optical fibers are classified into single-mode fibers and multimode fibers.
● Single-mode fibers have a diameter of 5 to 10 μm and transmit laser in a
single mode with a specified wavelength. These fibers support a wide
frequency band and a large transmission capacity, so they are used for long-
distance transmission. Most single-mode fibers are yellow, as shown in Figure
3-44.
● Multimode fibers have a diameter of 50 or 62.5 μm and transmit laser in
multiple modes with a specified wavelength. They have a small capacity and
their performance is inferior to that of single-mode fibers, making them
suitable to short-distance transmission.
In the latest cabling infrastructure of ISO/IEC 11801, multimode fibers are
classified into four categories: OM1, OM2, OM3, and OM4.
– OM1: traditional 62.5/125 μm multimode fibers. OM1 fibers have a large
core diameter and numerical aperture, and provide high light gathering
ability and bending resistance.
– OM2: traditional 50/125 μm multimode fibers. OM2 fibers have a small
core diameter and numerical aperture. Compared with OM1 fibers, OM2
fibers provide higher bandwidth because they significantly reduce the
modal dispersion. When transmitting data at 1 Gbit/s with 850 nm
wavelength, OM1 and OM2 fibers support maximum link lengths of 220
m and 550 m, respectively. These two types of fibers can provide
sufficient bandwidth within a distance of 300 m. Generally, OM1 and
OM2 fibers are orange, as shown in Figure 3-45.
– OM3: next-generation multimode fibers, with longer transmission
distances than OM1 and OM2 fibers.
– OM4: laser optimized multimode fibers with 50 μm core diameter. OM4
is an improvement to OM3 and only increases the modal bandwidth.
OM4 fibers provide 4700 MHz*km of modal bandwidth, whereas OM3
fibers provide only 2000 MHz*km of modal bandwidth. Generally, OM3
and OM4 fibers are light green, as shown in Figure 3-46. You can identify
OM3 and OM4 fibers by their labels or printed marks.
MPO fibers are used for 40G and 100G optical modules. An MPO fiber consists of
multiple multimode fiber cores, and each multimode fiber core provides one laser
transmission channel. Some fiber suppliers produce 8-strand MPO fibers, while
some suppliers produce 12-strand or 24-strand MPO fibers.
● A 40G optical module uses four channels to transmit laser and four channels
to receive laser. That is, a total of eight channels are required for a 40G
optical module. 8-strand and 12-strand MPO fibers use the same definition of
fiber channels. Therefore, they are equivalent in functionality when
connecting to 40G optical modules.
● When 100G optical modules are used, choose MPO fibers according to the
optical module form factor. Choose 8-strand or 12-strand fibers for QSFP28
optical modules with MPO connectors.
Optical Connectors
Optical connectors are used to connect optical fibers of the same type. Table
3-208 lists common optical connectors.
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Table 3-208 Common optical connectors
Connector Optical Connector
Type
Square SC/PC LC/PC MTRJ/PC MPO
connector connector connector connector connector
Round FC/PC ST/PC - -
connector connector connector
Figure 3-43 shows an LC/PC optical connector.
Figure 3-43 LC/PC optical connector
NO TICE
When connecting or removing an LC/PC optical connector, align the connector
with the optical port and do not rotate the fiber. Pay attention to the following
points:
● To connect a fiber, align the optical connector with the optical port and gently
insert the optical fiber into the port.
● To remove a fiber, press the clip on the connector, push the connector inward
slightly, and pull the fiber out.
Appearance
Figure 3-44 shows the appearance of an LC single-mode fiber.
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Figure 3-44 Appearance of an LC single-mode fiber
Figure 3-45 shows the appearance of an LC multimode fiber.
Figure 3-45 Appearance of an LC multimode fiber
Figure 3-46 shows the appearance of an MPO-MPO fiber.
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Figure 3-46 Appearance of an MPO-MPO fiber
Figure 3-47 shows the appearance of an MPO-4*DLC fiber.
Figure 3-47 Appearance of an MPO-4*DLC fiber
Pin Assignments of an MPO-4*DLC fiber
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Figure 3-48 Structure of an MPO-4*DLC fiber
Table 3-209 Pin assignments of an MPO-4*DLC fiber
X1 Pin X2 Pin
1 1B
2 2B
3 3B
4 4B
9 4A
10 3A
11 2A
12 1A
NO TE
If the X1 end port is down but the X2 end port is up, check the X1 end port.
● Check whether this port supports the breakout function. If the X1 end port does not
support the breakout function, replace it with another port that supports the breakout
function.
● Check whether the X1 end port is in the breakout state. If the X1 end port is not in the
breakout state, configure the port to be in the breakout state.
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Technical Specifications
Table 3-210 Breakout fibers supported
Part Number Model Description Mode
14132537-005 SS-OP- Optical Cable Multimode
MPO12-4*DLC- Parts,MPO/
M-15B PC,4DLC/
PC,MULTI-
MODE,15m,8
CORES,0/1m,GJFH
-8A1A.2(OM3),3.5
mm,2mm,LSZH,43
MM SHORT
MPO,BENDING
INSENSITIVE
14132537-006 SS-OP- Optical Cable Multimode
MPO12-4*DLC- Parts,MPO/
M-30 PC,4DLC/
PC,MULTI-
MODE,30m,8
CORES,0/1m,GJFH
-8A1A.2(OM3),3.5
MM,2mm,LSZH,4
3MM SHORT
MPO,BENDING
INSENSITIVE
14132538 MPO12-4DLC- Optical Cable Single-mode
SM-15 Parts,MPO/
APC,4DLC/
PC,Single
mode,15m,8
cores,0m/
1m,GYFH-8G.657
A2,3.5mm,2mm,L
SZH,43mm short
MPO,Bending
insensitive
3.6 Fiber Breakout
3.6.1 Breakout Fibers
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Positioning
Breakout fibers are used to flexibly allocate bandwidth resources to routers. They
cooperate with a breakout optical module to convert an MPO interface into
multiple LC interfaces to facilitate fiber layout.
Usage Scenario
The breakout function applies to a scenario where bandwidth resources are
unevenly allocated between two routers at different levels. In comparison with
breakout boxes, breakout fibers implement the following functions:
● Loosen fiber layout.
● Extend the cabling distance.
Fiber Structure
To insert a breakout optical module (multimode and short transmission distance)
into a port, use an MPO-LC fiber to directly connect the optical module.
Figure 3-49 MPO-LC fiber structure
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NO TE
When using a breakout optical fiber, insert the X1 end into a 40GE QSFP+ optical module
and the X2 end into four 10GE interfaces. If the 40GE interface is Down but the four 10GE
interfaces are Up, check the 40GE interface status.
● Check whether the 40GE interface supports the breakout function. If the 40GE interface
does not support the breakout function, replace it with another interface that supports
the breakout function.
● Check whether the 40GE interface is in the breakout state. If the 40GE interface is not in
the breakout state, configure the 40GE interface to be in the breakout state.
Technical Specifications
Table 3-211 lists the breakout fibers.
Table 3-211 Breakout fibers supported
Type BOM Number Offi Mode
cial
Na
me
Optical Cable 14134759 MP Single mode
Parts,MPO/APC,MPO/ O1
APC,Single 2-
mode,10m,8 MP
cores,GJFH-8G.657A2,3 O1
.5mm,LSZH,43mm 2-
Short MPO,Bending SM-
insensitive 10
Optical Cable 14132538 MP Single mode
Assembly,MPO/ O1
APC,4*DLC/ 2-4
PC,Singlemode,GJFH DLC
8G.657A2(LSZH),15m, -
3.5mm,8 Cores,0m/ SM-
1m,2mm 15
Optical Cable 14132537 SS- Multimode
Parts,MPO/PC,4DLC/ OP-
PC,Multi-mode,5m,8 MP
cores,0/1m,GJFH-8A1a. O1
2(OM3),3.5mm,2mm,L 2-4*
SZH,43mm Short DLC
MPO,Bending -
insensitive M-5
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Type BOM Number Offi Mode
cial
Na
me
Optical Cable 14132537-005 SS- Multimode
Parts,MPO/PC,4DLC/ OP-
PC,Multi-mode,15m,8 MP
cores,0/1m,GJFH-8A1a. O1
2(OM3),3.5mm,2mm,L 2-4*
SZH,43mm Short DLC
MPO,Bending -
insensitive M-1
5B
Optical Cable 14132537-006 SS- Multimode
Parts,MPO/PC,4DLC/ OP-
PC,MULTI- MP
MODE,30m,8 O1
CORES,0/1m,GJFH-8A1 2-4*
A.2(OM3),3.5MM,2mm DLC
,LSZH,43MM SHORT -
MPO,BENDING M-3
INSENSITIVE 0
Optical Cable 14132537-001 SS- Multimode
Parts,MPO/PC,4DLC/ OP-
PC,Multi-mode,100m,8 MP
cores,0/1m,GJFH-8A1a. O1
2(OM3),3.5mm,2mm,L 2-4*
SZH,43mm Short DLC
MPO,Bending -
insensitive M-1
00
Optical Cable 14136626 MP Single mode
Parts,MPO/APC,8FC/ O1
UPC,SINGLE 2-4
MODE,15m,8 DFC
CORES,0/1m,GJFH-8G. -
657A2,3.5mm,2mm,LS SM-
ZH,43MM SHORT 15
MPO,BENDING
INSENSITIVE
Optical Cable 14136627 MP Single mode
Parts,MPO/APC,8SC/ O1
UPC,SINGLE 2-4
MODE,15m,8 DSC
CORES,0/1m,GJFH-8G. -
657A2,3.5mm,2mm,LS SM-
ZH,43MM SHORT 15
MPO,BENDING
INSENSITIVE
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Table 3-212 lists the optical modules and ports mapping breakout fibers.
Table 3-212 Optical modules and boards mapping breakout fibers
Breakout Fiber Optical Module Board
[14134759/MPO12- [02311NUA/ Check the Hardware
MPO12-SM-10] Optical OSM010N11] High Description. If the
Cable Parts,MPO/ Speed Transceiver,QSFP description of a port
APC,MPO/APC,Single +,1310,41.25Gbps,-8.2dB contains QSFP28 or
mode,10m,8 m,0.5dBm,-12.6dBm,MP QSFP+ and supports the
cores,GJFH-8G.657A2,3.5 O,SM,10km breakout function, the
mm,LSZH,43mm Short optical module and
MPO,Bending insensitive breakout fiber can be
used together with the
[14132538/ port.
MPO12-4DLC-SM-15]
Optical Cable
Assembly,MPO/
APC,4*DLC/
PC,Singlemode,GJFH
8G.657A2(LSZH),15m,3.5
mm,8 Cores,0m/
1m,2mm
[14136626/
MPO12-4DFC-SM-15]
Optical Cable
Parts,MPO/APC,8FC/
UPC,SINGLE
MODE,15m,8
CORES,0/1m,GJFH-8G.65
7A2,3.5mm,2mm,LSZH,4
3MM SHORT
MPO,BENDING
INSENSITIVE
[14136627/
MPO12-4DSC-SM-15]
Optical Cable
Parts,MPO/APC,8SC/
UPC,SINGLE
MODE,15m,8
CORES,0/1m,GJFH-8G.65
7A2,3.5mm,2mm,LSZH,4
3MM SHORT
MPO,BENDING
INSENSITIVE
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Breakout Fiber Optical Module Board
[14132537/SS-OP- [02310WUU/
MPO12-4*DLC-M-5] OMXD30010] Optical
Optical Cable Transceiver,QSFP
Parts,MPO/PC,4DLC/ +,850nm,41.25Gbps,-7.6d
PC,Multi-mode,5m,8 Bm,-1dBm,-9.5dBm,MPO,
cores,0/1m,GJFH-8A1a.2( MMF,0.15km
OM3),3.5mm,2mm,LSZH,
43mm Short
MPO,Bending insensitive
[14132537-005/SS-OP-
MPO12-4*DLC-M-15B]
Optical Cable
Parts,MPO/PC,4DLC/
PC,Multi-mode,15m,8
cores,0/1m,GJFH-8A1a.2(
OM3),3.5mm,2mm,LSZH,
43mm Short
MPO,Bending insensitive
[14132537-006/SS-OP-
MPO12-4*DLC-M-30]
Optical Cable
Parts,MPO/PC,4DLC/
PC,MULTI-MODE,30m,8
CORES,0/1m,GJFH-8A1A.
2(OM3),3.5MM,2mm,LS
ZH,43MM SHORT
MPO,BENDING
INSENSITIVE
[14132537-001/SS-OP-
MPO12-4*DLC-M-100]
Optical Cable
Parts,MPO/PC,4DLC/
PC,Multi-mode,100m,8
cores,0/1m,GJFH-8A1a.2(
OM3),3.5mm,2mm,LSZH,
43mm Short
MPO,Bending insensitive
[14132537/SS-OP- [02311NTY/
MPO12-4*DLC-M-5] OMND10N13] High
Optical Cable Speed
Parts,MPO/PC,4DLC/ Transceiver,QSFP28,850n
PC,Multi-mode,5m,8 m,100G,-8.4dBm,2.4dBm,
cores,0/1m,GJFH-8A1a.2( -10.3dBm,MPO,MM,0.1k
OM3),3.5mm,2mm,LSZH, m,OM4
43mm Short
MPO,Bending insensitive
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Breakout Fiber Optical Module Board
[14132537-005/SS-OP-
MPO12-4*DLC-M-15B]
Optical Cable
Parts,MPO/PC,4DLC/
PC,Multi-mode,15m,8
cores,0/1m,GJFH-8A1a.2(
OM3),3.5mm,2mm,LSZH,
43mm Short
MPO,Bending insensitive
[14132537-006/SS-OP-
MPO12-4*DLC-M-30]
Optical Cable
Parts,MPO/PC,4DLC/
PC,MULTI-MODE,30m,8
CORES,0/1m,GJFH-8A1A.
2(OM3),3.5MM,2mm,LS
ZH,43MM SHORT
MPO,BENDING
INSENSITIVE
NO TE
Characters in the brackets indicate the BOM number and official name that are separated
using a slash ("/") in the [BOM number/Official name] format.
3.6.2 Breakout Boxes
3.6.2.1 Product Overview
Positioning
Breakout boxes are used to flexibly allocate bandwidth resources to routers. They
cooperate with a breakout optical module and optical jumper to convert an MPO
interface into multiple LC interfaces to facilitate fiber layout.
Product Features
● LC interfaces support automatic dust-proof covers, and MPO interfaces
support dust-proof plugs.
● In comparison with breakout fibers (MPO-LC fibers), breakout boxes feature
more flexible fiber layout.
● There is no restriction on the installation direction of breakout boxes, so that
the breakout boxes can be installed positively or negatively as needed.
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Usage Scenario
The breakout function applies to a scenario where bandwidth resources are
unevenly allocated between two routers at different levels. In comparison with
breakout fibers, breakout boxes implement the following functions:
● Increase the density of fiber layout.
● Shorten the cabling distance.
Figure 3-50 Breakout box cabling
3.6.2.2 10-Port-MPO-12-40-Port-LC-Breakout Box(single-mode)
Appearance
Figure 3-51 10-Port-MPO-12-40-Port-LC-Breakout Box(single-mode)
Components
Figure 3-52 10-Port-MPO-12-40-Port-LC-Breakout Box(single-mode)
1. MPO adapter 2. LC adapter 3. Mounting ear
MPO adapters map LC adapters according to their numbers displayed on the
panel. Figure 3-53 shows the mapping between MPO and LC adapters.
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Figure 3-53 Mapping between MPO and LC adapters
MPO-12 Jumper
The TYPE-B MPO jumper is used. The following figure shows the MPO-12 jumper
structure and line orders of X1 and X2 ports.
Table 3-213 describes the mappings between the lanes of the X1 and X2 ports.
Table 3-213 Mappings between the lanes of the X1 and X2 ports
Start End Start End
X1-1 X2-12 X1-7 /
X1-2 X2-11 X1-8 /
X1-3 X2-10 X1-9 X2-4
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Start End Start End
X1-4 X2-9 X1-10 X2-3
X1-5 / X1-11 X2-2
X1-6 / X1-12 X2-1
Technical Specifications
Table 3-214 Technical specifications of the 10-Port-MPO-12-40-Port-LC-Breakout
Box (single-mode)
Item Description
BOM Number 02082890
Official Name ODBS10040
Dimensions (H x W x D) 43.6 mm x 442 mm x 164 mm
Mounting ear 19-inch supported
Weight 2.3 kg
Insertion loss ≤ 0.75 db
Return loss Single-mode: ≥ 30 db
Operating temperature –40°C to +65°C
Storage temperature –40°C to +70°C
Relative operating humidity ● Long term: 5% RH to 85% RH, non-
condensing
● Short term: 5% RH to 95% RH,
non-condensing
Relative storage humidity 0% RH to 95% RH, non-condensing
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Table 3-215 Optical modules, jumpers, and ports supported by the 10-Port-
MPO-12-40-Port-LC-Breakout Box (single-mode)
Optical Module MPO-MPO Fiber Port
[02311NUA/ [14134759/MPO12- Supported boards:
OSM010N11] Function MPO12-SM-10] Optical Check the Hardware
Module,OSM010N11,Hig Cable Parts,MPO/ Description. If the
h Speed Transceiver,QSFP APC,MPO/APC,Single description of a port
+,1310,41.25Gbps,-8.2dB mode,10m,8 contains QSFP28 or QSFP
m,0.5dBm,-12.6dBm,MP cores,GJFH-8G.657A2,3.5 + and and supports the
O,SM,10km mm,LSZH,43mm Short breakout function, the
MPO,Bending insensitive optical module and
breakout fiber can be
used together with the
port.
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4 Hardware Installation and Parts
Replacement
4.1 Hardware Installation and Maintenance Guide of NetEngine 8000 F1A-8H20Q
4.1 Hardware Installation and Maintenance Guide of
NetEngine 8000 F1A-8H20Q
4.1.1 Hardware Installation and Usage Precautions
Following All Safety Precautions
● To ensure human and device security, comply with all the safety precautions
marked on the device and instructed in this document before any operation.
The CAUTION, WARNING, and NOTE items in this document do not cover all
the safety precautions that must be obeyed. They are supplements to the
safety precautions.
● When operating Huawei products and equipment, comply with safety
precautions and special safety instructions relevant to the corresponding
equipment provided by Huawei. The safety precautions in this document are
only some that Huawei can predict. Huawei is not liable for any consequence
that results from violation of universal regulations for safety operations and
safety codes on design, production, and equipment use.
Complying with Local Rules and Regulations
When operating a device, comply with local laws and regulations.
Installation Personnel Requirement
Installation and maintenance personnel must be trained to perform operations
correctly and safely.
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Personnel Safety
● A high-voltage power supply provides power for device operations. Direct
human contact with the high voltage power supply or human contact through
damp objects can be fatal.
● Unspecified or unauthorized high voltage operations could result in fire or
electric shock, or both.
● Ground a device before powering it on; otherwise, the human body and the
device are exposed to danger.
● Before performing operations on the power supply facilities, power off these
facilities.
● Do not look into the optical port without eye protection when handling
optical fibers.
● To protect human respiratory organs and human eyes from dust, take
protective measures when drilling holes.
● When working at heights, prevent objects from falling down.
Device Security
● Keep an unpacked device upright and handle it with care when carrying it or
installing it into a cabinet.
● Use a ladder to lay out cables. Do not trample on a device.
● Wear an ESD wrist strap or ESD gloves when handling circuit boards.
Otherwise, the static electricity discharged from the human body may
damage the electrostatic sensitive components, such as large-scale integrated
circuits (LSIs) on the circuit board.
● Before operating the device, check the electrical connection of the device, and
ensure that the device is properly grounded.
Chassis
Filler panels must be installed in vacant slots to ensure the device functions
correctly. For example, they ensure electromagnetic compatibility, prevent the
ingress of dust or foreign objects, and maintain proper airflow for heat dissipation.
Power Module
● After a power module enters the protection state, it cannot supply power. If
the power module cannot automatically resume power supply after the
triggering condition of the protection state is removed, remove the power
module from the chassis and reinstall it at least 30s later. The power module
then can work properly.
● When a power module enters overtemperature protection state, take
measures to lower the temperature of the chassis. The power module can
automatically resume power supply when the temperature falls within the
normal range.
Cable
● To protect personal safety, do not install power cables when the power is on.
Before connecting power cables, make sure that the power switches of the
external power supply system and the device are all in OFF position.
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● Before connecting signal cables, take ESD protection measures, for example,
wear ESD gloves or an ESD wrist strap.
● Before connecting Ethernet cables, use an Ethernet cable tester to test cable
connectivity.
● Both ends of an idle high-speed cable must be covered by an ESD cap.
● The bend radius of high-speed cables must be larger than the minimum bend
radius. Overbending high-speed cables may damage wires in the cables.
● Laser beams will cause eye damage. Do not look into bores of optical
modules or optical fibers without eye protection.
● Cover idle optical ports and optical modules with dust plugs and cover idle
optical fibers with dust caps.
● Bundle optical fibers with binding tape. Apply appropriate force to ensure that
the optical fibers in a bundle can be moved easily.
● Fiber connectors must be tidy and clean to ensure normal communication. If
a fiber connector is contaminated, clean it using a piece of fiber cleaning
fabric.
Optical Module
● Devices must use optical modules that are certified for Huawei devices.
Optical modules that are not certified for Huawei devices cannot ensure
transmission reliability and may affect service stability. Huawei is not liable
for any problems caused by the use of optical modules that are not certified
for Huawei devices.
● The transmit power of a long-distance optical module is often larger than its
overload power. Therefore, when using such optical modules, select optical
fibers of an appropriate length to ensure that the actual receive power is
smaller than the overload power. If the optical fibers connected to a long-
distance optical module are too short, use an optical attenuator to reduce the
receive power on the remote optical module. Otherwise, the remote optical
module may be burnt.
4.1.2 Introduction to the A66E Cabinet
Naming Conventions
Figure 4-1 shows the naming conventions of the A66E cabinet.
Figure 4-1 Cabinet name
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Table 4-1 Cabinet naming conventions
Field Description
1 ALPEN, indicating the cabinet appearance series
2 Cabinet width: 600 mm
3 Cabinet depth: 600 mm
4 Enforce, indicating an enhanced performance model (Base, indicating a
basic performance model)
Appearance
Figure 4-2 shows the A66E cabinet appearance.
Figure 4-2 Cabinet appearance
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Physical Structure
Figure 4-3 shows components of the A66E cabinet.
Figure 4-3 Cabinet components
1. Front door 2. Top cover 3. Rear door 4. Side panel
(installed on the
side with a chassis
header)
5. Mounting rail 6. Rack - -
Functions and Features
The cabinet is made of class-A high-strength carbon cold rolled steel and
galvanized sheet, which complies with the Restriction of the use of certain
Hazardous Substances (RoHS). The fire endurance of interior materials complies
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with Underwriter Laboratories (UL) standards. The distance between front and
rear mounting rails is adjustable in 25 mm increments. Its assembled architecture
facilitates capacity expansion.
The cabinet has the following features and functions:
● Overhead and underfloor cabling
● Sufficient space to place and connect components
● Ability in protecting internal components from contamination
● Ability in preventing damage to internal components
Heat Dissipation
The front and rear doors of the cabinet are of mesh construction. Air enters the
chassis from the front door and base and is exhausted through the rear door.
Figure4 shows the airflow.
Figure 4-4 Airflow in the cabinet
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Technical Specifications
Table 4-2 Technical specifications of the A66E cabinet
Item Details
Dimensions without 2200 mm x 600 mm x 600 mm (86.61 in. x 23.62 in. x
packaging (H x W x 23.62 in.)
D)
Dimensions with 2340 mm x 710 mm x 860 mm (92.13 in. x 27.95 in. x
packaging (H x W x 33.86 in.)
D)
Weight (empty, 96 kg (211.64 lb)
without packaging)
Weight (assembly 156 kg (343.92 lb)
cabinet, with
packaging)
Standards IEC60297
compliance
Distance between 381.25mm
mounting rails
Available space 47U
Installation scenario Indoor installation
Installation mode Installation on a concrete floor or ESD floor
Part number 02116432
4.1.3 Cabinet Accessories
4.1.3.1 (Optional) Cabinet Stand
Appearance
The cabinet stand is pictured in Figure 4-5.
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Figure 4-5 Cabinet stand
Functions
The stand elevates and supports the cabinet.
Technical Specifications
Table 4-3 lists technical specifications of the cabinet stand.
Table 4-3 Technical specifications of the cabinet stand
Stand Type Applicable ESD Floor Wi Applicable Chassis
Height (mm) dth Depth (mm)
(m
m)
Stand I 200–270 600 1000, 1100, and 1200
Stand II 270–410
Stand III 410–700
NO TE
The ESD floor height is the distance between the upper surface of the ESD floor and the
surface of the concrete floor.
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4.1.4 A66E Cabinet Installation
4.1.4.1 Installing the Cabinet on the Concrete Floor
4.1.4.1.1 Removing the Ground Cables and Cabinet Doors
NO TE
Before removing the ground cables and cabinet doors, remove the marking-off template
and concrete mounting kits.
1. Removing the ground cables from the front door and rear door. One end of
the ground cable is connected with the cabinet door.
2. Pull down the hook pin at the upper part of the door panel.
3. Remove the front door.
4. Follow the same steps to remove the rear door.
Figure 4-6 Removing the ground cable and door
NO TE
For the coming use, put away the front and rear doors of the cabinet and bolts.
4.1.4.1.2 Determining the Installation Position of the Cabinets
1. Positioning the cabinet.
a. Attach the plumb line to the cable rack that is vertical to the front of the
cabinet. Use the marker to mark the point of the plumb on the ground.
b. Follow the same procedure to mark the second point, and draw the
baseline by using the powder marker.
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Figure 4-7 Positioning the cabinet
NO TE
The method for positioning the cabinet described in this document is only for
reference. Follow the engineering drawing to position the cabinet in the actual
installation.
2. Determining installation holes for the cabinet.
Figure 4-8 Determining installation holes for the cabinet
NO TE
The spacing between the rear door of the front access cabinet and the wall or any
other obstacles should be no less than 100 mm.
3. Confirming the position of the drill holes.
a. Lay out the templates side by side and ensure that there is 600 mm
between the center lines of two adjacent templates.
b. Use a marker to mark installation holes on the concrete floor.
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Figure 4-9 Confirming the position of the drill holes
NO TE
Position the template so that the semicircular gap indicates the front of the
cabinet.
After marking the reference lines, check the hole positions with a ruler.
4.1.4.1.3 Installing Expansion Bolts
1. Fasten the expansion bolt clockwise untill the guide rib is fixed on the guide
trough.
2. Put the expansion bolt vertically into the hole. Use a claw hammer to strike
the expansion tube into the hole completely.
3. Fasten the expansion bolt clockwise until the nut is firmly inserted into the
expansion tube.
4. Turn the expansion bolt counterclock-wise and remove the expansion bolt,
spring washer, and flat washer in turn.
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Figure 4-10 Installing expansion bolts
4.1.4.1.4 Installing the Cabinet
1. Placing the cabinet.
a. Place the cabinet on the specified position, and align the installation
holes of the cabinet with the holes on the floor.
b. Fix the spring washer, flat washer and insulation tube on the expansion
bolt. Insert them into the holes and tighten the four expansion bolts a
bit, but do not fasten them.
c. Lift one side of the cabinet and insert the insulation plate under the
cabinet. Insert another insulation plate under the other side of the
cabinet. Ensure that the gaps properly lock the expansion bolts.
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Figure 4-11 Placing the cabinet
4.1.4.1.5 Leveling the cabinet and testing the insulation
1. Leveling and fixing the cabinet.
a. Remove the four adjusting bolts attached on the bottom enclosure frame,
install them on the adjusting nuts.
b. Check whether the cabinet is horizontal or vertical by using a spirit level
and a plumb line respectively.
c. If the cabinet is not horizontal, adjust the adjusting bolts by using a
socket wrench.
d. When the cabinet is horizontal, fasten the four expansion bolts to 45
N·m.
Figure 4-12 Leveling and fixing the cabinet
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NO TE
The adjustment range of adjusting anchor is from 0 mm to 10 mm.
2. Testing the insulation of the cabinet.
a. Set the multimeter to read mega ohms.
b. Measure the resistance between the expansion bolt and the ground bolt
of the rack, the measured resistance is more than five mega ohms.
Figure 4-13 Testing the insulation of the cabinet
NO TE
If the measured resistance is less than five mega ohms, check whether any
insulation part is damaged or not installed. Measure the resistance again.
Otherwise, remove all components, install and fasten the cabinet again.
4.1.4.1.6 Attaching the cabinets
1. Remove the connection plates on the lintels of the front and rear doors and
install them again as shown in the figure.
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Figure 4-14 Installing the connection plates
2. Use the spirit level and the plumb line to verify that the bottom line of the
cabinet is horizontal and the front line of the column is vertical. If the cabinet
is not horizontal, adjust the adjusting anchor by using a socket wrench.
Figure 4-15 Leveling the cabinet
NO TE
Both the gap between cabinets and the vertical deviation should be less than 3 mm.
4.1.4.1.7 Installing cabinet doors
NO TE
Install the cabinet door after the inside components and cables. To install the components
inside the cabinets and cables, see the Installaiton Guide.
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1. Installing the cabinet doors.
a. Align the door with the front face of the column.
b. Place the door on the lower lintel and close the door till the lower pin
automatically inserts into the hole in the lower lintel.
c. Press the spring pin with your finger and push the upper part of the door
till the spring pin properly inserts in the installation hole at the top of the
lintel.
d. Check the spring pin and lower pins and ensure that the door is properly
installed.
e. To install the rear door, see the front door installation.
Figure 4-16 Installing the cabinet doors
2. Install the ground cables at the front doors and rear doors as shown in the
figure.
Figure 4-17 Installing the ground cables
4.1.4.2 Installing the Cabinet on the ESD Floor
4.1.4.2.1 Removing the Ground Cables and Cabinet Doors
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NO TE
Before removing the ground cables and cabinet doors, remove the marking-off template
and concrete mounting kits.
1. Remove the ground cables from the front door and rear door. One end of the
ground cable is connected with the cabinet door.
2. Pull down the hook pin at the upper part of the door panel.
3. Remove the front door.
4. Follow the same steps to remove the rear door.
Figure 4-18 Removing the ground cables and doors
NO TE
For the coming use, put away the front and rear doors of the cabinet and bolts.
4.1.4.2.2 Determining the Installation Position of the Supports
1. Positioning the cabinet.
Figure 4-19 Positioning the cabinet
NO TE
The spacing between the rear door of the front access cabinet and the wall or any
other obstacles should be no less than 100 mm.
2. Determining installation holes for the cabinet.
a. Lay out the templates side by side and ensure that there is 600 mm
between the center lines of two adjacent templates.
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b. Use a marker to mark installation holes on the concrete floor.
Figure 4-20 Determining installation holes for the cabinet
NO TE
Position the template so that the semicircular gap indicates the front of the
cabinet.
After marking the reference lines, check the hole positions with a ruler.
4.1.4.2.3 Installing Expansion Bolts
1. Fasten the expansion bolt clockwise until the guide rib is fixed on the guide
trough.
2. Put the expansion bolt vertically into the hole. Use a claw hammer to strike
the expansion tube into the hole completely.
3. Fasten the expansion bolt clockwise until the nut is firmly inserted into the
expansion tube.
4. Turn the expansion bolt counterclockwise and remove the expansion bolt,
spring washer, and flat washer in tum.
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Figure 4-21 Installing expansion bolts
4.1.4.2.4 Installing Supports
1. Adjusting the height of supports.
a. Use a ruler to measure the distance between the concrete floor and the
upper surface of the antistatic floor.
b. Adjust the support to the required height based on the measurement
results and the scale on the support.
c. Partially tighten the height locking bolts on both sides.
Figure 4-22 Adjusting the height of supports.
2. Assembling the Support.
a. Adjust the telescopic rod based on the cabinet depth until the scale
indicating the cabinet length is displayed.
b. Use a torque socket to secure the 6 M8x20 screw assemblies on the
telescopic rods to 13 N·m.
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c. Assemble the telescopic rod and support by using eight M8x20 screw
assemblies and ensure that the protruding side of the guide rail faces
outwards. Then tighten all screw assemblies using a torque socket to a
torque of 13 N·m.
d. Use a level to check the levelness of the support.
e. If the support is not horizontal, loosen the bolt and slightly adjust the
support till it is level.
f. Use a torque socket to secure all the bolts that are used to fix the height
to 45 N·m.
Figure 4-23 Assembling the Support
3. Installing a Single Support.
a. Align the four mounting holes of the support with the four expansion
bolt holes on the floor and secure four expansion bolts
b. Adjust the position of the support and use a level to measure the
levelness of the support.
c. If the support is not level, place shims under the support.
d. Use a torque socket to fasten the four expansion bolts to 45 N·m.
e. Assemble the combining parts to support by using two M8x20 screw
assemblies tighten to a torque of 13 N·m.
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Figure 4-24 Installing a Single Support
4. Installing the supports in a row.
a. Combine other supports with the first support using combining parts.
Ensure that the fronts of all supports are in the same line and the centers
of adjacent combining parts are 600 mm away from each other. Use a
torque socket to secure the M8x20 screw assemblies on the telescopic
rods to 13 N·m.
b. Check the support levelness by using a level.
c. If the support is not level, place spacers under the support.
d. Tighten all expansion bolts using a torque socket to a torque of 45 N·m.
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Figure 4-25 Installing the supports in a row
4.1.4.2.5 Installing the Cabinet
1. Placing the cabinet.
a. Place the cabinet on the slide rails, and align the installation holes of the
cabinet with the holes of the slide rails.
b. Fit the spring washer, flat washer and insulation tube on the four M12x40
bolts. Insert them into the installation holes and tighten the bolts a bit,
but do not fasten them.
c. Lift one side of the cabinet and insert the insulation plate under the
cabinet. Insert another insulation plate under the other side of the
cabinet. Ensure that the gaps properly lock the expansion bolts.
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Figure 4-26 Placing the cabinet
2. Leveling and fixing the cabinet.
a. Remove the four adjusting bolts attached on the bottom enclosure frame,
install them on the adjusting nuts.
b. Check whether the cabinet is horizontal or vertical by using a spirit level
and a plumb line respectively.
c. If the cabinet is not horizontal,use a socket wrench to screw the adjusting
bolts at the bottom.
d. Lift one side of the cabinet and insert when the cabinet is horizontal,
screw the four M12x40 bolts to 45 N·m with a torque wrench.
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Figure 4-27 Leveling and fixing the cabinet
4.1.4.2.6 Testing the Insulation and Installing the Front Pallet
1. Testing the insulation of the cabinet.
a. Set the multimeter to read mega ohms.
b. Measure the resistance between the M12x40 bolt and the ground bolt of
the rack, the measured resistance is more than five mega ohms.
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Figure 4-28 Testing the insulation of the cabinet
2. Installing the floor support bracket.
Fix the floor support bracket on the support by using the M12x25 assembly
bolts.
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Figure 4-29 Installing the floor support bracket
4.1.4.2.7 Attaching the Cabinets and Restoring the ESD Floor
1. Installing the connection plates.
a. Remove the connection plates on the lintels of the front and rear doors
and install them again as shown in the figure.
Figure 4-30 Installing the connection plates
b. Use the spirit level and the plumb line to verify that the bottom line of
the cabinet is horizontal and the front line of the column is vertical. If the
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cabinet is not horizontal, adjust the adjusting anchor by using a socket
wrench.
Figure 4-31 Leveling the cabinet
NO TE
Both the gap between cabinets and the vertical deviation should be no less than
3 mm.
2. Restoring the ESD floor.
Figure 4-32 Restoring the ESD floor
NO TE
The ESD floor has been removed before you determine the installation position of the
supports. Cut the ESD floor according to the size of the cabinet.
For underfloor cabling, place the cables before you restore the ESD floor.
4.1.4.2.8 Installing Cabinet Doors
1. Installing the cabinet doors.
NO TE
Install the cabinet door after the inside components and cables. To install the
components inside the cabinets and cables, see the Installation Guide.
a. Align the door with the front face of the column.
b. Place the door on the lower lintel and close the door till the lower pin
automatically inserts into the hole in the lower lintel.
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c. Press the spring pin with your finger and push the upper part of the door
till the spring pin properly inserts in the installation hole at the top of the
lintel.
d. Check the spring pin and lower pins and ensure that the door is properly
installed.
e. Follow the same steps to install the rear door.
Figure 4-33 Installing the cabinet doors
2. Installing the ground cables at the front doors and rear doors as shown in the
figure.
Figure 4-34 Installing the ground cables
4.1.5 Device Installation Process
This section describes the general device installation process. Before installing
device, you need to determine the installation mode according to installation
environment. After unpacking and inspecting the device, you need to install the
chassis, boards, fibers, and cables in sequence, and then check the installation
result. After determining that the installation is correct, you can power on the
device and then check fiber connections.
Table 4-4 lists the general installation process.
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Table 4-4 Device installation process
Installation Process Description
Preparing for the Before installing a device, plan and construct the
installation installation space and confirm the installation method
based on the requirements of device operation
environment. This is a prerequisite for smooth
installation, commissioning, and stable running of the
device. For details, see section " Hardware Installation
and Maintenance - Preparation before installation."
Unpacking a device After the project starts, the project supervisor should
unpack and check the device together with the customer
representative. For details, see section "Hardware
Installation and Maintenance- Preparing before
installation - Unpacking a Device."
Installing a chassis The installation method of the chassis varies according
to the installation environment. For details, see section
"Hardware Installation and Maintenance - Installing a
Chassis in Cabinet."
Installing Generally, the components are installed in the chassis. If
components the components are delivered separately, see section
"Hardware Installation and Maintenance - Installing of
Components."
Planning cable To ensure that power cables are connected in order, you
routing are advised to plan power cable routing. For details, see
section "Hardware Installation and Maintenance - Cable
Routing Planning."
Installing cables The methods of installing cables vary according to the
installation environment of the chassis. For details, see
section "Hardware Installation and Maintenance -
Installation of cables."
Checking the To ensure normal and stable running of a device, you
installation need to check the installation of the device after all
hardware is installed. For details, see section "Hardware
Installation and Maintenance - Post-Installation Check."
Performing a power- Before powering on a device, you need to check the
on check voltage and fuse capacity of the external power supply.
After the power-on, you need to check whether the
device is running normally by observing the indicators.
For details, see section "Hardware Installation and
Maintenance - Power-on Check."
Maintaining a device Faulty fuses and other electronic components can only
be replaced by professionals authorized by Huawei. For
details, see section "Hardware Installation and
Maintenance - Maintenance of the device."
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4.1.6 Preparation before installation
4.1.6.1 Reading Carefully the Safety Precautions
Before you start the installation procedure, read all safety precautions described in
this document and observe any warning labels affixed to the device. Doing so
ensures your safety and protects the device from damage.
Safety precautions provided in this document may not cover every eventuality, so
remain mindful of safety at all times.
Huawei is not liable for any consequence that results from violation of regulations
pertaining to safe operations or safety codes pertaining to design, production, and
equipment use.
Only trained and qualified personnel are allowed to install, operate, or maintain
the device. Familiarize yourself with all safety precautions before performing any
operation on the device.
General Safety
CA UTION
● Always take precautions against ESD whenever you handle a device. For
example, wear ESD gloves or an ESD wrist strap. To avoid electric shock or
burn, remove conductive objects like jewelry and watch.
● Connect the ground cable first after installing the device into a cabinet or rack.
Do not remove the ground cable unless all the other cables and modules have
been removed from the device.
NO TICE
● During device transport and installation, prevent the device from colliding with
objects like doors, walls, or shelves.
● Move an unpacked device upright gently to avoid damages to the device. Do
not lay down the unpacked device and drag it.
● Do not touch unpainted surfaces of the device with wet or contaminated
gloves.
● Do not open the ESD bags of cards and modules until they are delivered to the
equipment room. When taking a card out of the ESD bag, do not use the
connector to support the card's weight because this operation will distort the
connector and make the pins on the backplane connector bend.
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Environmental Safety
DANGER
Do not place or operate the device in an environment with flammable or explosive
gases or smoke.
NO TICE
● Keep the device away from sources of water to prevent damages to circuits.
● The installation site must be well ventilated to prevent the device from
overheating.
Electrical Safety
DANGER
● Direct contact with a high-voltage power source or indirect contact through
damp objects can be fatal. Misoperations on high-voltage facilities may result
in fire, electric shock, or other accidents.
● Never install or remove the device or power cables when the power is on. The
electric arc or spark generated between a power cable and conductor may
cause fire or eye damage.
● To protect personal and equipment safety, ground the device before powering it
on.
Laser Safety
CA UTION
● Laser beams will cause eye damage. Do not look into bores of optical modules
or optical fibers without eye protection.
● Cover fiber connectors with dust caps when they are not connected.
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Mechanical Safety
CA UTION
● Wear protective gloves when you are moving the device.
● Use safe lifting practices when moving the equipment. Never attempt to lift
objects that are too heavy for one person to handle. Instead, seek help or use
appropriate tools.
● Before installing the chassis into or removing it from a cabinet, ensure there are
no objects that could fall from the cabinet and cause injury.
● If main control boards, service boards, and power modules have been installed
on the chassis, you are advised to remove them before moving the chassis to
prevent them from falling off and causing injury.
● Do not drill unapproved holes into a cabinet, as doing so may impair its
electromagnetic shielding and damage cables inside. In addition, drilling holes
produces metal shavings that may enter the cabinet and cause short circuits on
printed circuit boards (PCBs).
4.1.6.2 Checking the Installation Site
The Device must be used indoors. To ensure normal operations and long service
life of the device, the installation site must meet the following requirements
described in Table 4-5.
Table 4-5 Requirements for the installation site
Item Requirement
Cleanliness The device must be installed in a clean, dry, and well
ventilated standard equipment room with stable
temperature. The equipment room must be free from
leaking or dripping water, heavy dew, and humidity.
Dust proofing Dustproof measures must be taken in the site. Dust will
cause electrostatic discharges on the chassis and affect
connections of metal connectors and joints. This shortens
service life of the device and may cause failures of the
device.
Temperature and The temperature and humidity in the installation site must
humidity be within specifications. For the operating temperature
and relative humidity ranges required by the device, see
device overview. If the relative humidity exceeds 70% RH,
using dehumidifiers or dehumidifying air conditioners is
recommended.
Corrosive gases The installation site must be free from acidic, alkaline, or
avoidance corrosive gases.
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Item Requirement
Heat dissipation Keep any objects or obstructions at least 75 mm away
space from the air intake and exhaust vents to facilitate heat
dissipation.
Maintenance The equipment must be stacked in the cabinet or installed
space at an interval of 2U or more to prevent the return air from
affecting heat dissipation.
4.1.6.3 Checking the Cabinet
The device can only be installed in a standard 19-inch cabinet. Huawei A66E
cabinet is recommended. If you purchase a cabinet by yourself, ensure that the
cabinet meets the following requirements:
1. 19-inch cabinet with a depth of greater than or equal to 600 mm.
2. The cabling space in front of the cabinet complies with the cabling space
requirements of boards.
NO TE
If a board requires optical modules or attenuators with a puller, GE electrical modules,
or shielded network cables, ensure that sufficient space is available for routing optical
fibers. For a convex door or open rack, it is recommended that the distance between
the cabinet door and the front panel of the board be greater than or equal to 105 mm
(4.13 in.).
3. The device is designed with front-to-back or back-to-front airflow. Prevent the
air intake vent and air exhaust vent from being blocked during installation.
4. The porosity of each cabinet door must be greater than 50%, meeting heat
dissipation requirements of devices.
5. The cabinet has installation accessories, such as guide rails, floating nuts, and
screws.
6. The cabinet has a ground terminal to connect to the device.
7. The cabinet has a cable outlet on the top or at the bottom for overhead or
underfloor cabling.
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Figure 4-35 A66E cabinet
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4.1.6.4 Preparing Installation Tools and Accessories
Table 4-6 lists the tools required for installing a device.
Table 4-6 Installation tools
Tool Description Picture
ESD gloves Used to
prevent
electrostatic
discharges.
Protective Used to
gloves protect hands
during
operation.
ESD wrist Used to
strap prevent
electrostatic
discharges.
Wear the
strap on your
wrist and
insert the
other end into
the ESD jack
on the
cabinet.
Utility knife Used to cut
cartons or
paper.
Scissors Used to cut
the
installation
template or
other
materials.
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Tool Description Picture
Tweezers Used to
unplug
Ethernet
cables and
optical fibers.
Measuring Used to
tape measure
distances.
Marker Used to mark
component
installation
positions.
Flat-head Used to turn
screwdriver slotted-head
screws and
bolts.
Phillips Used to turn
screwdriver cross-head
screws and
bolts.
Combinatio Used to clamp
n pliers or bend metal
sheets, cut
metal wires,
strip off
coating of
cables, and
unplug nails.
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Tool Description Picture
Diagonal Used to cut
pliers insulation
tubes and
cable ties.
Wire Used to strip
stripper off the
insulation
coating and
shields of
communicatio
n cables with
small cross-
sectional
areas.
RJ45 Used to crimp
crimping Ethernet
tool cables.
COAX Used to crimp
crimping the metal
tool shield at the
end of a
coaxial cable.
Ethernet Used to test
cable tester Ethernet cable
connectivity.
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Tool Description Picture
Multimeter Used to test
cabinet
insulation,
cable
connectivity,
and device
electrical
performance
indicators,
including
voltage,
current, and
resistance.
Adjustable Used to
wrench tighten or
loosen hex or
square bolts
and nuts. The
span can be
adjusted to
suit bolts or
nuts in
different sizes.
Table 4-7 lists the installation accessories required for installing a device.
Table 4-7 Installation accessories
Tool Description Picture
Insulation Used to
tape insulate
power wires
or other
conductors.
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Tool Description Picture
Corrugated Used to
pipe protect optical
fibers.
Table 4-8 lists the installation accessories delivered with the device.
Table 4-8 Installation accessories
Accessory Quantity Description Part Number
Serial 1 Used to connect the console 04040838
cable port of the device to a serial
port of a maintenance terminal
for local commissioning or
maintenance of the device.
Panel 8 Used to fix expandable guide 26020141
screw rails and the device.
(M6x12)
Floating 8 Installed on mounting rails of a 26020075
nut (M6) cabinet or rack and used with
M6 screws to secure the
expandable guide rails and the
device in the cabinet or rack.
ESD wrist 1 Prevents ESD damages when 28050001
strap you touch or operate the
equipment or components.
Fiber 1 m Used to bundle optical fibers. 21101258
binding
tape
Cable tie 50 Used to bundle cables. 21100144
(300 x 3.6
mm)
Label 12 Used to bundle cables and 21200708
cable tie attach the power cable label
(29041061) to the cables.
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Accessory Quantity Description Part Number
Signal 1 Used to identify locations of 29041060
cable signal cables.
label
Power 1 Used to identify locations of 29041061
cable power cables.
label
4.1.6.5 Inspecting and Cleaning Optical Fiber Connectors and Adapters
4.1.6.5.1 Overview
This topic introduces the purpose and procedure of cleaning optical fiber
connectors, as well as polluters to optical fiber connectors.
Cleaning fiber connectors is to remove dust or other dirt to avoid performance
degradation of optical transmission systems.
Figure 4-36 shows an optical fiber connector.
Figure 4-36 Optical fiber connector
Optical fiber connectors should be free of:
● Dust
● Grease (usually brought by hands)
● Condensate residue
● Powder (evaporated residue of water or solvent)
Dust is the most common dirt in optical fiber connectors. The dust particles that
can be seen only by a microscope can affect the quality of optical signals,
deteriorate the system performance, and cause instability in network operation.
A 1-micrometer dust particle on the single-mode fiber connector can block 1%
light and cause 0.05 dB attenuation. A 9-micrometer dust particle that cannot be
seen by human eyes can block an entire fiber core. Therefore, small dirt even that
cannot be seen by human eyes should be removed.
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NO TE
Before you connect any optical component, make sure that you have checked and cleaned
the component.
4.1.6.5.2 Protection of Optical Fiber Connectors
This topic describes requirements for fiber connector protection.
The requirements are as follows:
● All boards with optical ports must be packed properly, to avoid mechanical
and electrostatic damages and to reduce vibrations.
● The protective caps must be put in an ESD bag.
● Protective caps must be installed on all optical fiber connectors when not in
use. The optical fiber connectors must be stored in proper packages to keep
them clean.
● Figure 4-37 shows the recommended protective caps, whereas Figure 4-38
shows the protective caps not recommended.
Figure 4-37 Protective caps recommended
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Figure 4-38 Protective caps not recommended
NO TE
The protective caps not recommended are made of soft rubber, which are apt to absorb
dust and sundries, and difficult to clean.
4.1.6.5.3 Tools, Equipment, and Materials
Optical connectors should be cleaned using recommended tools, equipment and
materials.
The following provides the recommended tools, equipment and materials:
● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
● Cassette cleaner
● Cleaning solvent (Isoamylol is preferred, propyl alcohol is the next, and
alcohol or formalin is forbidden.)
● Non-woven lens tissue, fiber cleaning tissue, and dustfree cloth (Non-woven
lens tissue is recommended.)
● Special compressed air
● Special cleaning roll
● Dustfree absorbent swab (made of medical cotton or long fiber cotton)
shown in Figure 4-39 and Figure 4-40
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Figure 4-39 Dustfree absorbent swabs for cleaning the SC and FC connectors
Figure 4-40 Dustfree absorbent swabs for cleaning the LC connectors
4.1.6.5.4 Inspecting Optical Fiber Connectors
This topic describes how to inspect the end face of optical fibers using a fiber
microscope.
Tools, Equipment, and Materials
The following provides the required tools, equipment and materials for inspecting
optical fiber connectors:
● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
Precautions
CA UTION
Laser energy is invisible and may cause eye injuries. Never look directly into fiber
connectors or ports.
Use a fiber microscope equipped with a safety device or a desktop video fiber
microscope when inspecting the optical fiber connectors.
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NO TICE
Electrostatic discharge is hazardous to the electronic equipment. Wear an ESD
wrist strap and ensure that the strap is grounded properly before touching the
equipment and boards, to protect the static-sensitive components against
electrostatic discharge of the human body. Otherwise, the equipment may be
damaged or the service may be interrupted.
Procedure
1. Shut down the laser and disconnect the fiber end before inspecting the fiber
connector.
2. Test the optical power using a power meter to ensure that the laser is shut
down.
3. Use a fiber microscope to check whether the fiber connector is contaminated
or damaged. See the examples below.
– Clean fiber and face
Figure 4-41 shows an image of a clean fiber end face under the fiber
microscope.
Figure 4-41 Clean fiber and face
– Damaged fiber end face
Figure 4-42 shows images of the damaged fiber end face. The image on
the left shows a severely damaged fiber. Severely damaged fibers can
cause damage to the equipment and should not be used. The image on
the right shows a defective fiber. If the output power is within a certain
range, the defective fiber might not cause any damage to the equipment.
If the output power is unstable or out of the range, however, the
defective fiber can cause damage to the equipment.
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Figure 4-42 Damaged or defective fiber end face
NO TE
Figure 4-42 shows only the 800-micrometer fiber cores.
For details on acceptable and unacceptable fibers, see Figure 4-43, Figure
4-44 and Figure 4-45.
Figure 4-43 Clean fiber end face
Figure 4-44 Acceptable fibers with imperfections
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Figure 4-45 Unacceptable fibers with imperfections
4. If any dirt is detected, clean the optical fiber connector. For details, see
"Cleaning Optical Fiber Connectors Using the Cassette Cleaner" and "Cleaning
Optical Fiber Connectors Using Lens Tissue".
5. If any damage is detected, replace the fiber.
4.1.6.5.5 Inspecting the Optical Fiber Link
This section describes the insertion loss and reflection requirements of optical links
and the method of checking the quality of optical links for the application of 50G
optical modules with the PAM4 coding technology.
Tools, Equipment, and Materials
Tools and instruments for checking optical fiber links are as follows:
● OTDR meter
● Fiber microscope
Precautions
CA UTION
Because the transmit optical power of the OTDR meter is much higher than the
damaged optical power threshold at the receive end, the optical fiber must be
removed from the optical module when the OTDR meter is used to test the optical
path quality.
Currently, the Ethernet port rate is increasing. Since the 50G optical module link
uses the PAM4 encoding technology, there are higher requirements on the optical
fiber and cable quality and the link is more sensitive to multipath reflection
interference of signals. If the fiber link connector, fiber section, or fiber splicing
surface is dirty, optical signals are reflected back and forth on the fiber link,
causing interference due to co-channel noise on the receive side. As a result, the
optical link is unstable or intermittently disconnected.
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According to the national standard (GBT50312-2016), the loss of the optical fiber
link connector must meet the requirements described in Table 4-9.
Table 4-9 Maximum attenuation of the optical fiber connector
Type Maximum attenuation of an optical fiber
connector (dB)
Fiber splicing connector 0.3
Optical mechanical connector 0.3
Optical connector 0.75
NO TE
Fiber cores are connected through connectors, such as the ODF, optical attenuator, and
flange, in splicing and mechanical modes.
Table 4-10 describes requirements for the reflection of the optical fiber connector
when Ethernet ports (such as 50G) use PAM4 encoding to double the rate. More
connectors bring lower requirements for the reflection.
Table 4-10 Maximum reflection of connectors
Number of Maximum Reflection of Each Connector (dB)
Optical Fiber
Connectors 50GBASE-FR 50GBASE-LR 50GBASE-ER
1 -25 -22 -19
2 -31 -29 -27
4 -35 -33 -32
6 -38 -35 -35
8 -40 -37 -37
10 -41 -39 -39
Procedure
1. After the optical fiber at the peer end is disconnected, use the OTDR meter to
test the local end. Check whether the loss and reflection of each link and
node are normal. (The loss of a fiber splicing connector should be less than
0.3 dB, the loss of a connector should be less than 0.75 dB, and the reflection
of a connector should be less than -30 dB.) If the test result is not within the
required range, process the abnormal port.
2. Locate the equipment room where the port resides based on the distance
between abnormal points in the OTDR test result. Preliminarily determine the
port location, disconnect the port, and perform an OTDR test on the port that
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reports alarms. Check whether the distance is consistent with that in the
previous test. If not, continue to test other ports.
3. After the abnormal port is found, test the port using a fiber microscope. If the
port is dirty, clean it. For details, see "Inspecting and Cleaning Optical Fiber
Connectors and Adapters".
4. After the port is cleaned, restore the port, and ensure that the connector is
tightened. Perform an OTDR test on the port to check whether loss and
reflection of each link and node are normal.
5. If the fault persists, replace the flange and perform an OTDR test on the port
that reports alarms to check whether loss and reflection of each link and
node are normal.
6. If the fault persists, replace the optical fiber and perform an OTDR test on the
port that reports alarms to check whether loss and reflection of each link and
node are normal.
7. If multiple abnormal points exist on the link, repeat steps 2 to 6.
4.1.6.5.6 Cleaning Optical Fiber Connectors Using the Cassette Cleaner
This topic describes how to clean the fiber connectors using a cassette cleaner.
Prerequisites
Before cleaning, inspect the fiber end face with a fiber microscope or a magnifier
to confirm the degree of fiber contamination. Clean the fiber only when it is
severely contaminated. This is because the cleaning operation itself may introduce
dust, dirt, or cause damage to the fiber.
The following procedure provides the steps to clean the fiber connectors using
cartridge type cleaners.
Tools, Equipment, and Materials
The following lists the required tools, equipment and materials for cleaning optical
fiber connectors:
● cassette cleaner
● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
Precautions
CA UTION
Laser energy is invisible and may cause eye injuries. Never look directly into fiber
connectors or ports.
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NO TICE
Electrostatic discharge is hazardous to the electronic equipment. Wear an ESD
wrist strap and ensure that the strap is grounded properly before touching the
equipment and boards, to protect the static-sensitive components against
electrostatic discharge of the human body. Otherwise, the equipment may be
damaged or the service may be interrupted.
Procedure
1. Shut down the laser and disconnect the fiber end before inspecting the fiber
connector.
2. Test the optical power using a power meter to ensure that the laser is shut
down.
3. Press down and hold the lever of the cassette cleaner. The shutter slides back
and exposes a new cleaning area.
4. Place the fiber end face gently against the cleaning area.
5. Drag the fiber end face gently on one cleaning area in the arrow direction
each time. Do it again on the other cleaning area in the same direction as the
first time once.
NO TICE
Do not drag the fiber end face on the same cleaning area more than once.
Otherwise, the connector can be contaminated or damaged.
6. Release the lever of the cassette cleaner to close the cleaning area.
7. Use a fiber microscope to inspect the fiber to check whether there is any dirt.
For details see the examples shown in "Inspecting Optical Fiber Connectors".
If the fiber end face is still dirty, repeat 1 to 6.
8. Connect the fiber to the optical port immediately. If it is not used for the time
being, put a protective cap on it.
9. Turn on the laser after connecting the fiber to the board.
4.1.6.5.7 Cleaning Optical Fiber Connectors Using Lens Tissue
This topic describes how to clean the fiber connectors using lens tissue.
Prerequisites
Before cleaning, inspect the fiber end face with a fiber microscope or a magnifier
to confirm the degree of fiber contamination. Clean the fiber only when it is
severely contaminated. This is because the cleaning operation itself may introduce
dust, dirt, or cause damage to the fiber.
Tools, Equipment, and Materials
The following provides the required tools, equipment and materials:
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● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
● Cleaning solvent (Isoamylol is preferred, propyl alcohol is the next, and
alcohol or formalin is forbidden.)
● Non-woven lens tissue, fiber cleaning tissue, and dustfree cloth (Non-woven
lens tissue is recommended.)
● Special compressed air or cleaning roll
Precautions
CA UTION
Laser energy is invisible and may cause eye injuries. Never look directly into fiber
connectors or ports.
NO TICE
Electrostatic discharge is hazardous to the electronic equipment. Wear an ESD
wrist strap and ensure that the strap is grounded properly before touching the
equipment and boards, to protect the static-sensitive components against
electrostatic discharge of the human body. Otherwise, the equipment may be
damaged or the service may be interrupted.
Procedure
1. Shut down the laser and disconnect the fiber end before inspecting the fiber
connector.
2. Test the optical power using a power meter to ensure that the laser is shut
down.
3. Put a little cleaning solvent on the lens tissue.
4. Clean the fiber end face on the lens tissue. See Figure 4-46 and Figure 4-47.
NO TICE
Drag the fiber end face on the same area in the lens tissue only once.
Otherwise, the connector can be contaminated or damaged.
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Figure 4-46 Cleaning the fiber end face using the lens tissue on the desk
Figure 4-47 Cleaning the fiber end face using the lens tissue on the hand
5. Repeat 4 several times on the areas of the lens tissue that have not been
used.
6. Use the compressed air to blow off dust on the fiber end face.
NO TE
● When using the compressed air, keep the nozzle as close as possible to the fiber
end face without touching it.
● Before using the compressed air, first spray it into the air to expel deposits in the
compressed air.
● If the compressed air is not available, use a cleaning roll instead.
7. Use a fiber microscope to inspect the fiber to check whether there is any dirt.
For details, see the examples shown in "Inspecting Optical Fiber Connectors".
If the fiber end face is still dirty, repeat 1 to 6.
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8. Do not touch the fiber connector after cleaning it. Connect it to the optical
port immediately. If it is not used for the time being, put a protective cap on
it.
NO TE
Do not use the same cleaning area to clean the fiber connector for more than one
time.
9. Turn on the laser after connecting the fiber to the board.
4.1.6.5.8 Cleaning Optical Fiber Adapters Using Dustfree Absorbent Swabs
This topic describes how to clean fiber adapters using dustfree absorbent swabs.
Prerequisites
There are several types of dustfree absorbent swabs available. Select appropriate
dustfree absorbent swabs based on site conditions. You can obtain the following
tools and materials from a fiber cable and connector manufacturer.
Tools, Equipment, and Materials
The following lists the required tools, equipment and materials:
● Optical power meter
● 400X fiber microscope (A video fiber microscope is recommended.)
● Cleaning solvent (Isoamylol is preferred, propyl alcohol is the next, and
alcohol or formalin is forbidden.)
● Special compressed air
● Dustfree absorbent swab (made of medical cotton or long fiber cotton)
Precautions
CA UTION
Laser energy is invisible and may cause eye injuries. Never look directly into fiber
connectors or ports.
NO TICE
Electrostatic discharge is hazardous to the electronic equipment. Wear an ESD
wrist strap and ensure that the strap is grounded properly before touching the
equipment and boards, to protect the static-sensitive components against
electrostatic discharge of the human body. Otherwise, the equipment may be
damaged or the service may be interrupted.
Procedure
1. Shut down the laser and disconnect the fiber end before inspecting the fiber
connector.
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2. Test the optical power using a power meter to ensure that the laser is shut
down.
3. Select the dustfree absorbent swab with a proper diameter based on the type
of an adapter.
NO TE
For SC and FC fiber adapters, use the dustfree absorbent swab with a diameter of 2.5
mm (0.1 in.); for the LC fiber adapter, use the dustfree absorbent swab with a
diameter of 1.25 mm (0.05 in.). See Figure 4-48 and Figure 4-49.
Figure 4-48 Dustfree absorbent swabs for cleaning the SC and FC connectors
Figure 4-49 Dustfree absorbent swabs for cleaning the LC connectors
4. Put a little cleaning solvent on the dustfree absorbent swab.
5. Place the dustfree absorbent swab gently on the adapter so that the cleaning
solvent is against the fiber end face. Draw out the dustfree absorbent swab
from the fiber adapter and then rotate the dustfree absorbent swab clockwise
once. Ensure that the tip of the dustfree absorbent swab directly contacts the
fiber end face.
6. Use the compressed air to blow off dust on the fiber end face.
NO TE
● When using the compressed air, keep the nozzle as close as possible to the fiber
end face without touching it.
● Before using the compressed air, first spray it into the air to expel deposits in the
compressed air.
7. Use a fiber microscope to inspect the fiber to check whether there is any dirt.
For details, see "Inspecting Optical Fiber Connectors". If the fiber end face is
still dirty, repeat 1 to 6.
8. Connect the fiber to the optical port immediately. If it is not used for the time
being, put a protective cap on it.
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9. Turn on the laser after connecting the fiber to the board.
4.1.6.6 Inspection of power distribution environment
4.1.6.6.1 Introduction to the Power Distribution System
Devices support both AC and DC power supplies.
● AC power supply mode: Under normal conditions, uninterruptible power
supply (UPS) obtains three-phase 380 V AC power input from a mains power
outlet and transmits 380 V AC power to an AC power distribution frame. A
chassis receives power from the AC power distribution frame through the
power distribution unit (PDU) installed in the cabinet.
Figure 4-50 AC power supply mode
● High-voltage (240 V) DC power supply mode: Under normal conditions, a
rectifier system obtains three-phase 380 V AC power input from a mains
power outlet and transmits 240 V DC power to a DC power distribution frame.
A chassis receives power from the DC power distribution frame through the
PDU installed in the cabinet/rack.
Figure 4-51 High-voltage (240 V) DC power supply mode
● DC power supply mode: Under normal conditions, a rectifier system receives
three-phase 380 V AC power input from a mains power outlet and transmits
-48 V DC power to a DC power distribution frame. The device obtains power
from the DC power distribution frame.
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Figure 4-52 DC power supply mode
4.1.6.6.2 DC Power Distribution Guide
DANGER
Do not install power cables when the power is on. This is to avoid injuries.
Figure 4-53 Schematic diagram of the DC power distribution
DC Power Supply System
For cable specifications, see "Hardware Description"-Equipment Cables-Power
Cables.
Table 4-11 PDF circuit breaker specifications
Item Description Remarks
Circuit breaker of ≥32 A -
each channel NOTICE
The circuit breaker
current must not
be greater than
the maximum
derating current of
the device.
Installing Power Cables
1. Connect the power cord to the power connector.
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2. Attach temporary labels to both ends of each power cable.
3. Route power cables along the cable ladder and lay them on the chassis.
4. Take off the plastic cover from each power module, connect one end of each
power cable to the corresponding terminal and the other end to the PDF.
Figure 4-54 Installing the Power Cables
5. Use cable ties to bundle cables every 150 mm upwards from the bottom and
fasten the cables to the cable tray.
6. Attach permanent labels 20 mm from both ends of each power cable.
NO TE
To ensure that the power cable is long enough, perform the following steps to install a
power cable:
1. Prepare a power cable a little longer than the distance between the power module and
PDF.
2. Install a terminal on one end of the power cable and connect the terminal to the device.
3. Connect power cables to the positive and negative electrodes securely. Otherwise, the
power test result is inaccurate.
4. Route the power cable, bind it to the cable tray, and cut any excess length of the cable.
Install a terminal on the other end of the power cable and connect the terminal to the
PDF.
4.1.6.6.3 AC Power Distribution Guide
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DANGER
Do not install power cables when the power is on. This is to avoid injuries.
Figure 4-55 Schematic diagram of the AC power distribution
AC Power Supply System
For cable specifications, see "Hardware Description"-Equipment Cables-Power
Cables.
Table 4-12 PDF circuit breaker specifications
Item Description Remarks
Circuit breaker of ≥10 A For hierarchical power supplying
each channel NOTICE protection, the current of the circuit
The circuit breaker breaker at the user side should be no
current must not less than 10 A.
be greater than
the maximum
derating current of
the device.
Installing AC Power Cables
1. Route AC power cables along the cable ladder and lay them on the chassis.
2. Insert the AC power cable to the AC input port and secure it using the loose-
proof pinch as shown in Figure 4-56. Connect the other end of the AC power
cable to the PDF of the equipment room.
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Figure 4-56 Installing the AC power cable
3. Use cable ties to bundle AC cables every 150 mm upwards from the bottom
and fasten the cables to the cable tray.
4. Attach permanent labels 20 mm from both ends of each AC power cable.
Instructions for Connecting the AC Power Cable to the Power Distribution
Box
1. Cut the PE ground wire (yellow-green wire) at the peeling place (wrap it with
insulation tape to prevent leakage or short circuit), peel the L wire (brown
wire) and N wire (blue wire) and crimp the OT terminal Or cold-pressed
terminal (terminal type is selected according to actual conditions).
2. Connect the L and N wires to the corresponding L and N input terminals of
the power distribution box.
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When using 110V power supply (dual live wire power supply), L and N are
connected to the two live wires (L) of the equipment room and connected to
the PGND cable. At the same time, both L and N poles must be configured
with circuit breakers.
4.1.6.7 Unpacking a Device
Unpack the chassis before starting the installation.
4.1.6.7.1 Unpacking a Carton
Tools
● ESD gloves
● Diagonal pliers
● Paper knife
CA UTION
● Integrated circuits (ICs) are sensitive to electrostatic discharge from the
human body. When handling boards or metallic parts of the equipment,
wear ESD gloves and hold only the edges of the boards during operation.
● If the equipment is transported from a cold and dry place to a warm and
damp place, wait at least 30 minutes before unpacking it. Otherwise, the
moisture condenses on the board surface and damages the components.
Procedure
1. Transport the packing box to the equipment room.
2. Check the packing box, and stop unpacking it in any of the following cases:
– The outer package is severely damaged.
– There is water leakage on the outer package.
Find the causes and provide feedback to the local representative office of
Huawei.
3. Observe the labels on the carton to check the equipment configuration and
take a record.
4. Cut the strap with the diagonal plier and then split the adhesive tape properly
along the seam between the cover and the body of the box with the paper
knife. Do not scratch the articles inside the box.
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Figure 4-57 Unpacking the carton of the NetEngine 8000 F1A-8H20Q
1. Pressure- 2. Carton label 3. Packing box 4. ESD PE bag
sensitive adhesive
tape
5. Foam protector 6. Chassis - -
5. Open the carton and take out the chassis box from the carton.
6. Open the chassis box and take out the chassis. Then, check whether the
chassis is damaged.
4.1.7 Installing a Chassis in Cabinet
Precautions
Ensure that the cabinet has been properly installed before installing devices in the
cabinet. The cabinet can be installed on an ESD floor or concrete floor.
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NO TICE
● When installing devices, ensure that the total heat consumption of all devices
in the cabinet is less than or equal to the heat dissipation capability of the
cabinet.
● To prevent heat dissipation from being affected by air return, devices must be
installed at an interval of 1 U or more in the cabinet. In addition, the middle-
column cabinets support device stacking.
● Ensure that heat dissipation holes on the panel are not blocked.
● When the chassis is installed together with other equipment in the same
cabinet, do not install the chassis near the air exhaust vent of other equipment.
● Determine whether the air exhaust vent affects adjacent devices to avoid high
temperature of adjacent devices.
Installing a Chassis in a Standard 19-Inch Cabinet
1. Wear an ESD wrist strap or ESD gloves. Ensure that the ESD wrist strap is
grounded and in close contact with your wrist.
2. Use a measuring tape to measure the distance between the front and rear
mounting rails in the cabinet.
3. Select front mounting brackets, rear mounting brackets, and rear mounting
bracket guide rails according to the distance between the front and rear
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mounting rails. Table 4-13 shows the front mounting brackets, rear mounting
brackets, and rear mounting bracket guide rails used on the device for
different distances between the front and rear mounting rails.
Table 4-13 Selection of front mounting brackets, rear mounting brackets, and
rear mounting bracket guide rails used on the device
Distance Front Mounting Brackets, Rear Mounting Brackets, and
Between Rear Mounting Bracket Guide Rails
Front and
Rear
Mounting
Rails
310 mm to
351 mm
369 mm to
410 mm
438 mm to
479 mm
497 mm to
538 mm
539 mm to
637 mm
638 mm to
696 mm
697 mm to
835 mm
4. Fix floating nuts and M6 screws in the correct holes.
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NO TE
When tightening floating nuts, ensure a minimum distance of 75 mm between a
chassis side and its adjacent column for ventilation.
5. Use a torque screwdriver to install the front mounting brackets using three
M4 screws with a torque of 1.2 N m.
6. Use a torque screwdriver to install the extension rails of the expandable
mounting brackets on the rear of the chassis using four M4 screws with a
torque of 1.2 N m.
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Install the front mounting brackets, rear mounting brackets, and rear
mounting bracket guide rails depending on the distance between the front
and rear mounting rails in the cabinet. See Table 4-14.
Table 4-14 Installing front mounting brackets, rear mounting brackets, and
rear mounting bracket guide rails
Distance Installation of Front Mounting Brackets, Rear Mounting
Between Brackets, and Rear Mounting Bracket Guide Rails
Front and
Rear
Mounting
Rails
310 mm to
351 mm
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Distance Installation of Front Mounting Brackets, Rear Mounting
Between Brackets, and Rear Mounting Bracket Guide Rails
Front and
Rear
Mounting
Rails
369 mm to
410 mm
438 mm to
479 mm
497 mm to
538 mm
539 mm to
637 mm
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Distance Installation of Front Mounting Brackets, Rear Mounting
Between Brackets, and Rear Mounting Bracket Guide Rails
Front and
Rear
Mounting
Rails
638 mm to
696 mm
697 mm to
835 mm
7. Use a torque screwdriver to install the extension runners of the expandable
mounting brackets on the rear posts of the cabinet using M6 screws with a
torque of 3 N m. Horizontally insert the chassis into the cabinet from the
front of the cabinet until the extension rails are fully inserted into the
extension runners. Then, use screws to fix the front mounting brackets to the
cabinet.
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8. Use a torque screwdriver to install the ground cable using an M4 screw with a
torque of 1.2 N m.
4.1.8 Cable Routing Planning
4.1.8.1 DC Power Cable Routing Planning
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Context
To ensure that power cables are connected in order, you are advised to plan power
cable routing.
NO TICE
Do not bundle or route outdoor cables (such as outdoor antenna feeders and
outdoor power cables) and indoor cables together in the cabinet or on the cable
tray.
If the cables on the right side are tightly bundled but the cabling space is still
insufficient, you can route the extra cables on the left side. In the case of left-side
cabling, keep the cables away from the upper and lower board, power module,
and fan module insertion/removal areas to facilitate future maintenance.
Power Cable Routing Planning
It is recommended that DC power cables be routed on the left side of the cabinet
or rack.
It is recommended that cables, such as optical fibers, and Ethernet cables, be
routed on the left and right sides of the cabinet as the circumstances may require.
Figure 4-58 shows the cable layout of a DC device.
Figure 4-58 Cable layout
4.1.8.2 AC Power Cable Routing Planning
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Context
To ensure that power cables are connected in order, you are advised to plan power
cable routing.
NO TICE
Do not bundle or route outdoor cables (such as outdoor antenna feeders and
outdoor power cables) and indoor cables together in the cabinet or on the cable
tray.
If the cables on the right side are tightly bundled but the cabling space is still
insufficient, you can route the extra cables on the left side. In the case of left-side
cabling, keep the cables away from the upper and lower board, power module,
and fan module insertion/removal areas to facilitate future maintenance.
Power Cable Routing Planning
It is recommended that AC power cables be routed on the left side of the cabinet.
It is recommended that cables, such as optical fibers, and Ethernet cables, be
routed on the left and right sides of the cabinet as the circumstances may require.
Figure 4-59 shows the cable layout of an AC device.
Figure 4-59 Cable layout
4.1.9 Installation of cables
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4.1.9.1 Installing Optical Fibers
NO TICE
● Wear an ESD wrist strap or ESD gloves before installing optical modules.
● The bending radius of a single-mode G.657A2 optical fiber is greater than or
equal to 10 mm, and the bending radius of a multi-mode A1b optical fiber is
greater than or equal to 30 mm.
● Cover empty optical interfaces and idle optical modules with dust caps.
● Do not bundle optical fibers too tightly. You must be able to conveniently
remove a single fiber from the bundle.
● Properly fix optical fibers onto the cabinet columns to prevent impact on the
surrounding devices.
1. Attach temporary labels to both ends of each optical fiber.
2. Arrange optical fibers into a bundle and feed them through the corrugated
pipe.
3. Wrap adhesive tapes on both ends of the corrugated pipe to protect it from
cuts.
4. Route the corrugated pipe along the cable ladder.
5. Insert the corrugated pipe through the dedicated cable hole on the cabinet
top to the cabinet about 100 mm and tie the pipe to the cabinet.
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Figure 4-60 Inserting the corrugated pipe
6. Install the optical module, as shown in step 1 in Figure 4-61.
7. Route optical fibers along the cable tray, remove the dust caps from the
optical modules and optical fiber interfaces. Then connect the end of each
optical fiber to the corresponding optical interface, as shown in step 2 in
Figure 4-61.
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Figure 4-61 Installing Optical Fibers
8. Connect the other end of each optical fiber to the ODF.
9. Bundle optical fibers with binding straps at an interval of 150 mm and fasten
the optical fibers to the cable tray.
10. Attach permanent labels 20 mm from both ends of each optical fiber.
4.1.9.2 Installing Network Cables
NO TICE
Before bundling network cables, use a network cable tester to test cable
connectivity.
NO TE
● Bundle the network cables in a rectangle shape. Ensure that the cable ties are evenly
spaced and face the same direction.
● Route cables at a proper distance from each other. Otherwise, the installation of other
cables may be affected.
● Route Ethernet cables, power cables, and ground cables separately. The Ethernet cables
must not be damaged or broken or have joints.
1. Attach temporary labels to both ends of each network cable.
2. Route network cables along the cable tray and plug them into corresponding
interfaces.
3. Use a network cable tester to test the connectivity of network cables.
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4. Use cable ties to bundle network cables at an interval of 150 mm and fasten
the network cables to the rack.
5. Attach permanent labels 20 mm from both ends of each network cable.
Figure 4-62 Installing network cables
4.1.9.3 Installing a Cabinet Ground Cable
1. Install a cabinet ground cable.
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Figure 4-63 Installing a cabinet ground cable
2. Install the ground cable between the device and cabinet.
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Figure 4-64 Installing the ground cable between the device and cabinet
4.1.10 Post-Installation Check
CA UTION
Before starting the post-installation check, make sure that the power switches of
the external power supply system are in OFF position.
After completing installation of a device, check the items listed in the following
table. If any item fails the check, check for the reason, reinstall the related
component, and check again. Ensure that all the items pass the check.
Check cabinets according to Table 4-15.
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Table 4-15 Cabinet checklist
No. Item Method
1 The cabinet installation location complies Observe
with the engineering design document.
2 Components are correctly installed in a Observe
cabinet. No component is loose or damaged.
3 All the bolts are tightened, especially those Observe
for electrical connections. The flat washers
and spring washers are installed completely
and properly.
4 The vertical deviation of a cabinet is less Measure
than 3 mm. You can use a plumb bob to
measure the vertical deviation.
5 The cabinets on the sides of the main path Measure
are aligned in a line, with a deviation of less
than 5 mm.
6 The surfaces of the cabinets in the same row Observe
are on the same plane. The cabinets are
deployed close to each other.
7 The front door of a cabinet can be opened Observe
and closed easily.
8 The cable outlets on the top and bottom of Observe
a cabinet are properly sealed.
9 Metal components in a cabinet have good Observe
electrical connections with the rack. Screw
mounting holes, guide rails, and mounting
brackets are not covered with insulation
painting.
10 Ground busbars of adjacent cabinets are Observe
connected through busbar cables.
Check cables according to Table 4-16.
Table 4-16 Cable checklist
No. Item Method
1 Routes of signal cables comply with the Observe
engineering design document.
2 Signal cables are not damaged or broken Observe
and have no splices.
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No. Item Method
3 Signal cable connectors are clean, intact, and Observe
correctly connected. Wires of each signal
cable are securely clamped in the
connectors.
4 Signal cables do not cross each other and Observe
have sufficient slack at the bent part. (Signal
cables can be crossed within 1 m outside the
cabinet.)
5 Pigtail fibers outside a cabinet are laid in a Observe
protection pipe or trough and are not
squeezed by other cables or objects.
6 Optical fibers are led into a cabinet through Observe and
a corrugated pipe. The corrugated pipe measure
should be no longer than 100 mm and be
bundled on the cabinet.
7 The bend radius of optical fibers is 20 times Observe and
larger than their diameters. Generally, the measure
bend radius of optical fibers should be no
less than 40 mm. The path of optical fibers is
not blocked by any components.
8 Optical fibers are bundled by binding tape Observe
with appropriate force.
9 Each signal cable has correct, clear, and tidy Observe
labels attached on both ends.
10 The routes of power cables and ground Observe
cables conform to the engineering design
document, facilitating future maintenance
and system expansion.
11 All power cables and ground cables are Observe
complete copper wires without splices.
Coatings of power cables and ground cables
are intact.
12 Power cables and ground cables are Observe
connected properly.
13 Power cables and ground cables are routed Observe
in compliance with the engineering design
document, meeting power distribution
requirements.
14 Power cables and ground cables are Observe
separated from signal cables.
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No. Item Method
15 Power cables and ground cables are routed Observe
straightly and properly bundled, with
sufficient slack at the bend part.
16 Power cables, ground cables, and power Observe
switches on power distribution boxes and
power distribution frames are identified by
correct, clear, and tidy labels.
17 The yellow-green ground cables are correctly Observe
connected. One end of a ground cable is
connected to the PGND ground bar in the
power distribution cabinet, and the other
end is connected to the ground point on a
cabinet. Screws at both ends of a ground
cable are securely fastened.
Check the installation environment according to Table 4-17.
Table 4-17 Installation environment checklist
No. Item Method
1 No fingerprints or other smears exist on the Observe
surface of the equipment cabinet.
2 No excessive adhesive tapes or cable ties Observe
exist on the cables.
3 No tapes, cable ties, wastepaper, or packing Observe
bags are left around the equipment.
4 All the items around the equipment are neat, Observe
clean, and intact.
4.1.11 Power-on Check
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Power-on Check Flowchart
Figure 4-65 Power-on Check Flowchart
NO TICE
The normal input voltage of the DC power supply system ranges from -40 V DC to
-72 V DC. The normal input voltage of the AC power supply system ranges from
90 V AC to 290 V AC.
Indicator description
Item Indicator Color Status Description
Fan module FAN Green The fan module works normally.
Red The fan module fails.
- If this indicator is steady off, the
fan module is not powered on or
the fan hardware is faulty.
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Item Indicator Color Status Description
Working STAT Green The device works normally.
status
indicator Red The hardware is faulty.
- If this indicator is steady off, the
device is not running or no power
is input.
Connection/ L/A Green If this indicator is steady green, the
data link is Up.
transmission
status If this indicator blinks, data is
indicator being received and transmitted.
Orange If this indicator blinks, data is
being received and transmitted.
- If this indicator is steady off, the
link is Down.
Breakout Breakout Green Each indicator for channels 0, 1, 2,
channel 0-3 and 3 turns on for 5s in sequence
indicator to indicate the status of the
corresponding channel. This
process repeats.
4.1.12 (Optional) Checking Optical Power
The following table describes comparison between the transmit optical power of
50 Gbps optical modules and damaged optical power threshold at the receive end:
Optical Maximum Minimum Damaged Description
Module Type Average Average Optical
Transmit Transmit Power
Optical Optical Threshold at
Power Power the Receive
End
50GBASE-FR 3 -4.1 5.2 The damaged
optical power
50GBASE-LR 4.2 -4.5 5.2 threshold is
greater than
the maximum
average
transmit
optical power,
posting low
self-loop risks.
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Optical Maximum Minimum Damaged Description
Module Type Average Average Optical
Transmit Transmit Power
Optical Optical Threshold at
Power Power the Receive
End
50GBASE-ER 6.6 0.4 -2.4 The damaged
optical power
threshold is
9dBm lower
than the
maximum
average
transmit
optical power
and 2.8dBm
lower than
the minimum
average
transmit
optical power,
posing high
self-loop risks.
In this case,
an optical
attenuator
must be
configured for
self-loop.
For applications of the 50 Gbps optical module supporting a distance of 40 km:
1. To ensure that the optical module runs stably for a long time, adjust the
receive optical power of the optical module to a value lower than -4 dB.
According to the IEEE 802.3 standard, if the receive optical power of the
optical module exceeds -2.3 dB, the optical module may be permanently
damaged.
2. Before connecting to the optical module, use an optical power meter to
measure the receive optical power (P). If P is less than -4 dB, the optical
module can be directly connected. If P is greater than -4 dB, add an optical
attenuator at the receive end to ensure that the receive optical power is less
than -4 dB. Alternatively, add an optical attenuator (no less than 10 dB is
recommended) before the interconnection, and then adjust the optical
attenuator based on the site requirements to prevent the optical module from
being damaged.
3. If a loopback occurs on the pigtail of the optical module or the optical
module is connected for a short distance, an optical attenuator must be
added. It is recommended that the optical attenuator be no less than 10 dB.
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4.1.13 Maintenance of the device
4.1.13.1 Basic Operation Process and Precautions
Context
To ensure that the device provides uninterrupted communication services for users
in networks, parts of a device are replaced mostly when the power is on.
Therefore, to ensure safe operation of a device and to minimize the impact of
parts replacement on services, maintenance personnel must strictly abide by the
basic operation process regulated in the manual, as shown in Figure 4-66.
Figure 4-66 Basic operation process of replacing parts
Procedure
1. Assess the feasibility of the operation.
During the process of troubleshooting or repairing a device, maintenance
personnel must assess whether the operation is feasible before replacing a
certain part.
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a. Whether the needed spare parts are available in the depot.
b. Whether the maintenance personnel is qualified for carrying out the
operation.
NO TE
Parts replacement can be carried out only by maintenance personnel who are
professionally trained. That is, maintenance personnel must familiarize
themselves with the functions of each part of the device, know the basic
operation process of parts replacement, and master the basic skills of parts
replacement.
c. Whether the risks of the operation can be controlled.
NO TICE
Parts replacement is risky to a certain extent. Hence, improper operation
may cause abnormal running of the device, service interruption, or
injuries to the personnel. Therefore, before replacing parts, maintenance
personnel must comprehensively evaluate the risks of the operation, that
is, whether the risks can be controlled through certain measures if the
system remains active. Maintenance personnel can replace the parts only
when the risks can be controlled. Otherwise, contact a Huawei local
office for timely technical support.
2. Prepare tools and spare parts.
After determining that the operation is feasible, maintenance personnel need
to prepare tools and spare parts.
a. Prepare spare parts.
NO TICE
Before replacing the component, contact Huawei engineers to see if a
license is required. You can apply for a license or use Stick License to
activate some license control items.
b. The common tools include the multimeter, cable tester, ESD wrist strap,
Phillips screwdriver, flat-head screwdriver, needle-nose pliers, cutter, and
pliers.
3. Take protective measures.
Although parts replacement is risky, in most cases, however, maintenance
personnel can prevent the risks by taking protective measures. For example,
before replacing a master board, maintenance personnel can switch services
on the master board to the slave board. After the slave board runs properly,
maintenance personnel can replace the master board. In this manner,
interruption of services is prevented.
Therefore, to ensure safe operation of a device and to minimize the impact of
parts replacement on services, maintenance personnel must take related
protective measures.
4. Replace parts.
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After checking that the protective measures are available, maintenance
personnel can carry out parts replacement according to the regulations
specified in the manual.
DANGER
Wear an ESD wrist strap or ESD gloves before replacing parts when the power
is on.
Avoid direct eye exposure to the laser beam launched from the optical
interface board or fiber.
5. Verify the functions of the new parts.
After completing part replacement, maintenance personnel must verify the
functions of the new parts through the testing methods described in this
section.
NO TE
The operation is considered successful only when the new parts are proved to be
running normally. Otherwise, contact Huawei technical support personnel.
6. Return and repair the faulty parts.
If a part that is replaced is confirmed to be faulty, maintenance personnel
should fill in the Offsite Repair Card for Faulty Materials, and send the card
and the faulty part to a Huawei local office for timely maintenance.
NO TICE
Carefully maintain the damaged control board that store data to prevent
information leak.
Before you replace the control board, delete data from it to prevent data
embezzlement.
Use either of the following methods to delete data from the control board:
● Connect the control board to a PC and then delete data from the control
board on the PC.
● Physically destroy the control board.
4.1.13.2 Replacing a power module
4.1.13.2.1 Replacing the DC Power Module
Precautions
Before replacing a power module, you need to note the following points:
Before replacing a power module, switch off the corresponding circuit breaker on
the power distribution cabinet.
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Do not touch metal parts when removing or installing a power module with the
power on.
Tools
Before replacing a power module, you need the following tools:
● ESD wrist strap or ESD glove
Procedure
1. Check the location of the power module to be replaced.
Before pulling out a power module that is to be replaced, you should first
check the location of the module, for example, the cabinet and chassis where
the power module resides. Then, locate the power module to be replaced in
the chassis and attach a label to the panel to identify the power module.
2. Switch off the corresponding circuit breaker on the power distribution cabinet.
Thus, the power module to be replaced is powered off.
3. Wear the ESD wrist strap and connect the grounding terminal to the ESD jack
on the rack.
4. Disconnect power cables from the wiring terminals.
5. Press and hold the lock on the power module rightward with your thumb,
slowly pull the power module out by the handle, as shown in Figure 4-67.
Figure 4-67 Pull out the power module
6. Hold both sides of the power module and insert the module into the guide
rail of the slot. Ensure that the power module is in good contact with the
backplane of the chassis, as shown in Figure 4-68.
Figure 4-68 Insert the power module
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7. Connect the cables to the power module in the original sequence, and
reinstall the protective cover.
8. Switch on the corresponding circuit breaker on the power distribution cabinet.
Verify the functions of the new power module.
– If the STAT indicator on the panel of the power module is on and is
green, power module works normally.
– Run the display device command on the console interface to check the
running status of the new power module. If the Status is displayed as
Normal, it indicates that the power module runs normally.
If the fan module fails to return to the normal state, you should contact a
Huawei local office for timely technical support.
Follow-up Procedure
After replacing the power module, collect the tools. If a power module that is
replaced is confirmed to be faulty, you should fill in the Offsite Repair Card for
Faulty Materials, and send the card and the faulty power module to a Huawei
local office for timely maintenance.
4.1.13.2.2 Replacing the AC Power Module
Precautions
Before replacing a power module, you need to note the following points:
Before replacing a power module, switch off the corresponding circuit breaker on
the power distribution cabinet.
Do not touch metal parts when removing or installing a power module with the
power on.
Tools
Before replacing a power module, you need the following tools:
● ESD wrist strap or ESD glove
Procedure
1. Check the location of the power module to be replaced.
Before pulling out a power module that is to be replaced, you should first
check the location of the module, for example, the cabinet and chassis where
the power module resides. Then, locate the power module to be replaced in
the chassis and attach a label to the panel to identify the power module.
2. Switch off the corresponding circuit breaker on the power distribution cabinet.
Thus, the power module to be replaced is powered off.
3. Wear the ESD wrist strap and connect the grounding terminal to the ESD jack
on the rack.
4. Disconnect power cables from the wiring terminals.
5. Press and hold the lock on the power module rightward with your thumb,
slowly pull the power module out by the handle, as shown in Figure 4-69.
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Figure 4-69 Pull out the power module
6. Hold both sides of the power module and insert the module into the guide
rail of the slot. Ensure that the power module is in good contact with the
backplane of the chassis, as shown in Figure 4-70.
Figure 4-70 Insert the power module
7. Connect the cables to the power module in the original sequence, and
reinstall the protective cover.
8. Switch on the corresponding circuit breaker on the power distribution cabinet.
Verify the functions of the new power module.
– If the STAT indicator on the panel of the power module is on and is
green, power module works normally.
– Run the display device command on the console interface to check the
running status of the new power module. If the Status is displayed as
Normal, it indicates that the power module runs normally.
If the fan module fails to return to the normal state, you should contact a
Huawei local office for timely technical support.
Follow-up Procedure
After replacing the power module, collect the tools. If a power module that is
replaced is confirmed to be faulty, you should fill in the Offsite Repair Card for
Faulty Materials, and send the card and the faulty power module to a Huawei
local office for timely maintenance.
4.1.13.3 Replacing the Fan Module
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Precautions
● To ensure that system heat dissipation is not affected, a fan module must be
replaced within one minute.
● The fans are exposed on the left side of the fan tray. Keep your fingers,
clothing, and jewelry away from the fans. Always handle the fan tray by the
handle.
● Do not touch the fan when the fan is rotating.
Tools
● ESD wrist strap or ESD gloves
Procedure
1. Check the location of the fan module to be replaced.
Before removing the old fan module, check its location, for example, the
cabinet and chassis where the fan module resides. Then, find the fan module
to be replaced in the chassis and attach a label to the panel to identify the
fan module to avoid misoperation.
2. Wear the ESD wrist strap and connect the ground terminal to the ESD jack on
the chassis.
3. Hold the handle on the fan module with one hand and pull part of it. Support
the bottom of the fan module with the other hand until the fan module is
completely pulled out, as shown in Figure 4-71.
Figure 4-71 Pull out the fanmodule
4. Hold the handle on the new fan module with one hand and support the
bottom of the fan module with the other hand. Then, insert the fan module
into the chassis, as shown in Figure 4-72.
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Figure 4-72 Insert the fan module
5. Verify the function of the new fan module.
In normal situations, after the new fan module is inserted into the chassis, the
fans inside it immediately start to roatate. In this case, you can check whether
the new fan module functions normally in the following manners:
– If the FAN indicator on the panel of the fan module is on and green, it
indicates that the fan module runs normally.
If the indicator is red, it indicates that the fan module fails to run normally. If
the new fan module fails to return to the normal state, contact Huawei
technical personnel.
Follow-up Procedure
After replacing a part, collect the tools. If the part is faulty, maintenance personnel
should fill in the Offsite Repair Card for Faulty Materials, and send the card and
the faulty part to Huawei for timely maintenance.
4.1.13.4 Replacing an Optical Module
Context
CA UTION
Laser beams will cause eye damage. Do not look into bores of Optical Modules or
optical fibers without eye protection.
NO TICE
● Huawei-certified Optical Modules are strongly recommended because non-
Huawei-certified Optical Modules cannot ensure transmission reliability and
may affect service stability.
● Optical Modules are hot swappable, and you do not need to power off the
device when replacing Optical Modules.
● Optical Modules are electrostatic-sensitive components. Therefore, you must
take ESD protection measures when replacing Optical Modules.
● Only external Optical Modules can be replaced and pluggable. Built-in Optical
Modules cannot be replaced.
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Follow these guidelines when replacing an Optical Module:
● Replacing an Optical Module interrupts service transmission. Therefore,
replace an Optical Module only when you confirm that the Optical Module
has failed.
● Ensure that the new Optical Module has the same center wavelength and
complies with the same standards as the old one.
● When replacing an Optical Module, ensure that no optical fiber is connected
to the Optical Module. Install or remove optical fibers carefully to avoid
damages to fiber connectors. Exercise caution when installing or removing
optical fibers to prevent damage to the Optical Module.
● After removing the optical fibers from an Optical Module, cover the fiber
connectors with dust caps. Place the optical fibers in an appropriate place to
prevent them from swinging.
● Use assistant tools like the tweezers delivered with the device to remove an
Optical Module in a confined space.
● After removing a copper transceiver, wait at least 2 seconds before inserting a
new one. Otherwise, the port may fail to go Up. If the port cannot go Up,
remove the copper transceiver and install it 2 seconds later.
● If the LINK indicator on an optical port with two optical fibers is off, swap the
two optical fibers.
● During the replacement, keep the bores of the Optical Module and fiber
connectors clean, protecting them from dust and other contamination
sources. Install dust plugs on idle optical ports.
Tools and Accessories
● ESD wrist strap or ESD gloves
● Spare Optical Module
● Dust caps
● (Optional) Optical port dust plug
● (Optional) Tweezers
Procedure
1. Check the location of the Optical Module to be replaced.
Before pulling out an Optical Module that is to be replaced, you should first
check the location of the module, for example, the cabinet and chassis where
the Optical Module resides. Then, locate the Optical Module to be replaced in
the chassis and attach a label to the panel to identify the Optical Module.
2. Run the display interface interface-type interface-number command to view
and record the type of the Optical Module to be replaced, as the following
output in bold displays:
<HUAWEI> display interface Gigabitethernet0/1/0
GigabitEthernet0/1/0 current state : DOWN
Line protocol current state : DOWN
Description: HUAWEI, GigabitEthernet0/1/0 Interface (ifindex: 7)
Route Port,The Maximum Transmit Unit is 1500
IP Sending Frames' Format is PKTFMT_ETHNT_2, Hardware address is 001a-2b11-4d51
The Vendor PN is RTXM191-400
The Vendor Name is WTD
Port BW: 1G, Transceiver max BW: 1G, Transceiver Mode: SingleMode
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WaveLength: 1310nm, Transmission Distance: 10km
Rx Power: -1.43dBm, normal range: [-19.014, -3.000]dBm
Tx Power: -4.86dBm, normal range: [-6.859, -2.857]dBm
Loopback:none, full-duplex mode, negotiation: disable, Pause Flowcontrol:Receive Enable and
Send Enable
Last physical up time : 2012-10-11 10:01:20
Last physical down time : 2012-10-11 10:01:19
Current system time: 2012-10-12 09:53:44
Statistics last cleared:2012-10-12 09:02:03
Last 300 seconds input rate: 0 bits/sec, 0 packets/sec
Last 300 seconds output rate: 0 bits/sec, 0 packets/sec
Input peak rate 88 bits/sec, Record time: 2012-10-12 09:03:45
Output peak rate 78 bits/sec, Record time: 2012-10-12 09:02:54
Input: 2144 bytes, 22 packets
Output: 614 bytes, 7 packets
Input:
Unicast: 21 packets, Multicast: 1 packets
Broadcast: 0 packets, JumboOctets: 0 packets
CRC: 0 packets, Symbol: 0 packets
Overrun: 0 packets, InRangeLength: 0 packets
LongPacket: 0 packets, Jabber: 0 packets, Alignment: 0 packets
Fragment: 0 packets, Undersized Frame: 0 packets
RxPause: 0 packets
Output:
Unicast: 6 packets, Multicast: 1 packets
Broadcast: 0 packets, JumboOctets: 0 packets
Lost: 0 packets, Overflow: 0 packets, Underrun: 0 packets
System: 0 packets, Overruns: 0 packets
TxPause: 0 packets
Last 300 seconds input utility rate: 0.00%
Last 300 seconds output utility rate: 0.00%
3. Record the location of the cables and check whether the labels on the cables
are correct and clear. If the labels are hard to identify, re-make labels and re-
label the cables in case the cables are not connected properly.
4. Wear the ESD gloves or wrist strap and connect the grounding terminal to the
ESD jack on the rack.
5. Pull out the Optical Module to be replaced.
a. Remove the optical cables from the connector and cover the connector
with a dust cap.
b. Pull the bail-clasp or pull-tab latch on the optical module, as shown in
Figure2 and Figure3 respectively.
NO TE
When the operation space is insufficient, you can use a fiber interface clamp to
remove an Optical Module. Figure1 shows the appearance of a fiber interface
clamp.
Figure 4-73 Fiber interface clamp
c. Hold the handle to pull out the Optical Module carefully from the optical
interface, as (2) shown in Figure2. When installing a CFP Optical Module,
hold the screw rods with both hands, and slightly pull out the Optical
Module from the optical port.
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CA UTION
The QSFP28 and QSFP-DD modules will get very hot during operation. To
prevent injuries, do not touch the module shells when removing the
modules.
d. Place the removed Optical Module in the ESD bag.
Figure 4-74 Pulling out an bail-clasp Optical Module
Figure 4-75 pull-tab latchPulling out an Optical Module
6. Insert the new Optical Module into the optical interface.
a. Take out the new Optical Module from the ESD bag and check whether
there is any damage or component missing. Check whether the new
Optical Module is of the same type as the Optical Module to be replaced.
b. Insert the new Optical Module into the optical interface, as shown in
Figure 4-76. When the click of the reed in the Optical Module is heard, it
indicates that the Optical Module is correctly inserted. If the new Optical
Module is a CFP one, insert the new Optical Module into the optical port
of the card, push the transceiver panel horizontally into the connector
using even force with both thumbs. After the transceiver is inserted, push
the transceiver slightly to ensure that it has reached the stop position.
Pull out the two screw rods slightly to ensure that they can properly
function. Pre-tighten one of the screw rods. Then, tighten the other screw
rod. After that, tighten the first screw rod. To prevent the Optical Module
from getting loosened due to vibration or collision, you are advised to use
a screwdriver to tighten the screw rods.
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CA UTION
Do not insert an Optical Module reversely. If an Optical Module cannot
be completely inserted into an optical port, do not force it into the port.
Instead, turn the Optical Module over and try again.
Figure 4-76 Inserting an Optical Module
c. Remove the dust cap from the connector and insert the optical cables in
the original sequence.
7. Verify the functions of the new Optical Module.
Then, you can verify the functions of the new Optical Module in the following
ways:
– Check whether the LINK indicator on the optical interface works
normally. If the indicator is green, it indicates that the links connected to
the interface are Up.
– Run the display interface interface-type interface-number command on
the console interface to view the type and running status of the new
Optical Module. Check whether the type of the new Optical Module
corresponds to that of the original Optical Module, as the following
output in bold displays:
<HUAWEI> display interface Gigabitethernet0/1/0
GigabitEthernet0/1/0 current state : DOWN
Line protocol current state : DOWN
Description: HUAWEI, GigabitEthernet0/1/0 Interface (ifindex: 7)
Route Port,The Maximum Transmit Unit is 1500
IP Sending Frames' Format is PKTFMT_ETHNT_2, Hardware address is 001a-2b11-4d51
The Vendor PN is RTXM191-400
The Vendor Name is WTD
Port BW: 1G, Transceiver max BW: 1G, Transceiver Mode: SingleMode
WaveLength: 1310nm, Transmission Distance: 10km
Rx Power: -1.43dBm, normal range: [-19.014, -3.000]dBm
Tx Power: -4.86dBm, normal range: [-6.859, -2.857]dBm
Loopback:none, full-duplex mode, negotiation: disable, Pause Flowcontrol:Receive Enable
and Send Enable
Last physical up time : 2012-10-11 10:01:20
Last physical down time : 2012-10-11 10:01:19
Current system time: 2012-10-12 09:53:44
Statistics last cleared:2012-10-12 09:02:03
Last 300 seconds input rate: 0 bits/sec, 0 packets/sec
Last 300 seconds output rate: 0 bits/sec, 0 packets/sec
Input peak rate 88 bits/sec, Record time: 2012-10-12 09:03:45
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Output peak rate 78 bits/sec, Record time: 2012-10-12 09:02:54
Input: 2144 bytes, 22 packets
Output: 614 bytes, 7 packets
Input:
Unicast: 21 packets, Multicast: 1 packets
Broadcast: 0 packets, JumboOctets: 0 packets
CRC: 0 packets, Symbol: 0 packets
Overrun: 0 packets, InRangeLength: 0 packets
LongPacket: 0 packets, Jabber: 0 packets, Alignment: 0 packets
Fragment: 0 packets, Undersized Frame: 0 packets
RxPause: 0 packets
Output:
Unicast: 6 packets, Multicast: 1 packets
Broadcast: 0 packets, JumboOctets: 0 packets
Lost: 0 packets, Overflow: 0 packets, Underrun: 0 packets
System: 0 packets, Overruns: 0 packets
TxPause: 0 packets
Last 300 seconds input utility rate: 0.00%
Last 300 seconds output utility rate: 0.00%
– Check whether there is any new alarm or performance event.
– Check whether the services are normal on the new Optical Module. If the
services are normal, it indicates that replacing an Optical Module is
successful.
If the new Optical Module fails to return to the normal state, you should
contact a Huawei local office for timely technical support.
Follow-up Procedure
After replacing an Optical Module, collect the tools. If an Optical Module that is
replaced and is confirmed to be faulty, you should fill in the Offsite Repair Card
for Faulty Materials, and send the card and the faulty Optical Module to a Huawei
local office for timely maintenance.
4.1.13.5 Replacing an Optical Cable
Context
Before replacing an optical cable, you need to note the flowing points:
● During the process of replacing an optical cable, the services are interrupted
temporarily.
● Be careful when you remove or insert an optical cable in case that the
connector of the optical cable is damaged.
● When installing or maintaining an optical interface board or an optical cable,
do not observe an optical interface or connectors of an optical cable.
● The bending radius of a single-mode G.657A2 optical fiber is greater than or
equal to 10 mm, and the bending radius of a multi-mode A1b optical fiber is
greater than or equal to 30 mm.
● Connectors of optical cables are divided into the LC type and the SC type. You
must select an optical cable according to the interface type.
Tool
Before replacing an optical cable, you need the following tools:
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● Cutter
● Binding strap
● ESD wrist strap or ESD glove
Procedure
1. Record the location of both ends of the optical cable to be replaced and the
cabling mode.
2. Take out the new optical cable and check whether the type of the new optical
cable is consistent with that of the old one. The multi-mode optical cable is
orange and the single-mode optical cable is yellow.
3. Make a new label according to the contents of the label on the old optical
cable.
4. Lay out the new optical cable in the original place.
5. Remove the old optical cable.
a. Put on the ESD gloves or wrist strap and connect the grounding terminal
to the ESD jack on the rack.
b. Hold the connectors and remove them. Then, cover the connectors with
dust caps.
NO TE
If a connector is dusty, clean it with dust-free cloth or fiber cleaning paper.
c. Remove the old optical cable from the corrugated pipe.
6. Insert the new optical cable.
Before inserting the new optical cable, remove the dust caps and keep them
properly for future use. Then, connect both ends of the new optical cable to
the optical interfaces and secure the optical cables.
7. Attach a label to the new optical cable, as shown in Figure 4-77.
Figure 4-77 Attaching a label to a new optical cable
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8. Lay out the new optical cable in a tidy manner in the cabinet and bind the
optical cable with a binding strap. Note that the optical cable should be
bound with proper strength and with even space in between. Bind the
redundancies of the optical cable at the ODF side.
9. Check whether the new optical cable works normally.
a. Check the LINK indicator at the optical interface. If the indicator is steady
on and green, it indicates that the link is Up.
b. Check whether the service on the board where the new optical cable
connects is normal. If the services are normal, it indicates that the optical
cable is replaced successfully.
c. Check whether there is any new alarm or performance event.
Follow-up Procedure
After replacing an optical cable, collect the tools and the replaced optical cable.
Do not place the old and the new optical cables together to avoid confusions.
4.1.13.6 Replacing a Network Cable
Context
Before replacing a network cable, you need to note the following points:
● During the process of replacing a network cable, the services are interrupted
temporarily.
● It is recommended that you replace a network cable during the hours when
the network is not busy, for example, from 00:00 am to 06:00 am.
Tool
Before replacing a network cable, you need the following tools:
● Cutter
● Cable tie
● ESD wrist strap or ESD glove
● Cable tester
● Crimper
Procedure
1. Check the location and cabling of the network cable to be replaced.
2. Prepare a new network cable. The type of the new network cable must be
consistent with that of the old network cable. When a network cable is made,
test its connectivity with a cable tester.
3. Wear the ESD gloves or wrist strap and connect the grounding terminal to the
ESD jack on the rack.
4. Lay out the new network cable according to the original cabling mode.
If you need to replace more than one network cable at a time, you should
attach temporary labels to the new network cables to identify the cables. The
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new network cables must be numbered consistently with the network cables
to be replaced.
5. Remove the old network cable and record the location where the old network
cable is installed.
a. Remove the connectors of the network cable.
b. Cut the cable tie with a cutter and remove the network cable.
6. Insert the new network cable connector into the network interface of which
the location is recorded. If a click is heard, it indicates that the insertion is
successful. The indicator of the network interface being steady on and green
indicates that the link is Up.
7. Attach a label to the new network cable, as shown in Figure 4-78.
Figure 4-78 Attaching a label to a new network cable
8. Bind the cable with a cable tie and cut the redundancies of the tie.
9. Run the ping command to check the connection between both ends of the
new network cable. If both ends fail to communicate normally, check whether
the network cable is damaged or whether the connectors are secured.
Follow-up Procedure
After replacing a network cable, collect the tools and the replaced cable. Do not
place the old and the new cables together to avoid confusions.
4.1.14 Appendix
4.1.14.1 On-site Cable Assembly and Installation
4.1.14.1.1 Cable Assembly Precautions
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Checking the Appearance of Cables
● If the cable jacket or insulation is visibly dirty, clean it before assembly.
● If the jacket or insulation of a cable has visible damage, irreparable scuffing,
or other defects, do not use the cable.
● If the shield layer of a cable is damaged, do not use the cable.
● If the cable jacket or insulation cracks after the cable is bent or twisted,
discard this cable and check whether other cables have the same problem. If
other cables have the same problem, replace these cables.
Checking the Appearance of Connectors
● Do not use connectors with visible defects, damage, rust, or scuffing.
● Do not use connectors if their shells or pins have exposed part or uneven
plating, or their pins are lost, broken, or bent.
● Do not use connectors that have dirt on their pins or in their jacks or if there
are conductors between pins or between pins and the shell.
Precautions for Assembly
● Use dedicated tools or tools delivered by Huawei and follow the methods
given here during assembly.
● Hold terminals of cables instead of pulling the cables themselves when
installing or removing cable components.
● Take the following precautions when cutting or stripping cables:
– Make cables slightly longer than necessary.
– Coil cables longer than 2 m (6.56 ft) after cutting. Bind and fasten the
coils using bundling ropes. The inner diameters of the coils should be
larger than 20 times the outer diameters of the cables.
– When stripping the jackets of cables, avoid damaging the shield layers
(braid or aluminum foil), insulation, core conductors, and other jackets
that do not need to be stripped.
– After assembling cables, cut all visible cross sections of jackets to ensure
that the cross sections are arranged neatly.
– Do not touch the core conductors of cables with your hands. Terminate
exposed conductors in a timely way after stripping off insulation so that
the surface of the conductors does not become oxidized.
● Take the following precautions when crimping and connecting cables or
connectors:
– The terminals and conductors should be connected tightly after they are
crimped. They should not be moved or turned.
– Cut all the exposed copper wires.
– Try to avoid a second crimping of sleeves.
– Keep all the conductors clean and aligned.
NO TE
The connectors, cables, and tools provided by different vendors may be different. The
figures in this document are for your reference only.
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4.1.14.1.2 Assembling Power Cables
Assembling the OT Terminal and Power Cable
Background
Figure 4-79 shows the components of an OT terminal and a power cable.
Figure 4-79 the components of an OT terminal and a power cable
A. Heat shrink B. Bare crimping C. Insulation D. Conductor
tubing terminal
Procedure
1. Based on the cross-sectional area of the cable conductor, strip a length of
insulation coating C to expose the conductor D of length L1, as shown in
Figure 4-80. The recommended values of L1 are listed in Table 4-18.
Figure 4-80 Stripping a power cable (OT terminal)
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NO TICE
● When you strip a power cable, do not damage the conductor of the cable.
● If the bare crimping terminal is not provided by Huawei, the value of L1 is
1 mm (0.04 in.) to 2 mm (0.08 in.) greater than the value of L.
Table 4-18 Mapping between the cross-sectional area of the conductor and
the value of L1
Cross- Value of L1 (mm Cross-Sectional Value of L1 (mm
Sectional (in.)) Area of (in.))
Area of Conductor (mm2
Conductor (in.2))
(mm2 (in.2))
1 (0.002) 7 (0.28) 10 (0.015) 11 (0.43)
1.5 (0.002) 7 (0.28) 16 (0.025) 13 (0.51)
2.5 (0.004) 7 (0.28) 25 (0.039) 14 (0.55)
4 (0.006) 8 (0.31) 35 (0.054) 16 (0.63)
6 (0.009) 9 (0.35) 50 (0.077) 16 (0.63)
NO TE
If you are proficient in assembling OT terminals and power cables, you can obtain the
value of L1 by comparing the part to be crimped with the power cable.
2. Put the heat-shrinkable (A) tubing onto the bare crimping terminal, as shown
in Figure 4-81.
Figure 4-81 Putting the heat shrink tubing onto the bare crimping terminal
3. Put the OT terminal B onto the exposed conductor, and ensure that the OT
terminal is in good contact with the insulation coating C, as shown in Figure
4-81.
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NO TICE
After the conductor is fed into the OT terminal, the protruding part of the
conductor, or L2 in Figure 4-81, must not be longer than 2 mm (0.08 in.).
4. Crimp the joint parts of the bare crimping terminal and the conductor, as
shown in Figure 4-82.
NO TE
The shapes of crimped parts may vary with the crimping dies.
Figure 4-82 Crimping the joint parts of the bare crimping terminal and the
conductor (OT terminal)
5. Push the heat shrink tubing (A) toward the connector until the tube covers
the crimped part, and then use a heat gun to heat the tube, as shown in
Figure 4-83.
Figure 4-83 Heating the heat shrink tubing (OT terminal)
NO TICE
Stop heating the shrink tubing when the connector is securely locked in the
shrink tubing. Do not heat the shrink tubing too long as this may damage the
insulation coating.
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Assembling the JG2 Terminal and Power Cable
Bacnground
Figure 4-84 shows the components of a JG2 terminal and a power cable.
Figure 4-84 Components of a JG2 terminal and a power cable
A. Heat shrink B. JG2 terminal C. Insulation layer D. Conductor of a
tubing of a power cable power cable
Procedure
1. Strip a part of the insulation to expose the cable conductor with a length of L,
as shown in Figure 4-85. The recommended values of L are listed in Table
4-19.
Figure 4-85 Stripping a power cable (JG2 terminal)
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NO TICE
● When you strip a power cable, do not damage the conductor of the cable.
● If the bare crimping terminal is not provided by Huawei, you can adjust the
value of L as required
Table 4-19 Mapping between the cross-sectional area of the conductor and
the value of L
Cross-Sectional Area of Conductor Value of L (mm (in.))
(mm2 (in.2))
16 (0.025) 13 (0.51)
25 (0.039) 14 (0.55)
35 (0.054) 16 (0.63)
2. Put the heat shrink tubing onto the bare crimping terminal, as shown in
Figure 4-86.
Figure 4-86 Putting the heat shrink tubing onto the bare crimping terminal
3. Put the bare crimping terminal onto the exposed conductor, and ensure that
the bare crimping terminal is in good contact with the insulation of the power
cable, as shown in Figure 4-86.
4. Crimp the joint parts of the bare crimping terminal and the conductor, as
shown in Figure 4-87.
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Figure 4-87 Crimping the joint parts of the bare crimping terminal and the
conductor (JG2 terminal)
5. Push the heat shrink tubing toward the connector until the tube covers the
crimped part, and then use a heat gun to heat the tube, as shown in Figure
4-88.
Figure 4-88 Heating the heat shrink tubing (JG2 terminal)
Assembling the Cord End Terminal and Power Cable
Background
Figure 4-89 shows the components of a cord end terminal and a power cable.
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Figure 4-89 Components of a cord end terminal and a power cable
A. Cord end terminal B. Insulation layer of a C. Conductor of a power
power cable cable
Procedure
1. Strip a part of the insulation layer to expose the cable conductor with a
length of L1, as shown in Figure 4-90. Determine the value of L1 based on
the cross-sectional area of the cable conductor. The recommended values of
L1 are listed in Table 4-20.
NO TICE
When you strip a power cable, do not damage the conductor of the cable.
Figure 4-90 Stripping a power cable (cord end terminal)
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Table 4-20 Mapping between the cross-sectional area of the conductor and
the value of L1
Cross- Value of L1 (mm Cross-Sectional Value of L1 (mm
Sectional (in.)) Area of (in.))
Area of Conductor (mm2
Conductor (in.2))
(mm2 (in.2))
1 8 10 15
1.5 10 16 15
2.5 10 25 18
4 12 35 19
6 14 50 26
2. Put the cord end terminal onto the exposed conductor and ensure that the
conductor is aligned with the edge of the cord end terminal, as shown in
Figure 4-91.
NO TICE
After the conductor is fed into the cord end terminal, the protruding part of
the conductor must not be longer than 1 mm (0.04 in.).
Figure 4-91 Putting the cord end terminal onto the conductor
3. Select a proper cross-sectional area, and crimp the joint parts of the cord end
terminal and the conductor, as shown in Figure 4-92.
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Figure 4-92 Crimping the joint parts of the cord end terminal and the
conductor
4. Check the maximum width of the crimped terminal. Table 4-21 lists the
maximum width of a crimped terminal.
Table 4-21 Maximum width of a crimped terminal
Cross-Sectional Area of the Maximum Width of the Crimped
Terminal (mm2) Terminal — W1 (mm(in.))
0.25 1
0.5 1
1.0 1.5
1.5 1.5
2.5 2.4
4 3.1
6 4
10 5.3
16 6
25 8.7
35 10
Assembling an SPC1 Connector and the Power Cable
Context
NO TE
Colors and exteriors of cables may vary with countries and regions.
Figure1shows an SPC1 connector.
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Figure 4-93 Connector
(1) SPC1 (2) Scale (3) Hole for the cable
Procedure
1. Strip the jacket off the cable according to the scale on the connector, as
shown in Figure2.
NO TICE
● The figure for stripping the jacket shows the minimum length of the jacket
to be stripped off the cable.
● Ensure that the wires do not split during cable stripping.
Figure 4-94 Stripping the jacket off the cable
2. Insert the positive conducting wire to hole 1 (+) and the negative conducting
wire to hole 2 (–), as shown in Figure3.
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NO TICE
● Before power-on, check whether the positive and negative conducting
wires of all power cables are correctly connected. Any incorrect power
cable connection may cause damage to equipment or unexpected injuries
of human body.
● If the conducting wires are inserted properly, you will hear two click
sounds.
● When a cable is connected to an SPC1 connector, if the connector is not
removed and the cable is reversely connected, the following issues may
occur: sparking, fuse blowout, and connector damage. Therefore, remove
the SPC1 connector before the cable connection.
NO TE
The cross-sectional area of the cable supported by the SPC1 connector ranges from 1.5
mm2 to 10 mm2 or 0.0023 in.2 to 0.016 in.2.
Figure 4-95 Inserting the conducting wires
3. After the conducting wires are inserted, check whether they are secured by
springs from the visible window, as shown in Figure4. Pull each conducting
wire slightly to check whether it is securely connected. If the conducting wire
is pulled out a bit or a spring presses the insulation layer, remove and cut the
split conducting wire, and then strip the jacket and install the conducting wire
again.
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Figure 4-96 Checking whether conducting wires are secured by springs from
the visible window
NO TICE
● A conducting wire cannot deviate from the hole center, as shown in
Figure5.
● Ensure that the conducting wire is aligned with the cable hole, and avoid
the situation shown in Figure6.
Figure 4-97 Wire deviating from the hole center
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Figure 4-98 Wires not aligned with the holes
4.1.14.1.3 Assembling Ethernet Cables
Assembling the Shielded RJ45 Connector and Ethernet Cable
Background
Figure 4-99 shows the components of an RJ45 connector and a shielded Ethernet
cable.
Figure 4-99 Shielded RJ45 connector and cable
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A. Jacket of B. Metal shell of C. Wire holder of D. Plug of
connector connector connector connector
E. Jacket of F. Shield layer of G. Twisted-pair -
Ethernet cable Ethernet cable wires
Procedure
1. Fit the jacket of the connector onto the Ethernet cable, as shown in Figure
4-100.
Figure 4-100 Fitting the jacket of the connector onto the Ethernet cable
2. Remove a 30 mm (1.18 in.) long section of the jacket, cut off the nylon twine
inside the jacket, and cut a no more than 5 mm (0.20 in.) cleft in the jacket,
as shown in Figure 4-101.
Figure 4-101 Removing the jacket of a twisted-pair cable (unit: mm (in.))
NO TICE
● When you remove a section of the jacket, do not damage the shield layer
of the twisted-pair cable.
● When you remove the shield layer, do not damage the insulation of the
twisted-pair cable.
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3. Fit the metal shell onto the twisted-pair cable. The shield layer is covered by
the metal shell, as shown in Figure 4-102.
Figure 4-102 Fitting the metal shell onto the twisted-pair cable
4. Fit the metal shell onto the twisted-pair cable until the shield layer is covered
completely. Along the edge of the metal shell, cut off the aluminum foil shield
layer and ensure that there is no surplus copper wire. The exposed twisted-
pair cable is about 20 mm (0.79 in.) long, as shown in Figure 4-103.
Figure 4-103 Removing the shield layer of a twisted-pair cable (unit: mm
(in.))
5. Lead the four pairs of twisted-pair wires through the wire holder, as shown in
Figure 4-104 and Figure 4-105. Ensure that the colored wires are in the
correct location in the cable.
Figure 4-104 Leading wires through the wire holder
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Figure 4-105 Cable locations in a wire holder
6. Align the four pairs of cables in the holder, as shown in Figure 4-106. The
connections between the wires and the pins are shown in Figure 4-107 and
listed in Table 4-22.
Figure 4-106 Four pairs of cables on a wire holder
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Figure 4-107 Connections between wires and pins
Table 4-22 Connections between wires and pins (using a straight-through
cable as an example)
Matching Pins of Wires Wire Color
1 White-Orange
2 Orange
3 White-Green
4 Blue
5 White-Blue
6 Green
7 White-Brown
8 Brown
7. Cut off the surplus cables along the lower edge of the wire holder, as shown
in Figure 4-108.
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Figure 4-108 Cutting off surplus cables
8. Put the connector body onto the wire holder and turn the metal shell by 90°,
as shown in Figure 4-109.
Figure 4-109 Putting the connector body onto the wire holder
NO TE
Ensure that the wire holder is in good contact with the connector body.
9. Push the metal shell toward the connector body until the wire holder and the
connector body are engaged completely. Crimp the connector, as shown in
Figure 4-110.
Figure 4-110 Crimping the connector
10. Push the jacket towards the metal shell until the metal shell is covered. This
completes the assembly of one end of the cable, as shown in Figure 4-111.
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Figure 4-111 Pushing the metal shell
11. To complete the assembly of the other end, repeat steps 1 to 10.
Assembling an Unshielded RJ45 Connector and Ethernet Cable
Background
Figure 4-112 shows the components of an unshielded RJ45 connector and cable.
Figure 4-112 Components of an unshielded RJ45 connector and cable
A. Plug of connector B. Jacket C. Twisted-pair wires
Procedure
1. Remove a 16-mm (0.63 in.) long section of the jacket, as shown in Figure
4-113.
NO TICE
When you remove the shield layer, do not damage the insulation of the
twisted-pair cable.
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Figure 4-113 Removing the jacket of a twisted-pair cable (unit: mm (in.))
2. Align the four pairs of wires and cut the ends neatly, as shown in Figure
4-114. The connections between the wires and the pins are listed in Table
4-23.
Figure 4-114 Connections between wires and pins (unit: mm (in.))
Table 4-23 Connections between wires and pins (using a straight-through
cable as an example)
Matching Pins of Wires Wire Color
1 White-Orange
2 Orange
3 White-Green
4 Blue
5 White-Blue
6 Green
7 White-Brown
8 Brown
3. Feed the cable into the plug, and crimp the connector, as shown in Figure
4-115.
NO TE
When inserting the cable, check from the side or bore of the plug to ensure that the
cable is completely seated in the plug.
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Figure 4-115 Crimping the connector
4. To complete the assembly of the other end, repeat steps 1 to 3.
Checking the Appearance of Contact Strips
Background
● To ensure proper contact between the crimped wires and the wire conductors,
the heights and sizes of the contact strips must be standard and the same.
● The contact strips must be parallel to each other, with an offset of less than ±
5°. The top margin of a strip must be parallel to the axis of the connector,
with an offset of less than ± 10°.
● To ensure conductivity, the surface of the contact strips must be clean.
● The contact strips must be in good contact with the RJ45 socket. The plastic
separators must remain intact and be aligned.
● The contact strip blade must extend beyond the ends of the wires. The ends
of the wires must be in contact with the edge of the RJ45. The distance
between them must be less than 0.5 mm (0.02 in.).
Procedure
1. Hold the crimped connector, with the front side facing you, and check
whether the contact strips are of the same height. The height should be 6.02
± 0.13 mm (0.237 ± 0.005). If a measuring tool is not available, you can
compare the connector with a standard connector. Figure 4-116 shows an
unqualified piece, and Figure 4-117 shows a qualified piece.
NO TE
All unqualified pieces must be crimped again.
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Figure 4-116 Contact strips of different heights
Figure 4-117 Contact strips of the same height
2. Hold an RJ45 connector and turn it 45°. Observe the top edges of the metal
contact strips. Figure 4-118 shows an unqualified piece.
Figure 4-118 Unparallel contact strips of different heights
3. Check whether the contact strips are clean. If they are not clean and the dirt
cannot be removed, replace it with a new RJ45 connector. Figure 4-119 shows
an unqualified piece.
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Figure 4-119 Dirt on a contract strip
4. Check whether the contact strips and the plastic separators are well aligned
and intact. If a separator is skewed and cannot be fixed, replace it with a new
RJ45 connector. Figure 4-120 shows an unqualified piece.
Figure 4-120 Skewed plastic separators
5. Hold the connector with the side facing towards you, and check whether you
can see the cross-sections of the wires. Ensure that the ends of the wires are
in good contact with the edge of the RJ45, and that the contact strip blade
extends beyond the ends of the wires and is crimped with the wires. If not,
replace the connector. Figure 4-121 shows an unqualified piece.
Figure 4-121 Wires not in good contact with the edge of the RJ45
Testing the Connection of Assembled Cables
Background
Huawei provides two types of Ethernet cables: straight-through cables and
crossover cables.
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● Straight-through cables are connected in a one-to-one manner. They are used
to connect terminals such as a computer or switch to network devices. Table
Pin assignment of the straight-through cable connector lists the
connections of core wires in a straight-through cable.
Table 4-24 Pin assignment of the straight-through cable connector
Connector X1 Connector X2 Color Relation
Pin Pin
X1.1 X2.1 White-orange Twisted pair
X1.2 X2.2 Orange
X1.3 X2.3 White-green Twisted pair
X1.6 X2.6 Green
X1.4 X2.4 Blue Twisted pair
X1.5 X2.5 White-blue
X1.7 X2.7 White-brown Twisted pair
X1.8 X2.8 Brown
● Crossover cables are connected in a crossover manner. They are used to
connect terminals such as two computers or switches. Table Pin assignment
of the crossover cable connector lists the connections of core wires in a
crossover cable
Table 4-25 Pin assignment of the crossover cable connector
Connector X1 Connector X2 Color Relation
Pin Pin
X1.1 X2.3 White-orange Twisted pair
X1.2 X2.6 Orange
X1.3 X2.1 White-green Twisted pair
X1.6 X2.2 Green
X1.4 X2.4 Blue Twisted pair
X1.5 X2.5 White-blue
X1.7 X2.7 White-brown Twisted pair
X1.8 X2.8 Brown
Figure 4-122 shows the pins of an RJ45 connector.
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Figure 4-122 Pins of an RJ45 connector
Procedure
1. Feed both connectors of the cable into the ports of the cable tester.
2. After the connectors are properly inserted, turn on the tester. If the indicators
from 1 to G turn on simultaneously, you can infer that the pins work normally
and the wires are correctly connected.
NO TE
Turn the switch to the S position to slow down lighting of the indicators so that you
can see the indicators more clearly, as shown in Figure 4-123.
Figure 4-123 Testing the conduction and connections of wires
3. Gently shake the connector and repeat Step 2 to check whether the metal
contact strips are in good contact with the core wires and Ethernet ports, as
shown in Figure 4-124.
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Figure 4-124 Checking the reliability
The procedure for testing a crossover cable is the same as that for testing a
straight-through cable except for the sequence in which the indicators turn
on, which depends on the wire connections of a crossover cable.
The Ethernet cable is qualified if the indicators turn on in the following
sequence:
At the master (left) section of the tester, the indicators turn on in the
sequence of 1-8-G. At the slave (right) section of the tester, the indicators
turn on in the sequence of 3-6-1-4-5-2-7-8-G.
If the indicators do not come on in this sequence, the Ethernet cable is
unqualified.
NO TE
If a tester is not available, you can use a multimeter to perform a simple test, as
shown in Figure 4-125.
Figure 4-125 Testing the connection of an Ethernet cable
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4.1.14.1.4 Installing Cable Accessories
Precautions for Installing Cable Accessories
NO TE
The illustrations in this document may differ from actual situations, but the installation
methods are the same. For example, in this document, the adapters of cable connectors
have separate interfaces. In the actual situation, the adapters may have interfaces fixed on
equipment.
Tools
Use dedicated tools provided or specified by Huawei and follow the installation
procedure described here.
Bending Radius
Unless otherwise specified, bending radius (R) of cables or fibers must meet the
requirements listed in Table 4-26.
Table 4-26 Bending radius of cables or fibers
Cable or Fiber Bending Radius (R)
Ordinary cable In normal cases, R ≥ 2d. When the
cable is connected with a connector, R
≥ 5d.
Fiber Single-mode G.657A2 optical fiber: R ≥
10 mm (0.39 in.), bending angle > 90°
Multi-mode A1b optical fiber: 30 mm
(1.18 in.) ≤ R ≤ 40 mm (1.57 in.),
bending angle > 90°
NO TE
The letter d indicates the diameter of a cable or fiber.
Precautions for Installation
● Hold terminals of cables instead of pulling the cables themselves when
installing or removing cable components.
● Do not insert a connector forcibly when the connector is blocked. Use a
dedicated tool to pull out the connector. Install the connector again after you
check that the pins are inserted properly.
● Before tightening screws on cable connectors, ensure that the connectors are
properly connected to their adapters. Tighten the screw with appropriate force
using a flat-head or Phillips screwdriver instead of bare hands or an electric
screwdriver. If the screw cannot be screwed into the tapped hole, determine
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the reason and try again. Do not apply too much force, or the screw or
adapter may be damaged.
● When removing densely aligned cables or fiber connectors, use dedicated
pliers such as cable-pulling pliers and fiber-pulling pliers.
● Do not twist, bend, stretch, or extrude fibers during installation.
● Cover the idle fiber connectors with dust caps. Remove the dust caps before
using the fiber connectors.
Requirements for Cable Routing
● To protect cables, remove the burrs in the cable through-holes or install
protective rings in the holes.
● To ease the connection and to avoid stress, keep cable joints slack. After
connecting multiple cables to a connector that has multiple interfaces, keep
the cables slack to avoid generating stress.
● Bind or clean cables gently because cable distortion affects signal quality.
● Keep cables away from moveable components such as doors.
● Sharp objects must not touch cable wiring to prevent damage to cables.
● To protect power cables, route power cables of the active and standby power
modules separately.
Installing Power Adapters
?.1. Installing the OT Terminal
This section describes how to install OT terminals on the terminals. You can install
one OT terminal or two OT terminals on one terminal.
Procedure
● Install an OT terminal.
a. Align the hole of the OT terminal (conductor upward) with a connecting
hole, as shown in Figure 4-126.
Figure 4-126 Aligning the OT terminal with a connecting hole
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NO TE
When you install an OT terminal, the crimping sleeve is installed as shown in
Figure 4-127, where A is correct and B is incorrect.
Figure 4-127 Installing an OT terminal, showing the orientation of
crimping sleeve
b. Place the spring washer and flat washer in turn, mount a matching screw,
and fasten it clockwise, as shown in Figure 4-128.
Figure 4-128 Installing two terminals back to back
NO TICE
Ensure that the OT terminal is not in contact with other terminals or
metal components.
c. Move the cable slightly and ensure that it is securely connected, as shown
in Figure 4-129.
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Figure 4-129 Installed OT terminal
● Install two OT terminals on a post.
Before you install two OT terminals on a post, ensure that the two terminals
can be installed on the post and that the electrical connecting pieces have a
large contact area. Two OT terminals can be installed using any of these
methods:
– Bend the upper OT terminal at a 45- or 90-degree angle, as shown in
Figure 4-130.
– Cross the two terminals, as shown in Figure 4-131.
Figure 4-130 Bending the upper OT terminal at a 45- or 90-degree angle
Figure 4-131 Crossing two terminals
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NO TICE
If the two terminals are different sizes, place the smaller one above the bigger
one. A maximum of two terminals can be installed on a post.
● To remove an OT terminal, loosen the screw counterclockwise.
4.1.14.1.5 Installing Ethernet Adapters
Installing a Shielded Ethernet Connector
Procedure
1. Hold the male and female connectors, with the male connector facing the
female connector, as shown in Figure 4-132.
Figure 4-132 Holding the male and female shielded connectors
2. Insert the male connector into the female connector, as shown in Figure
4-133.
Figure 4-133 Feeding the male shielded connector into the female shielded
connector
3. When you hear a click, the cable connector is completely inserted in the port.
(The clip on the cable connector pops up to fix the connector in the port.) Pull
the connector slightly and ensure that it is securely connected, as shown in
Figure 4-134.
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Figure 4-134 Installed shielded Ethernet connector
4. To remove an Ethernet connector, press the locking key and pull out the
connector, as shown in Figure 4-135.
Figure 4-135 Removing a shielded Ethernet connector
Installing an Unshielded Ethernet Connector
Procedure
1. Hold the male and female connectors, with the male connector facing the
female connector, as shown in Figure 4-136.
Figure 4-136 Holding the male and female unshielded connectors
2. Feed the male connector into the female connector, as shown in Figure
4-137.
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Figure 4-137 Feeding the male connector into the female unshielded
connector
3. A crisp click indicates that the connector is locked by the locking key. Pull the
connector slightly and ensure that it is securely connected. Figure 4-138
shows an installed Ethernet connector.
Figure 4-138 Installed unshielded Ethernet connector
4. To remove an Ethernet connector, press the locking key and pull out the
connector, as shown in Figure 4-139.
Figure 4-139 Removing an unshielded Ethernet connector
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4.1.14.1.6 Installing Fiber Connectors
NO TE
● After you remove the dustproof cap, ensure that the fiber pins are clean and install
them as soon as possible.
● When you disassemble fiber connectors, you must use a dedicated tool if the connectors
are densely installed. Do not pull fiber protection pipes to remove fiber connectors.
Installing an FC Fiber Connector
Procedure
1. Remove the dustproof cap of the FC connector and store it for future use.
2. Align the core pin of the male connector with that of the female connector, as
shown in Figure 4-140.
Figure 4-140 Aligning the male connector with the female connector
3. Align the male connector with the female connector and gently push the
male connector until it is completely seated in the female connector, as
shown in Figure 4-141.
Figure 4-141 Feeding the male connector into the female connector
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4. Fasten the locking nut clockwise and ensure that the connector is securely
installed, as shown in Figure 4-142.
Figure 4-142 Fastening the locking nut
5. To disassemble an FC fiber connector, loosen the locking nut
counterclockwise, and gently pull the male connector, as shown in Figure
4-143.
Figure 4-143 Disassembling an FC fiber connector
Installing an LC Fiber Connector
Procedure
1. Remove the dustproof cap of the LC fiber connector and store it for future
use.
2. Align the core pin of the male connector with that of the female connector, as
shown in Figure 4-144.
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Figure 4-144 Aligning the male connector with the female connector
3. Align the male connector with the fiber adapter and gently push the male
connector until it is completely seated in the fiber connector, as shown in
Figure 4-145.
Figure 4-145 Feeding the male connector into the female connector
4. A clicking sound indicates that the male connector is locked, as shown in
Figure 4-146.
Figure 4-146 Installed LC connector
5. To disassemble an LC fiber connector, press the locking nut to release the
locking clips from the bore, and gently pull the male connector, as shown in
Figure 4-147.
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Figure 4-147 Disassembling an LC fiber connector
Installing an SC Fiber Connector
Procedure
1. Remove the dustproof cap of the SC fiber connector and store it for future
use.
2. Align the core pin of the male connector with that of the female connector, as
shown in Figure 4-148.
Figure 4-148 Aligning the male connector with the female connector
3. Feed the fiber connector into the female connector, with your fingers holding
the shell of the fiber connector (not the pigtail). When you hear a click, the
fiber connector is secured by the clips (internal parts, not illustrated in the
figure). Pull the fiber connector gently. If the connector does not loosen, the
installation is complete. As shown in Figure 4-149.
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Figure 4-149 Installed SC fiber connector
4. To disassemble an SC fiber connector, hold the shell of the connector (do not
hold the fiber) and gently pull the connector in the direction vertical to the
adapter. Unlock the male connector, and then separate it from the shell, as
shown in Figure 4-150.
Figure 4-150 Disassembling an SC fiber connector
NO TICE
During operation, pinch the housing instead of the tail.
Installing an MTRJ Fiber Connector
Procedure
1. Remove the dustproof cap of the MTRJ fiber connector and store it for future
use.
2. Align the core pin of the male connector with that of the female connector,
make sure that the center PINs of the two connectors are on the same axis,
and the pins and card slots are in the same direction, as shown in Figure
4-151.
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Figure 4-151 Aligning the male connector with the female connector
3. Align the fiber adapter along the axis and gently push the fiber plug, as
shown in Figure 4-152.
Figure 4-152 Feeding the male connector into the female connector
4. When you hear a "click", it has been plugged into place. At this time, the
hook has popped up to lock the fiber plug. Pull gently without loosening, as
shown in Figure 4-153.
Figure 4-153 Installed MTRJ fiber connector
5. When disassembling, lightly press the button of the optical fiber plug to
disengage the hook from the slot, and gently pull the optical fiber plug
housing along the axis, and the disassembly is completed, as shown in Figure
4-154.
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Figure 4-154 Disassembling a MTRJ fiber connector
Installing an MPO Connector
Procedure
1. Remove the dustproof cap of the MPO fiber connector and store it for future
use.
2. Align the core pin of the male connector with that of the female connector, as
shown in Figure 4-155.
Figure 4-155 Aligning the male connector with the female connector
3. Hold the shell labeled "PUSH" and feed the male connector into the female
connector until you hear a clicking sound. The male and female connectors
are securely installed, as shown in Figure 4-156.
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Figure 4-156 Installed MPO fiber connector
4. To disassemble an MPO fiber connector, hold the shell labeled "PULL" and
remove the male connector, as shown in Figure 4-157.
Figure 4-157 Disassembling an MPO fiber connector
4.1.14.1.7 Replacing the Mold of the Crimping Tool
Procedure
1. Hold the handles of a pair of COAX crimping tools. Loosen the two fastening
screws counterclockwise, as shown in Figure 4-158.
Figure 4-158 Loosening two fastening screws
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2. Hold the handles of the COAX crimping tools to open the self-locking
mechanism. The jaw of the COAX crimping tools opens automatically, as
shown in Figure 4-159.
Figure 4-159 Pliers jaw opening automatically
3. Remove the mold from the COAX crimping tools, as shown in Figure 4-160.
Figure 4-160 Removing the mold from the COAX crimping tools
4. Place the mold to be installed into the jaw of the COAX crimping tools and
align the screw holes, as shown in Figure 4-161.
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Figure 4-161 Installing a new mold in the COAX crimping tool
NO TICE
Keep the short side of the mold inwards and the long side outwards, with the
teeth of the mold aligning from the larger size to the smaller size.
5. Hold the handles of the COAX crimping tools tightly to match the mold and
the jaw completely. Align the screw holes, as shown in Figure 4-162.
Figure 4-162 Aligning the screw holes
6. Hold the handles of the COAX crimping tools with one hand. Tighten the two
fastening screws clockwise. Figure 4-163 and Figure 4-164 shows the mold
installed in the COAX crimping tool.
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Figure 4-163 Mold installed in the COAX crimping tool
Figure 4-164 An installed mold
4.1.14.2 Environmental Requirements for Device Operation
4.1.14.2.1 Environmental Requirements for Equipment Room
Requirements for Selecting a Site for Equipment Room
When designing a project, consider the communication network planning and
technical requirements of the equipment. Also consider hydrographic, geological,
seismic, power supply, and transportation factors.
Construction, structure, heating and ventilation, power supply, lighting and fire-
proof construction of the equipment room should be designed by specialized
construction designers to suit the environmental requirements of devices. The
equipment room should also follow local regulations concerning the industrial
construction, environmental protection, fire safety, and civil air defense.
Construction must conform to government standards, regulations, and other
requirements.
The equipment room should be located in a place free from high temperature,
dust, toxic gases, explosive materials, or unstable voltage. Keep the equipment
room away from significant vibrations or loud noises, as well as power transformer
stations.
The specific requirements for selecting a site for an equipment room are as
follows:
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● The room should be located at a distance of at least 5 km (3.11 mi.) from
heavy pollution sources such as smelting and coal mines. It should be located
at a distance of at least 3.7 km (2.30 mi.) from moderate pollution sources
such as chemical, rubber, and galvanization factories. It should be located at a
distance of at least 2 km (1.24 mi.) from light pollution sources such as
packinghouses and tanyards. If these pollution sources cannot be avoided,
ensure that the equipment room is upwind of the pollution sources. In
addition, use a high-quality equipment room or protection products.
● The room should be located away from livestock farms, or be upwind of the
livestock farms. Do not use an old livestock room or fertilizer warehouse as
the equipment room.
● The equipment room must be far away from residential areas. An equipment
room that is not far away from residential areas must comply with equipment
room construction standards to avoid noise pollution.
● The room should be located far away from industrial and heating boilers.
● The room should be at least 3.7 km (2.30 mi.) away from the seaside or salt
lake. Otherwise, the equipment room should be airtight with cooling facilities.
In addition, alkalized soil cannot be used as the construction material.
Otherwise, equipment suitable for wet conditions must be used.
● The doors and windows of the equipment room must be kept closed to
maintain an airtight room.
● Using steel doors to ensure sound insulation is recommended.
● No cracks or openings are allowed on the walls or floors. The outlet holes on
the walls or windows must be sealed. Walls must be constructed such that
they are smooth, wear-resistant, dustproof, flame retardant, sound insulated,
heat absorptive, and have electromagnetic shielding.
● The air vent of the room should be far from the exhaust of city waste pipes,
big cesspools and sewage treatment tanks. The room should be in the positive
pressure state to prevent corrosive gases from entering the equipment room
and corroding components and circuit boards.
● It is recommended that the room be on or above the second floor. If this
requirement cannot be met, the ground for equipment installation in the
room should be at least 600 mm (23.62 in, ) above the maximum flood level.
● The equipment room should be strong enough to resist winds and downpours.
● The room should be located away from dusty roads or sand. If this is
unavoidable, the doors and windows of the equipment room must not face
pollution sources.
● Do not place air conditioning vents near the equipment so that they blow
directly on the equipment because condensation may be blown into the
equipment.
● Do not use decorative materials that contain sulfur in the equipment room.
Equipment Room Layout
An equipment room usually contains mobile switching equipment,
telecommunications equipment, power supply equipment, and other auxiliary
equipment. To ensure easy maintenance and management, place the equipment
in different rooms. Figure 4-165 shows the layout of the equipment room.
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Figure 4-165 Layout of the equipment room
The general layout principles of the equipment room are as follows:
● It should meet requirements for laying out and maintaining communication
cables and power cables.
● It should reduce the cabling distance, which facilitates cable maintenance,
reduces potential communication faults, and maximizes efficiency.
Construction Requirements for the Equipment Room
Table 4-27 describes the construction requirements for the equipment room.
Table 4-27 Construction requirements for the equipment room
Item Requirements
Area The smallest area of the equipment room can accommodate the
equipment with the largest capacity.
Net height The minimum height of the equipment room should not be less
than 3 m (9.84 ft). The minimum height of the equipment room
is the net height below overhead beams or ventilation pipes.
Floor The floor in the equipment room should be semi-conductive and
dustproof. A raised floor with an ESD covering is recommended.
Cover the raised floor tightly and solidly. The horizontal
tolerance of each square meter should be less than 2 mm (0.08
in.). If raised floors are unavailable, use a static-electricity-
conductive floor material, with a volume resistivity of 1.0 x 10^7
ohms to 1.0 x 10^10 ohms. Ground this floor material or raised
floor. You can connect them to ground using a one megohm
current-limiting resistor and connection line.
Load-bearing The floor must bear loads larger than 561 kg/m2 (0.79 bf/in.2).
capacity
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Item Requirements
Door and The door of the equipment room should be 2 m (6.56 ft) high
windows and 1 m (3.28 ft) wide. One door is enough. Seal the doors and
windows with dustproof plastic tape. Use double-pane glass in
the windows and seal them tightly.
Wall surface Paste wallpaper on the wall or apply flat paint. Do not use
treatment pulverized paint.
Cable trays Use cable trays to arrange cables. The inner faces of the cable
trays must be smooth. The reserved length and width of the
cable trays, and the number, position and dimensions of the
holes must comply with the requirements of device
arrangement.
Water pipe Do not pass service pipes, drainpipes, and storm sewers through
the equipment room. Do not place a fire hydrant in the
equipment room, but place it in the corridor or near the
staircase.
Internal Separate the area where the equipment is installed from the
partition wall equipment room door. The partition wall can block some outside
dust. As shown in Figure 4-166.
Installation Install air conditioner vents so that the air does not blow directly
position of on equipment.
the air
conditioner
Other Avoid the proliferation of mildew, and keep out rodents (like
requirements mice).
Figure 4-166 Internal partition wall inside the equipment room
Equipment Room Environment
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Dust on devices may cause electrostatic discharge and result in poor contact for
connectors or metal connection points. This problem can shorten the life span of
devices and cause faults.
The equipment room must be free from explosive, conductive, magnetically-
permeable, and corrosive dust. Table 4-28 lists the requirement for dust
concentration in the equipment room.
Table 4-28 Requirements for dust particles in the equipment room
Mechanical active Unit Concentration
material
Dust particle Particle /m3 ≤ 3x 104
(no visible dust
accumulated on a
workbench in three
days)
Suspending dust mg/m3 ≤0.2
Precipitable dust mg/m2·h ≤1.5
NOTE
● Dust particle diameter ≥ 5 µm
● Suspending dust diameter ≤ 75 µm
● 75 µm ≤ precipitable dust diameter ≤ 150 µm
Take the following measures to meet the requirements:
● Use dustproof materials for ground, wall, and ceiling construction.
● Use screens on the door and windows facing outside. The outer windows
should be dust-proof.
● Clean the equipment room regularly and clean the air filter door monthly.
● Wear shoe covers and ESD clothing before entering the equipment room.
Requirements for Corrosive Gases
The room should be free from dusts and corrosive gases, such as SO2, H2S, and
NH3. Table 4-29 lists the requirements for the corrosive gas concentration.
Table 4-29 Requirements for corrosive gas concentration
Chemical Unit Concentration
active material
3
SO2 mg/m ≤0.30
3
H2S mg/m ≤0.10
3
NOx mg/m ≤0.50
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Chemical Unit Concentration
active material
3
NH3 mg/m ≤1.00
3
Cl2 mg/m ≤0.10
HCl mg/m3 ≤0.10
HF mg/m3 ≤0.01
3
O3 mg/m ≤0.05
Take the following measures to meet the requirements:
● Avoid constructing the room near a place where the corrosive gas
concentration is high, such as a chemical plant.
● Ensure the air intake vent of the room is in the prevailing upwind direction
from any pollution source.
● Place batteries in different rooms.
● A professional service should monitor the corrosive gas conditions regularly.
Requirements for ESD Prevention
The absolute value of electrostatic voltage must be less than 1000 V.
Take the following measures to meet this requirement:
● Train operators about ESD prevention.
● Keep the correct humidity level in the equipment room to reduce the impact
of static electricity.
● Lay out an ESD floor in equipment rooms.
● Wear ESD shoes and clothing before entering equipment room.
● Use ESD tools, such as wrist straps, tweezers, and pullers.
● Ground all conductive materials in the room, including computer terminals.
Use ESD worktables.
● Keep non-ESD materials (such as common bags, foam, and rubber) at least
30 cm (11.81 in.) away from boards and ESD-sensitive components.
Electromagnetism Requirements for the Equipment Room
All interference sources, inside or outside the equipment room, can cause
equipment problems with capacitive coupling, inductive coupling, electromagnetic
wave radiation, and common impedance (including grounding system) coupling.
Prevent the interference using these approaches:
● Take effective measures against electrical interference from the power supply
system.
● Do not use the working ground of the equipment as the same ground for
surge protection. Separate them as far as possible.
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● Keep the equipment far away from high-power radio transmitters, radar units,
and high-frequency and high-current equipment.
● Use electromagnetic shielding if necessary.
Requirements for Lightning Proof Grounding
Table 4-30 lists the requirements for lightning proof grounding.
Table 4-30 Requirements for lightning proof grounding
Item Requirements
Capital ● Use reinforced concrete to construct the equipment room.
construction ● Install a lightning proof device like a lightning rod outside
the room.
● The lightning proof ground shares the same grounding
body with the protective ground of the room.
Power cables ● After the AC low-voltage power cables are led into the
leading in the room, install the surge protector for the power cables in the
equipment AC voltage stabilizer and the AC power distribution panel
room need to (box). Correctly ground the surge protector nearby.
be equipped ● After the DC power cable is led into the equipment room or
with a surge outdoor cabinet from outdoors or outside the cabinet,
protector install a power lightning protection device for the DC power
cable. The lightning protection device should be grounded
in proximity.
● For an equipment room in urban area, install a power
supply surge protector with the nominal discharge current
of no less than 20 kA. For an equipment room that is built
in a suburb and subject to lightning strikes, install a power
supply surge protector with the nominal discharge current
of more than 60 kA. For an equipment room that is built in
a mountain area and subject to frequent lightning strikes,
or in a separate high-rise building in a city, install a power
supply surge protector with the nominal discharge current
of more than 100 kA.
● The ground cable of the surge protector should be no
longer than 1 m (3.28 ft).
Grounding for ● Connect the DC working ground (positive pole of the -48 V
DC power DC power supply or the negative pole of the 24 V DC power
distribution supply) with the indoor collective ground cable nearby. The
total ground cable should meet the maximum load of the
equipment.
● The power equipment must have a DC working ground
cable, which can connect the power equipment to the
collective ground cable of the telecommunication site (or
the protective ground bar of the equipment room).
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Item Requirements
Equipotential ● Properly ground the devices and auxiliary devices in the
connection room such as mobile base station, transmission, switching
equipment, power supply equipment, and cable distribution
frame. Connect all PGND cables to the collective protective
ground bar. Connect all PGND cables in one equipment
room to one protective ground bar.
● Apply joint grounding to the working ground and protective
ground of devices, which means the two share one
grounding network.
● The cable tray, rack or shell, metal ventilation pipe, metal
door or window of the equipment should be grounded for
protection.
General ● Do not connect the neutral line of the AC power cable with
requirements the protective ground of any telecom equipment in the
for grounding equipment room.
● Do not install a fuse or switch on the ground cable.
● All ground cables should be as short as possible, and
arranged in a straight line.
Grounding ● The grounding resistance must be lower than 1 ohm.
resistance ● The upper end of the grounding body should be at least 0.7
m (2.30 ft) over the ground. In cold areas, bury the
grounding body below the frozen ground.
● Measure the grounding resistance periodically to ensure
effective grounding.
Routing of ● Do not arrange the signal cables overhead in the
signal cable equipment room. All signal cables must be led into the site
underground.
● Use the cables with a metal jacket or place them into a
metal pipe if they come out/in the equipment room.
● Ground the idle lines inside the cable in the equipment
room.
● Signal cables should be deployed on internal walls. Do not
deploy outdoor aerial cables.
● Keep signal cables away from power cables and surge
protection devices.
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Item Requirements
Collective ● Use a ground ring or ground bar for the collective ground
ground cable cable.
● Do not use aluminum cables as ground cables. Adopt
measures to prevent electrification corrosion when
connecting different metal parts together.
● Use a copper busbar as the collective ground cable with a
cross-sectional area of no less than 120 mm2 (0.19 in.2), or
use the galvanized flat steel of the same resistance. Insulate
the collective ground cable from the reinforcing steel bars
of the building.
Grounding The grounding lead-in should be a maximum of 30 m (98.42
lead-in ft) long. Use the galvanized flat steel with cross-sectional area
of 40 mm x 4 mm (1.58 in. x 0.158 in.) or 50 mm x 5 mm
(1.97 in. x 0.197 in.).
4.1.14.2.2 Requirements for Power Supply
Requirements for AC Power Supply
An AC power supply system consists of power mains, uninterruptible power
supplies (UPSs), and self-supplied electric generators, and should use a centralized
power supply mode. In addition to meeting the requirements of the server load,
the AC power supply must have a simple connection line, safe operation, flexible
scheduling, and easy maintenance.
The low-voltage power supply should be 3-phase, 5-wire mode or monophase 3-
wire mode. This AC power supply should be 110 V/220 V, with a frequency of 50
Hz.
The UPS should supply the same power and operate at the same phase as the
power mains. The switching time between the UPS and mains should be less than
10 ms; otherwise, the networking devices will reboot or reset.
For power distribution capacity in the equipment room, both the working current
and fault current of the devices should be considered. Ensure that independent AC
power supplies protect independent devices. Configure the current-carrying
capacity of the protection switch of the equipment room for more than that of the
devices.
Table 4-31 lists the voltage range of the AC power supply for the devices.
Table 4-31 Voltage range of AC power supply
Item Requirements
AC power capacity to -10% to +5% of the rated voltage
support the devices
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Item Requirements
AC power capacity to -15% to +10% of the rated voltage
support the power
modules and important
buildings
Frequency of alternating -4% to +4% of the rated value
current
Voltage wave shape sine Within 5% of the rated voltage
distortion
The automated electric generator must have a standard interface that supports
telecommunication protocols, remote telecommunication, monitoring, and control.
AC power cables should meet the following specifications:
● AC neutral should have a conductor with the same cross section as the phase
line.
● AC cables should have non-flammable insulation. The layout of AC cables
should comply with local regulations. Low-voltage power distribution rooms
should comply with local regulations.
Recommendations for AC Power Supply
The following are recommendations for the AC power supply.
● If the voltage of the power mains that supply power directly to devices
exceeds the rated voltage by -10% to 5%, or exceeds the voltage range that
devices can support, a voltage regulating device or voltage stabilizing device
is required.
● If the mains do not supply power for the device directly, or if the mains
voltage exceeds the rated voltage by -15% to 10% or exceeds the input
voltage range of the DC power supply, a voltage regulating device or voltage
stabilizing device is required.
● A UPS or inverter power supply system is required to provide uninterrupted
AC power to support the telecommunication load.
● If abnormalities occur on the mains, telecommunication servers should be
equipped with a self-supplied electric generator to support the key
telecommunication load. The capacity should be not less than 150% to 200%
of the total uninterruptible power supply.
● Storage batteries are usually installed in a parallel connection of two groups.
UPS storage batteries are generally installed in one group. The redundancy
required for the UPS can rely on concatenation or parallel connection. When
an inverter or a UPS is used, the active inverter is determined by the
maximum power and a backup inverter is required.
Requirements for DC Power Supply
The equipment room should receive stable and reliable DC power. Deploy the
power equipment near the telecommunications equipment to make the DC feeder
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as short as possible. To reduce power consumption and installation cost, the loop
voltage drop from the battery port to the equipment port should be less than 3.2
V.
● A large-scale enterprise can deploy an independent power supply system on
each floor to supply power to the telecommunications equipment room on
the respective floor.
● A medium-scale enterprise can use a power room and a battery room for
centralized power supply or use distributed power supply systems.
● A small-scale enterprise can deploy an integrated power supply system in its
equipment room but must take measures to prevent corrosive gases released
from batteries from eroding circuit boards of telecommunications equipment.
Table 4-32 lists the specifications for the DC power supply.
Table 4-32 Specifications for the DC power supply
Item Requirements
DC power Greater than 1.5 times the rated current
capacity to
support the
surge current
Regulated If the AC input voltage is in the range of 85% to 110% of the
voltage rated value, and the load current is in the range of 5% to
precision 100% of the rated value, the output voltage of the rectifier
ranges from -46.0 V to -56.4 V, with the regulated voltage
precision less than or equal to 1%.
Overshoot Integral value of the DC output voltage ±5%
amplitude of
switch on/off
Peak noise ≤200 mV
voltage
Dynamic The recovery time is less than 200 ms. The overshoot is in the
response range of the integral value of the DC output voltage ±5%.
Recommendations for DC Power Supply
The following are recommendations for the DC power supply.
● Use distributed power supply mode. Use multiple DC power supply systems
and put power equipment in multiple locations.
● Adopt a standard DC power supply system, and set the output voltage to the
communications equipment within the required range.
● Improve reliability of the AC power supply system to reduce the necessary
capacity of storage batteries. For small offices, increase the capacity of
storage batteries if it is difficult to enhance reliability of the AC power supply
system.
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● The total capacity of the high-frequency switching rectifier must satisfy the
power of the communication loading and battery charging. If there are 10 or
fewer active rectifier modules, configure one backup module. If there are
more than 10 active modules, configure one backup module for every 10
active modules.
● Install storage batteries in two or more groups. The capacity is determined by
the duration for which the storage batteries must supply power. For most
offices, the batteries should be able to supply power for at least one hour.
4.1.14.3 Equipment Grounding Specifications
4.1.14.3.1 General Grounding Specifications
Table 4-33 shows the general grounding specifications.
Table 4-33 General grounding specifications
No. Description
1 The working ground and protective ground, including the shielded
ground and the lightning-proof ground of the cable distribution frame
should share the same grounding conductor.
2 The cable trays, shells, metal ventilation pipes, metal doors and windows
in the equipment room should be grounded for protection.
3 The metal parts of the equipment which are electrically floating in
normal conditions should be grounded for protection.
4 The ground cable must be connected securely to the protective ground
bar of the equipment room.
5 Do not use other equipment as part of the ground cable or electrical
connection.
4.1.14.3.2 Grounding Specifications for Equipment Room
The grounding resistance of a comprehensive communication building should be
less than or equal to one ohm. The grounding resistance of an ordinary
communication office should be less than five ohms. The grounding resistance in
an area where the earth resistance rate is high should be less than 10 ohms.
4.1.14.3.3 Grounding Specifications for Devices
Table 4-34 lists the equipment grounding specifications.
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Table 4-34 Equipment Grounding Specifications
No. Description
1 All communication devices and auxiliary devices (such as mobile base
stations, transmission and switching devices, power supply devices) in
the equipment room should be grounded for protection. Connect all
protective ground for various devices jointly to a general ground bar, and
then to the same protective ground bar in the room together with the
protective ground (PGND) of the device.
2 The PGND of the equipment is shorted to the copper ground bar
provided by the customer. The short-circuiting cable used should be a
yellow-green plastic insulated cable with a copper core and a cross-
sectional area greater than 25 sq. mm (0.039 sq. in.).
3 There are grounding terminals and grounding lugs at the lower part of
the front door, rear door and side panel of the cabinet, connected to the
grounding terminals of the cabinet framework through connection
cables with cross-sectional area of no less than 1.6 sq. mm (0.002 sq.
in.).
4 Ensure that all metal components of the cabinet conduct well. No
insulating coating should be sprayed on the connection part of the metal
components.
5 Connect the cabinets in the same row by fastening captive screws and
gaskets on the top of the cabinets. Do not spray any coating into a
rectangular area measuring 30 mm x 50 mm (1.18 in. x 1.97 in.) around
the connection hole for a captive bolt. Measures to prevent rust and
corrosion must be taken for this area. Zinc electroplating with iridescent
yellow chromate conversion coating should be applied to the gasket and
nut to ensure good electrical contact.
6 When combining cabinets of the same type, short-circuiting cables are
required to connect the ground busbars (if any) of the cabinets. The
cross-sectional area of the short-circuiting cable is 6 sq. mm (0.009 sq.
in.) and is no more than 300 mm (11.8 in.) long. Connect the two ends
of the short-circuiting cable to the ground busbar terminals of
neighboring cabinets and fix them firmly.
4.1.14.3.4 Grounding Specifications for Communications Power Supply
Table 4-35 shows the grounding specifications for communication power supplies.
Table 4-35 Grounding specifications for communication power supplies
No. Description
1 The inlet for the AC power cable at the equipment room should be
equipped with a surge protection device (C-level) with a nominal
discharge current no less than 20 kA.
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No. Description
2 The protective ground for the power supply and that for communication
equipment share the same grounding conductor. If the power supply and
the equipment are in the same equipment room, use the same
protective ground bar for them if possible.
3 Use a surge protection circuit on the AC power interface.
4 The positive of the -48 V DC power supply or negative pole of the 24 V
DC power supply should be grounded at the output of the DC power
supply.
5 The working ground and protective ground of the DC power supply
equipment should use the same grounding conductor with the protective
ground of the switching equipment. If the power supply and equipment
are in the same equipment room, use the same protection ground bar
for them if possible.
6 Add surge protection on the DC power interface.
4.1.14.3.5 Grounding Specifications for Signal Cables
Table 4-36 lists the grounding specifications for signal cables.
Table 4-36 Grounding specifications for signal cables
No. Description
1 Equip the cable outdoors with a metal jacket, well grounded at both
ends, or connect the ends of the metal jacket to the protective ground
bar of the equipment room. For cables inside the equipment room,
install surge protection devices at the interface to the equipment. The
PGND cable for the surge protection devices should be as short as
possible.
2 The incoming and outgoing signal cables to and from the office and
unused wires inside the cable should be grounded for protection.
3 The Tone & Data Access (TDA) cable must pass through the Main
Distribution Frame (MDF) with surge protective device (SPD) when
going out of the office. The cable's shield layer should be connected to
the protective ground of the MDF. The MDF should use the same
grounding conductor as the cabinet.
4 Do not route signal cables overhead.
4.1.14.3.6 Specifications for Laying Out Grounding Cables
Table 4-37 shows the specifications for the ground cable.
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Table 4-37 Specifications for laying out ground cables
No. Description
1 The grounding wire should not run parallel to or twist around the signal
cable.
2 Bury ground underground or arrange them indoors. Do not route ground
cables overhead.
3 Do not connect two cables together to extend the PGND cable, or add
any switches or fuses.
4 The PGND cable should be an alternating yellow and green plastic
insulated one with a copper core.
5 The neutral line of the AC power cable cannot be connected to the
protective ground of transmission and communication equipment in the
equipment room.
6 A PGND cable should be as short as possible, with a length of no more
than 45 m (147.64 ft).
4.1.14.4 Engineering Labels for Cables
An engineering label serves as an identifier for on-site installation and
maintenance after the installation. Labels on the cables facilitate correct and
orderly connection of cables, and easy maintenance after installation.
Engineering labels are specialized for power cables and signal cables:
● Signal cables include network cables, optical fibers, and user cables.
● Power cables include the AC power cables and DC power cables.
NO TE
Fill in labels according to specified requirements to keep consistency of labels in the
equipment room. Make a relevant statement in the self-check report.
4.1.14.4.1 Introduction to Labels
Label Materials
Features:
● Thickness: 0.09 mm (0.004 in.)
● Color: chalk white
● Material: polyester (PET)
● Ambient temperature: -29°C (-20.2°F) to +149°C (300.2°F)
● Printed by a laser printer and written with a marker
● Pass UL and CSA authentication
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Type and Structure
Label for Signal Cables
The label for signal cables is L-shaped with fixed dimensions, as shown in Figure
4-167.
Figure 4-167 Label for signal cable
To specify more clearly the position of a cable, use the dividing lines on the label.
For example, there is a dividing line between the cabinet number and the chassis
number, and another one between the chassis number and the slot number. Each
dividing line is light blue (Pantone 656c) and 1.5 mm x 0.6 mm (0.06 in. x 0.02
in.).
The cut dotted line helps to fold the label when affixed to the cable, and its size is
1 mm x 2 mm (0.04 in. x 0.08 in.).
The word "TO:" (upside down in the figure) at the lower right corner of the label
is used to identify the opposite end of the cable on which the label is affixed.
Power Cable Label
The label for power cables should be attached to the identification plate on the
cable ties that are attached to the cable. The identification plate has an embossed
area 0.2 mm x 0.6 mm (0.008 in. x 0.02 in.) around (symmetric on both sides), and
the area in the middle is for affixing the label, as shown in Figure 4-168.
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Figure 4-168 Power Cable Label
Label Printing
The contents can be printed or written on the labels. Printing is recommended for
the sake of high efficiency and eye-pleasant layout.
Template for Printing
You can obtain a template from the Huawei local office to print labels.
The template is made in Microsoft Word. Follow these instructions to use the
template:
● You can modify the contents of the template. Do not change settings of
centered characters, direction, and fonts.
● If many characters need to be filled in, decrease the font size, but make sure
that the printouts are clear and legible.
Merging Cells in the Template
To merge two or more cells, do as follows:
1. Select Edit/Select All.
2. Select Format/Borders and Shading/Borders. Select Box tab and click OK.
3. Drag the mouse to select cells to be merged and select the Table/Merge
Cells.
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Requirements on the Printer
To print labels, use a laser jet printer of any model. Before printing labels, set up
the page and try printing.
1. Try printing on ordinary paper with both sides blank. Place the blank paper
over the whole page of the label paper, and check whether the page setup
conforms to the label layout.
2. Make sure the printer properties, such as "paper size" and "direction", have
been set correctly.
– If the printout conforms to the sheet of labels, print the labels on the
label paper.
– If the printout does not conform, adjust the page setup and try printing
again until the correct printout is produced.
The method for adjusting the page setup is as follows.
1. Select File/Page Setup.
2. Select Layout and set Header and Footer as 0.
3. Select the Margins tab page. Select Left for Gutter Position and adjust the
values of Top, Bottom, Left, and Right.
NO TE
If the warning prompt as shown in Figure 4-169 appears before printing, click Ignore
to continue the printing.
Figure 4-169 Warning prompt before printing
After the page setup has been made correctly, save it for future use. This page
setup is only necessary the first time you use the template to print the labels.
Requirements for Feeding the Printer
The label paper consists of two layers and has undergone multiple processing
procedures such as printing and cutting. No matter what model of printer you use,
feed in the labels one page at a time. To avoid jamming the labels, never use the
auto-feed mode.
Feed in the label paper in the correct direction to ensure that the text is printed in
a correct position.
Requirements for the Printed Label
Make sure that the printed labels satisfy the following requirements:
● All the printouts must be on the label, and nothing should be printed on the
backing layer of the label page.
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● Contents in the cells should be aligned in the center. In a single-line printout,
the dividing lines and the word "TO:" should not be covered by printed
characters.
● When the cells are merged and the printouts are made in multiple lines, avoid
covering the word "TO:" when printing the text. Use the space bar to move
the text to the next line.
Writing Labels
Writing Tools
To make sure the printouts are clear and legible, use black markers instead of
ball-point pens to write the labels.
If no marker is available, black ball-point pens are allowed, although not
recommended. Compared with ball-point pens, waterproof markers are better.
When writing with a ball-point pen, do not leave the oil on the label, which may
contaminate the label and blur the words.
NO TE
The delivered marker has two nibs. Use the smaller nib to write the labels.
Font
For the sake of legibility, use standard block letters and numbers as shown in
Table 4-38.
Table 4-38 Standard typeface for handwriting
0 1 2 3 4 5 6 7 8
9 A B C D E F G H
I J K L M N O P Q
R S T U V W X Y Z
Determine the size of characters based on the number of letters or digits and
ensure that the characters are distinct and tidy.
Placement of text on a label is shown in Figure 4-170.
Figure 4-170 Placement of text on a label
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Attaching Labels
After printing or writing the label, remove the label from the page and attach it to
the signal cable, or the identification plate of the power cable. The methods for
attaching labels are described in the following sections.
Label for Signal Cables
● Choose the place to attach labels.
The label is attached 2 cm (0.79 in.) from the connector on a signal cable. In
special cases (for example, to avoid cable bending or affecting other cables),
other positions are allowed to attach the labels. The rectangular part with
text is attached facing right or downward, as shown in Figure 4-171. The
details are as follows:
– The identification card is to the right of the cable in vertical cabling.
– The identification card should be downward when you lay out the cable
horizontally.
Figure 4-171 Text area of the label
● Procedure for attaching labels
Figure 4-172 shows the methods and procedures for attaching labels.
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Figure 4-172 Label for signal cables
Power Cable Label
Remove the label from the backing page, and attach it to the identification plate
on the cable tie. The label should be attached to the rectangular flute on the
identification plate, and attached to only one side of the identification plate. In an
equipment room, all labels should be attached in the same way. The cable ties are
bundled at 2 cm (0.79 in.) from the connectors, and other positions are allowed in
special circumstances.
Cable ties should be bound on both ends of a cable. After the bundling, the
finished identification plate should be on top of the cable in horizontal cabling, or
on the right side of the cable in vertical cabling, as shown in Figure 4-173. The
details are as follows:
● The identification card is to the right of the cable in vertical cabling.
● The identification card is on the top of the cable in horizontal cabling. Make
sure that the label is facing out.
Figure 4-173 Binding the label for the power cable
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Contents of Engineering Labels
Contents of Labels for Power Cables
Labels for power cables are affixed on only one side of the identification plates.
On the labels, there is information (the part after the word "TO:") about the
location of the device on the other end of the cable, like the location of control
cabinet, distribution box or power socket.
Contents of Labels for Signal Cables
The two sides of the label affixed on the signal cable carry information about the
location of the ports connected to both ends of the cable. Figure 4-174 shows the
information on both sides of the labels affixed to the signal cables.
● Area 1 contains the location information of the local end of the cable.
● Area 2 (with the word "TO:") contains the location information of the
opposite end of the cable.
● Area 3 has been folded up inside the label.
Figure 4-174 Printed parts on the label for signal cables
Seen from the cabling end of the equipment, the text part of the label is on the
right side of the cable. The side with "TO:" that is facing outside carries the
location information of the opposite end; and the other side carries the location
information of the local end.
In other words, the information in Area 1 at one end is the same as the
information in Area 2 at the other end of the cable.
Precautions for Using Engineering Labels
When using labels, pay attention to the following points:
● When printing, writing, or attaching labels, keep the labels clean.
● Since the label paper is made of moistureproof material, ink-jet printers and
ink pens cannot be used to print and write labels.
● Labels should be attached neatly. New-type labels are L-shaped. If they are
pasted at incorrect locations or in the incorrect direction, the appearance of
the device is affected.
● Power cable ties should be attached in the same positions on power cables,
with identification plates on the same side.
● The positions of "up", "down", "left" or "right" are all based on the viewpoint
of the engineering person who is working on the label.
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4.1.14.4.2 Engineering Labels for Optical Fibers
These labels are affixed to the optical fibers that connect the optical interfaces on
the boards in a chassis, or on the device boxes. There are two types of labels for
optical cables:
● One is for the fiber that connects the optical interfaces on two devices.
● The other is for the fiber that connects the device and the ODF.
Labels for the Optical Fibers Connecting Devices
Meaning of the Label
Table 4-39 lists information on both sides of the labels affixed to the optical fibers
that connect two devices.
Table 4-39 Information on labels affixed to the fibers between two devices
Content Meaning Example
MN-B-C-D- MN: cabinet M: The cabinet rows from front to back are
R/T number numbered from A to Z.
N: The cabinet columns from left to right are
numbered from 01 to 99.
For example, A01 is the cabinet in row A and
column 01.
B: chassis Numbered in bottom-up order with two digits,
number for example, 01.
C: physical Numbered in top-down and left-right order
slot number starting from 01. For example, 01 is the first slot
at the top left of the chassis.
D: optical Numbered in top-down and left-right order,
interface consistent with the port sequence number on
number. the device.
R: Receiving -
interface
T: optical
transmitting
interface
Example of the Label
Figure 4-175 shows a sample label on an optical fiber.
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Figure 4-175 Sample label on an optical fiber between two devices
The meaning of the label is listed in Figure 4-175.
● "A01-01-05-01-R" indicates that the local end of the optical fiber is connected
to the optical receiving interface 01 in slot 5, chassis 01 in the cabinet in row
A, column 01 in the machine room.
● "G01-01-01-01-T" indicates that the opposite end of the optical fiber is
connected with optical transmitting interface 01 in slot 01, chassis 01 in the
cabinet in row G, column 01 in the machine room.
Labels for the Optical Fibers Connecting the Device and an ODF
Meaning of the Labels
Table 4-40 shows information on both sides of labels attached to an optical fiber
between a device and an optical distribution frame (ODF).
Table 4-40 Information on labels affixed to a fiber between a device and an ODF
Content Meaning Example
MN-B-C-D- MN: cabinet For example, A01.
R/T number
B: chassis Numbered in bottom-up order with two digits,
number for example, 01.
C: physical slot Numbered in top-down and left-right order
number starting from 01. For example, 01 is the first
slot at the top left of the chassis.
D: optical Numbered in top-down and left-right order,
interface consistent with the port sequence number on
number. the device.
R: Optical -
receiving
interface
T: optical
transmitting
interface
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Content Meaning Example
ODF-MN-B- MN: row M: The cabinet rows from front to back are
C-R/T number and numbered from A to Z.
column N: The cabinet columns from left to right are
number of an numbered from 01 to 99.
ODF
For example, G01 is the ODF of row G and
column 01.
B: row number Range from 01 to 99, for example, 01-01.
of the terminal
device
C: column
number of the
terminal
device
R: Optical -
receiving
interface
T: optical
transmitting
interface
Example of the Label
Figure 4-176 shows a sample label on an optical fiber.
Figure 4-176 Sample label on an optical fiber between the device and the ODF
Meaning of the label in Figure 4-176:
● "ODF-G01-01-01-R" indicates that the local end of the optical fiber is
connected to the optical receiving terminal in row 01, column 01 of the ODF
in row G, column 01 in the machine room.
● "A01-01-05-01-R" indicates that the opposite end of the optical fiber is
connected to optical receiving interface 1 in slot 05, chassis 01 in the cabinet
in row A, column 01 in the machine room.
4.1.14.4.3 Engineering Labels for Network Cables
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Applicable Ranges
The labels can be applied to Ethernet cables.
Label Content
Table 4-41 shows the information on both sides of the labels affixed to Ethernet
cables.
You can also decide the label content based on the actual environment. If the
device is not installed in the cabinet, for example, you can remove the cabinet
number.
Table 4-41 Information on the Ethernet cables
Content Meaning Example
MN-B-C-D MN: cabinet For example, A01 is the first cabinet in row A.
number
B: chassis Numbered in bottom-up order with two
number digits, for example, 01.
C: physical slot Numbered with two digits in top-down and
number left-right order. For example, 01.
D: network port Numbered in top-down and left-right orders.
number For example, 01.
MN-Z MN: cabinet For example, B02 is the second cabinet in
number row B.
Z: Location Fill in the location number of the terminal
number device on site. If the cable is connected to a
device in a cabinet, specify the serial
numbers of the cabinet, the chassis, and the
Ethernet interface of the device. For example,
B02-03-12. If the cable is connected to the
Network Management Station (NMS),
specify the specific location of the NMS.
The contents of the labels for network cables connecting hubs and devices or
agents and the network cables for other purposes should be specified according to
actual connections. The details are as follows:
● For a network cable connecting a hub and device, the label on the hub end
should indicate the numbers of the chassis and cabinet where the hub resides,
and the serial number on the hub. The label on the device end should indicate
the number of the chassis and cabinet where the device is located. If the
device is a standalone device, provide the specific position of the device.
● For a network cable connecting a hub and an agent or terminal, the label on
the agent or terminal end should contain the serial number of the network
interface. The definitions of the cabinet number and chassis number are the
same as those described in Table 1-28.
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● If the hub is a standalone device without a cabinet or chassis, the label should
contain specific location information that identifies the hub.
The serial number on the hub, the network interface number of the agent or
terminal, and the location of the standalone device should be specified according
to actual connections.
Label Example
Figure 4-177 shows a sample label on an Ethernet cable.
Figure 4-177 Sample label on an Ethernet cable
Meaning of the label in Figure 4-177:
● "A01-03-01-01" indicates that one end of the network cable is connected to
network interface 01 in slot 01, chassis 03 of the cabinet in row A, column 01
in the equipment room.
● "B02-03-01" indicates that another end of the network cable is connected to
network interface 01 in chassis 03 of the cabinet on row B, column 02 in the
equipment room. No slot number is given.
4.1.14.4.4 Engineering Labels for User Cables
Attach labels to both ends of a user cable to indicate the locations of the cable on
the device and main distribution frame (MDF).
Meaning of the Engineering Labels for User Cables
Table 4-42 shows the contents of the labels.
Table 4-42 Contents of the engineering labels for user cables
Content Meaning Example
MN-B-C-D MN: cabinet For example, A01 is the first cabinet in row A.
number
B: frame Numbered in the bottom-up order with two
number digits, for example, 03.
C: physical slot Numbered with two digits in top-down and
number left-right order. For example, 01.
D: cable Numbered with two digits in top-down and
number left-right order. For example, 01.
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Content Meaning Example
MDF-MN-B-C MN: row M: The rows of cabinets from front to back
number and are numbered from A to Z. N: The columns of
column number cabinets from left to right are numbered
of the MDF from 01 to 99. For example, G01 is the MDF
of Row G and Column 01.
B: row number Ranges from 01 to 99, for example, 01-01.
of the terminal
device
C: column
number of the
terminal device
Example of the Label
Figure 4-178 shows a sample label on a user cable.
Figure 4-178 Sample label on a user cable
The meaning of the label in Figure 4-178 is as follows:
● "A01-03-01-01" indicates that the local end of the user cable is connected to
port 1 in slot 1, chassis 03 of the cabinet in row A, column 01 in the
equipment room.
● "MDF-G01-01-01" indicates that the opposite end of the user cable is
connected to the terminal in row 01, column 01 of the MDF in row G, column
01 in the equipment room.
4.1.14.4.5 Engineering Labels for Power Cables
Engineering Labels for DC Power Cables
These labels are affixed to the DC power cables that provide power supply for
cabinets, including the -48 V, PGND, and BGND cables. Here, the DC power cables
also include power cables and PGND cables.
The labels for DC power cables are affixed to one side of the identification plates
on cable ties. For details of the labels, see Table 4-43.
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Table 4-43 Contents of the label
Content Meaning
MN(BC)- MN(BC): BC is written right under MN.
B--48Vn B: chassis number, numbered in bottom-up order with two
digits, for example, 01.
MN(BC)-B-
BGND n: power socket number, numbered as 1 to 3 in the bottom-
up and left-to-right orders.
MN(BC)-B- On the loaded cabinet side, only MN is used to identify the
PGND cabinet.
On the power cabinet side, MN identifies the row and column
number of the power distribution equipment like a control
cabinet and distribution box, and BC identifies the row and
column number of the -48 V connector. If there is no row
number or column number, or the connector can be identified
without them, BC can be omitted. It is unnecessary to identify
the row and column number for BGND and PGND.
The label only carries location information about the destination direction of the
power cable whereas information about the local end is unnecessary. That is, the
label only carries location information about the opposite equipment, the control
cabinet, or the distribution box. Table 1-30 lists the information on two -48 V
power supplies on the label. The information on other DC voltages, such as 24 V
and 60 V should be given in similar methods.
Make sure that labels are affixed in the correct direction. That is, after the cable
ties are bundled onto the cable, the identification plates with the labels should
face up, and the text on the labels in the same cabinet should be in the same
direction. For details, see Figure 4-179.
Figure 4-179 Example of the labels for DC power cables
The meaning of the label in Figure 4-179 is as follows:
● On the loaded cabinet side, the label "A01/B08--48V2" on the cable indicates
that the cable is -48 V DC supply, which is from the eighth connector in row B
of -48 V bus bar in the cabinet in row A, and column 1 in the equipment
room.
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● On the distribution box side, the label "B03--48V2" indicates that the cable is
-48 V DC supply, connected to DC power socket 2 in row B, column 03 in the
equipment room.
NO TE
In the power distribution box or the first power cabinet of a row in a transmission
equipment room, every terminal block on the -48 V connector bar has a numeric
identification. For example, in the above label of "A01/B08--48V2", "08" (or sometimes "8")
is the numeric identification of the terminal block.
PGND and BGND are two copper bars, on which the terminal blocks are short-
circuited. Therefore, it makes no difference which terminal is connected to them. It
is only necessary to give the row and column of the power distribution box,
instead of giving the specific serial number of the terminal block on the copper
bar. For example, if the label on the loaded cabinet side is "A01-BGND", it means
that the power cable is a BGND that connects BGND copper bar in the power
distribution box in row A, column 01 in the machine room. Information on the
labels for PGND cables should be given in a similar way.
Engineering Labels for AC Power Cables
These labels are affixed to both ends of an AC power cable that provides AC
power supply to cabinets, including 110/220 V, PGND, and BGND cables. The
110/220 V AC cables and related PGND and BGND cables are covered with an
insulating sheath, so the labels need to contain only the word "AC" and the
cabinet numbers.
The labels for AC power cables are affixed to one side of the identification plates
on cable ties. For details, see Table 4-44.
Table 4-44 Label content
Content Meaning
MN-(B)-ACn MN: serial number of the cabinet or the socket where the
power is led in
B: chassis number, numbered in bottom-up order with two
digits, for example, 01.
n: power port number, numbered as 1 to 3 in bottom-up and
left-to-right order.
Serial number of the socket where the power is led in: the
location of the socket is marked according to the actual
situation. If the sockets can be identified by row numbers and
column numbers, they can be numbered following the same
rule for the cabinets. If the sockets cannot be identified by
rows and columns, specify the detailed locations to avoid
confusion with other sockets.
The label only carries location information about the opposite equipment and the
power socket; information about the local end is unnecessary.
Make sure that labels are affixed in the correct direction. That is, after the cable
ties are bundled onto the cable, the identification plates with the labels should
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face up, and the text on the labels in the same cabinet should be in the same
direction, as shown in Figure 4-180.
Figure 4-180 Labels for AC power cables
Meaning of the label in Figure 4-180.
● On the equipment cabinet side, the label marked "A01-AC1" indicates that
the power cable is connected to the first AC power socket of row A and
column 01 in the equipment room.
● On the power socket side, the label marked "B01-AC1" indicates that the
power cable is connected to the first AC power socket in the cabinet of row B
and column 01 in the equipment room.
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