ne5000e hardware description(v800r002c01_01)

HUAWEI NetEngine5000E Core RouterV800R002C01

NE5000E Hardware Description

Issue 01

Date 2011-10-15

HUAWEI TECHNOLOGIES CO., LTD.

Copyright © Huawei Technologies Co., Ltd. 2011. All rights reserved.No part of this document may be reproduced or transmitted in any form or by any means without prior writtenconsent 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. NoticeThe purchased products, services and features are stipulated by the contract made between Huawei and thecustomer. All or part of the products, services and features described in this document may not be within thepurchase 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 representationsof any kind, either express or implied.

The information in this document is subject to change without notice. Every effort has been made in thepreparation of this document to ensure accuracy of the contents, but all statements, information, andrecommendations in this document do not constitute the warranty of any kind, express or implied.

Huawei Technologies Co., Ltd.Address: Huawei Industrial Base

Bantian, LonggangShenzhen 518129People's Republic of China

Website: http://www.huawei.com

Email: [email protected]

Issue 01 (2011-10-15) Huawei Proprietary and ConfidentialCopyright © Huawei Technologies Co., Ltd.

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http://www.huawei.com

mailto:[email protected]

About This Document

Intended AudienceThis document describes the contents, related version, intended audience, conventions, andupdate history of the HUAWEI NetEngine5000E Core Router Hardware Description.

CAUTIONFor the NE5000E, the interface is numbered as slot number/card number/interface number. Forthe NE5000E cluster, the interface is numbered as chassis ID/slot number/card number/interfacenumber. The chassis ID must be specified along with the slot number.

The intended audience of this document are:

l Commissioning Engineers

l Data Configuration Engineers

l Network Monitoring Engineers

l System Maintenance Engineers

Related Versions (Optional)The following table lists the product versions related to this document.

Product Name Version

HUAWEI NetEngine5000ECore Router

V800R002C01

Symbol ConventionsThe symbols used in this document are described in the following table. They are defined asfollows.

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description About This Document


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Symbol Description

Indicates a hazard with a high level of risk, which ifnot avoided, will result in death or serious injury.

Indicates a hazard with a medium or low level ofrisk, which if not avoided, could result in minor ormoderate injury.

Indicates a potentially hazardous situation, which ifnot avoided, could result in equipment damage, dataloss, performance degradation, or unexpectedresults.

Indicates a tip that may help you solve a problem orsave time.

Provides additional information to emphasize orsupplement important points of the main text.

Change HistoryUpdates between document issues are cumulative. Therefore, the latest document issue containsall updates made in previous issues.

Changes in Issue 01 (2011-10-15)The Initial commercial release.

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Contents

About This Document.....................................................................................................................ii

1 NE5000E Cluster.............................................................................................................................11.1 Overview............................................................................................................................................................2

1.1.1 Cluster Overview.......................................................................................................................................21.1.2 Cluster Architecture...................................................................................................................................31.1.3 Cluster Features.........................................................................................................................................3

1.2 Inter-Chassis Connection of the NE5000E Cluster............................................................................................41.2.1 Inter-chassis Connections in CCC-0..........................................................................................................41.2.2 Inter-chassis Connections in CCC-2..........................................................................................................5

2 NE5000E CLC..................................................................................................................................82.1 Overview............................................................................................................................................................9

2.1.1 System Overview.......................................................................................................................................92.1.2 System Features.......................................................................................................................................102.1.3 Components of the NE5000E..................................................................................................................102.1.4 Slots layout of the NE5000E...................................................................................................................112.1.5 System Configurations............................................................................................................................12

2.2 Power Supply System.......................................................................................................................................132.2.1 Architecture of the Power Supply System...............................................................................................132.2.2 Partitioned Power Supply on a CLC........................................................................................................142.2.3 8000W DC Power Supply System...........................................................................................................142.2.4 8000W AC Power Supply System...........................................................................................................17

2.3 Heat Dissipation System...................................................................................................................................192.3.1 System Air Channel.................................................................................................................................192.3.2 Fan Speed Adjustment.............................................................................................................................202.3.3 System Fan Module.................................................................................................................................202.3.4 Air Filter..................................................................................................................................................23

2.4 LCD Module.....................................................................................................................................................232.4.1 Appearance and Front Panel of the LCD.................................................................................................232.4.2 Display Mode..........................................................................................................................................242.4.3 Display Contents......................................................................................................................................252.4.4 Technical Specifications..........................................................................................................................32

2.5 Switching Fabric...............................................................................................................................................33

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2.5.1 Introduction to the Switching Fabric.......................................................................................................332.5.2 SFEB........................................................................................................................................................34

2.6 Control Plane....................................................................................................................................................362.6.1 Introduction to the Control Plane............................................................................................................362.6.2 MPU.........................................................................................................................................................37

2.7 Physical Specifications.....................................................................................................................................422.7.1 Chassis Specifications.............................................................................................................................422.7.2 Board Specifications................................................................................................................................43

3 Boards............................................................................................................................................463.1 Flexible Card Line Processing Unit(LPUF100,4 sub-slots).............................................................................47

3.1.1 5-Port 10GBase LAN-XFP Flexible Card(2 sub-slots)...........................................................................483.1.2 5-Port 10GBase LAN/WAN-XFP Flexible Card(2 sub-slots)................................................................513.1.3 2-Port 10GBase LAN-XFP Flexible Card(1 sub-slot)............................................................................543.1.4 2-Port 10GBase LAN/WAN-XFP Flexible Card(1 sub-slot)..................................................................573.1.5 2-Port OC-192c/STM-64c POS/OTU2-XFP Flexible Card(1 sub-slot)..................................................603.1.6 1-port OC-768c/STM-256c POS-LC Flexible Card(2 sub-slots)............................................................633.1.7 24-port 1000Base-X-SFP Flexible Card(2 sub-slots)..............................................................................66

3.2 1-Port 100GBase-CFP Integrated Line Process Unit(LPUI-100)....................................................................693.3 1000Base-X-SFP Optical Interface LPU..........................................................................................................72

3.3.1 10-port 1000Base-X-SFP optical interface LPU.....................................................................................723.3.2 20-port 1000Base-X-SFP optical interface LPU.....................................................................................77

3.4 10G Ethernet Optical Interface LPU................................................................................................................813.4.1 1-port 10GBase LAN-XFP optical interface LPU..................................................................................823.4.2 1-port 10GBase WAN-XFP Optical Interface LPU................................................................................863.4.3 2-port 10GBase LAN-XFP optical interface LPU..................................................................................903.4.4 2-port 10GBase WAN-XFP optical interface LPU.................................................................................953.4.5 4-port 10GBase LAN-XFP optical interface LPU..................................................................................993.4.6 4-port 10GBase WAN-XFP optical interface LPU...............................................................................104

3.5 OC-48c/STM-16c POS-SFP Optical Interface LPU......................................................................................1083.5.1 1-port OC-48c/STM-16c POS-SFP optical interface LPU....................................................................1083.5.2 2-port OC-48c/STM-16c POS-SFP optical interface LPU....................................................................1123.5.3 4-port OC-48c/STM-16c POS-SFP optical interface LPU....................................................................1163.5.4 8-port OC-48c/STM-16c POS-SFP optical interface LPU....................................................................120

3.6 OC-192c/STM-64c POS-XFP Optical Interface LPU....................................................................................1243.6.1 1-port OC-192c/STM-64c POS-XFP optical interface LPU.................................................................1253.6.2 2-port OC-192c/STM-64c POS-XFP optical interface LPU.................................................................1293.6.3 4-port OC-192c/STM-64c POS-XFP optical interface LPU.................................................................133

3.7 Combination LPU...........................................................................................................................................1373.7.1 Overview...............................................................................................................................................1373.7.2 Application............................................................................................................................................1383.7.3 Features and Functions..........................................................................................................................1383.7.4 Panel......................................................................................................................................................138



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3.7.5 Interface Attributes................................................................................................................................1403.7.6 Technical Specifications........................................................................................................................144

4 Cables...........................................................................................................................................1454.1 DC-Input Power Cable...................................................................................................................................146

4.1.1 8000W DC-Input Power Cable..............................................................................................................1464.2 AC-input Power Cable....................................................................................................................................147

4.2.1 8000W AC-input Power Cable..............................................................................................................1474.3 Chassis and Cabinet Grounding Cable...........................................................................................................148

4.3.1 Introduction...........................................................................................................................................1484.3.2 Structure.................................................................................................................................................1484.3.3 Technical Specifications........................................................................................................................148

4.4 Console Port Cable.........................................................................................................................................1494.4.1 Introduction...........................................................................................................................................1494.4.2 Structure.................................................................................................................................................1494.4.3 Technical Specifications........................................................................................................................150

4.5 Auxiliary Port Cable.......................................................................................................................................1504.5.1 Introduction...........................................................................................................................................1504.5.2 Structure.................................................................................................................................................1514.5.3 Technical Specifications........................................................................................................................152

4.6 Clock Cable....................................................................................................................................................1524.6.1 Introduction...........................................................................................................................................1524.6.2 Structure.................................................................................................................................................1534.6.3 Technical Specifications........................................................................................................................155

4.7 Ethernet Cable................................................................................................................................................1574.7.1 Introduction...........................................................................................................................................1574.7.2 Structure.................................................................................................................................................1574.7.3 Technical Specifications........................................................................................................................159

4.8 CXP Fiber.......................................................................................................................................................1604.8.1 Overview of CXP Fiber Optics.............................................................................................................1604.8.2 Structure.................................................................................................................................................1604.8.3 Technical Specifications........................................................................................................................162

4.9 Optical Fiber...................................................................................................................................................1634.9.1 Introduction...........................................................................................................................................1634.9.2 Structure.................................................................................................................................................1644.9.3 Technical Specifications........................................................................................................................165

A Appendix A List of Indicators................................................................................................167A.1 Indicators of NE5000E..................................................................................................................................168

A.1.1 Fan Module Indicators..........................................................................................................................168A.1.2 Power Module Indicators......................................................................................................................168A.1.3 MPU Indicators.....................................................................................................................................169A.1.4 SFU Indicators......................................................................................................................................170A.1.5 SFEB Indicators....................................................................................................................................171



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A.1.6 LPU Indicators......................................................................................................................................172

B Appendix B List of Boards......................................................................................................173B.1 Boards............................................................................................................................................................174B.2 Power Consumption and Weight...................................................................................................................176

C Appendix C List of LPU Interface Attributes......................................................................179C.1 Interface Attributes of 1000Base-X-SFP.......................................................................................................180C.2 Interface Attributes of 10GBase LAN/WAN-XFP........................................................................................181C.3 Interface Attributes of 10GBase LAN/WAN-XFP........................................................................................182C.4 Interface Attributes of OC-48c/STM-16c POS-SFP......................................................................................183C.5 Interface Attributes of OC-192c/STM-64c POS-XFP...................................................................................184

D Appendix D transceiver..........................................................................................................186D.1 Instructions on How to Use an Optical Module............................................................................................187D.2 1 Gbit/s Electrical Transceiver......................................................................................................................189D.3 1.25 Gbit/s GBIC Optical Module.................................................................................................................191D.4 1.25 Gbit/s SFP/eSFP Optical Module..........................................................................................................197D.5 2.5 Gbit/s eSFP Optical Module....................................................................................................................211D.6 10 Gbit/s XFP Optical Module......................................................................................................................216D.7 100Gbps CFP Optical Modules.....................................................................................................................222

E Glossary......................................................................................................................................224

F Acronyms and Abbreviations.................................................................................................226



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1 NE5000E Cluster

About This Chapter

1.1 OverviewThis chapter provides an overview of NE5000E cluster.

1.2 Inter-Chassis Connection of the NE5000E ClusterThis section describes the inter-chassis connection of the NE5000E cluster.

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1.1 OverviewThis chapter provides an overview of NE5000E cluster.

1.1.1 Cluster OverviewThis section describes the components of the Cluster.

An NE5000E cluster consists of Cluster Central Chassis (CCCs) and Cluster Line-card Chassis(CLCs).

A CLC consists of Switch and Fabric Units (SFUs), Line Processing Units (LPUs) andcorresponding Physical Interface Cards (PICs), and Main Processing Units (MPUs).

A CCC consists of (SFUs), Electric Cross Units (ECUs), Optical Flexible Cards (OFCs), InternalCommunication Units (ICUs), and MPUs.

NOTE

A CLC can be separately purchased and can work independently.

Figure 1-1 and Figure 1-2 show the appearance of a CCC.

Figure 1-1 Appearance of the CCC (front view)



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Figure 1-2 Appearance of the CCC (rear view)

1.1.2 Cluster ArchitectureThis section describes NE5000E cluster architecture.

In the NE5000E cluster, multiple CLCs are managed by a centralized system.

The cluster configurations vary with the number of CCCs and CLCs. Based on the number ofCCCs, the NE5000E cluster can be classified into three types, namely, CCC-0 and CCC-2.

Each CLC provides 16 LPU slots, the interface capacity of each CLC is 1.28 Tbit/s. (1 T = 1 x10 12 bits)

l A single NE5000E consists of only one CLC and supports a maximum interface capacityof 1.28 Tbit/s. .

l CCC-0, which is also called a back-to-back (BTB) system, consists of two CLCs andsupports a maximum interface capacity of 2.56 Tbit/s. .

l CCC-2 consists of two CCCs and eight CLCs. The number of CLCs is determined by actualrequirements and cannot be more than eight.

1.1.3 Cluster FeaturesThis section describes the cluster features.



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The NE5000E cluster supports the following main features:

l Upgradable and congestion-free switching fabric, with the switching capacity at the Tbit/s level

l Distributed hardware-based forwardingl Separation of control channels and service channels to ensure unblocked control channelsl Good rollback capability and expansibility, which supports:

– Expansion from a single NE5000E into CCC-0– Expansion from a single NE5000E into CCC-2– Expansion from CCC-0 into CCC-2

l Carrier-class high reliability and manageabilityl Centralized management by the CCCl Shielding at the modular level to meet Electro Magnetic Compatibility (EMC) requirementsl Debugging and diagnosis of CLCs preformed on the CCCl Hot swapping of boards, power modules, and fan modulesl 1:1 backup of MPUsl 3+1 load balancing between the SFUs on the CLCl 7+1 load balancing between the SFUs on the CCCl Backup of key components, such as power modules, fan modules, clocks, and management

busesl Protection against mis-insertion of boardsl Queries about alarm prompts, alarm indications, running statuses, and alarm statusesl Queries about alarm prompts, alarm indications, running statuses, and alarm statuses of the

voltage and ambient temperature

1.2 Inter-Chassis Connection of the NE5000E ClusterThis section describes the inter-chassis connection of the NE5000E cluster.

According to the number of CCCs, the NE5000E-X16 cluster is classified into the followingmodels:l CCC-0

– CCC-0 has no CCC and directly connects to two CLCs. The two CLCs are called themaster chassis and slave chassis. CCC-0 is also called the back-to-back system.

l CCC-2– CCC-2 has two CCCs and connects to up to eight CLCs.

1.2.1 Inter-chassis Connections in CCC-0This section describes Inter-chassis Connections in CCC-0.

The general principle of inter-chassis connection in CCC-0 is as follows: The interfaces withthe same number (the interfaces have same slot numbers, subcard numbers, and interfacenumbers) on two NE5000Es are interconnected.

Inter-chassis connections in CCC-0 include control channels and data forwarding channels.



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l Figure 1-3 shows the connection of control channels.ETH1 on MPUs are used to interconnect two CLCs, as shown inFigure 1-3,four MPUs useETH1 for interconnection.

l Figure 1-3 shows the connection of data forwarding channels. The general principle is thesame as that of the control channel connection.In the figure, subcard 1 on SFE 22 is used as an example. The connections on the otherSFEs are the same and the details are not provided here.

Figure 1-3 Inter-chassis connections in CCC-0 (with all CLCs being NE5000Es)

012345

012345

012345

012345

012345

012345

012345

012345

Master chassis

Slave chassis

17 18

MPU

ETH0

1817

MPU

ETH0

SFE

Subc

ard

0S

ubca

rd 1

012345

012345

012345

012345

012345

012345

012345

012345

19 20 21 22

SFE

19 20 21 22

Sub

card

0S

ubca

rd 1

ETH1 ETH1

1.2.2 Inter-chassis Connections in CCC-2This section describes Inter-chassis Connections in CCC-2.

Inter-chassis connections in CCC-2 include control channels and data forwarding channels.

l Figure 1-4 shows the connection of control channels.

NOTEThe control channels of CLCs can be connected to any idle interfaces numbered from 0 to 7 on the ICUsin slot 11 of CCC 1 and CCC 2. Two CLCs are used as an example in the preceding figure.

l Figure 1-5 shows the connection of data forwarding channels.



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Figure 1-4 Inter-chassis control channel connection in CCC-2 (with all CLCs beingNE5000Es)

CCC 1

11

11

CCC 2

CLC 2

17 18

CLC 1

17 18



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Figure 1-5 Inter-chassis data forwarding channel connection in CCC-2 (with all CLCs beingNE5000Es)

CLC 2CLC 1 CLC 3 CLC 4

CLC 6CLC 5 CLC 7 CLC 8

012345

The connection between subcard CLC1-19-0 and CLC2-19-0 is used as an example. The connections on the other subcards are similar.

0 31 42 5

0 31 42 5

012345

1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8

CCC 1 CCC 2

CLC

5-19-0C

LC5-19-1

CLC

5-20-0C

LC5-20-1

CLC

5-21-0C

LC5-21-1

CLC

5-22-0C

LC5-22-1

CLC

6-19-0C

LC6-19-1

CLC

6-20-0C

LC6-20-1

CLC

6-21-0C

LC6-21-1

CLC

6-22-0C

LC6-22-1

CLC

7-19-0C

LC7-19-1

CLC

7-20-0C

LC7-20-1

CLC

7-21-0C

LC7-21-1

CLC

7-22-0C

LC7-22-1

CLC

8-19-0C

LC8-19-1

CLC

8-20-0C

LC8-20-1

CLC

8-21-0C

LC8-21-1

CLC

8-22-0C

LC8-22-1

CLC

1-19-0C

LC1-19-1

CLC

1-20-0C

LC1-20-1

CLC

1-21-0C

LC1-21-1

CLC

1-22-0C

LC1-22-1

CLC

2-19-0C

LC2-19-1

CLC

2-20-0C

LC2-20-1

CLC

2-21-0C

LC2-21-1

CLC

2-22-0C

LC2-22-1

CLC

3-19-0C

LC3-19-1

CLC

3-20-0C

LC3-20-1

CLC

3-21-0C

LC3-21-1

CLC

3-22-0C

LC3-22-1

CLC

4-19-0C

LC4-19-1

CLC

4-20-0C

LC4-20-1

CLC

4-21-0C

LC4-21-1

CLC

4-22-0C

LC4-22-1



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2 NE5000E CLC

About This Chapter

2.1 OverviewThis section describes the hardware of the NE5000E.

2.2 Power Supply SystemThis chapter describes the power supply system of the NE5000E.

2.3 Heat Dissipation SystemThis section describes the appearance, functions, and specifications of the heat dissipationsystem.

2.4 LCD ModuleThis section describes the appearance, panel, display mode, displayed contents, and technicalspecifications of the LCD module.

2.5 Switching FabricThis section describes the functions of the SFU.

2.6 Control PlaneThis section describes the control plane of the NE5000E.

2.7 Physical SpecificationsThis section describes the specifications of the chassis and boards.

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2.1 OverviewThis section describes the hardware of the NE5000E.

The core router NE5000E is developed on the basis of the hardware platform of the Huawei NEseries product. It is designed for deployment at the key position of the Internet as a super corenode of the backbone network. The NE5000E supports Layer 3 routing and MPLS forwarding.This chapter describes the main hardware components of the NE5000E.

2.1.1 System OverviewThis section describes the system overview.

The NE5000E adopts a centralized routing engine and a distributed forwarding architecture.

The core router NE5000E is designed with an integrated chassis, which can be assembledindependently. The major components of the chassis, including the SFU, LPU, and MPU, areall hot-swappable. In addition, the chassis has independent power supply and heat dissipationsystems.

One NE5000E has 16 slots.The switching capacity of one chassis is 2.56 Tbit/s. (1T=1×1012

bits)

Figure 2-1 Appearance of a single NE5000E



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2.1.2 System FeaturesThis section describes main features of the NE5000E.

The main features of the NE5000E are described as follows.

l Upgradable and congestion-free switching fabric, with the switching capacity at the Tbit/s level.

l The system adopts distributed hardware-based forwarding.l The control channel is separated from the service channel, thus ensuring the smooth

functioning of the control channel.l Carrier-class high reliability and manageability.l Shielding at the modular level to meet Electro Magnetic Compatibility (EMC)

requirements.l Hot-swappable boards, power modules, and fans.l 1:1 redundancy of MPUs.l 3+1 load balancing between the SFUs.l The system is equipped with redundant key components, such as power modules, fan

modules, clocks, and management buses.l The system provides protection against mis-insertion of boards.l The system provides queries about alarm prompts, alarm indications, running statuses, and

alarm statuses of power supply system.l The system provides queries about alarm prompts, alarm indications, running status, and

alarm status of the voltage and ambient temperature.

2.1.3 Components of the NE5000EThis section describes components of the NE5000E

As shown in Figure 2-2, the NE5000E is designed with an integrated chassis. All the majorcomponents are hot-swappable.



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Figure 2-2 Chassis components of the NE5000E

10 11

0 1L/A

L/AL/A

L/AL/A

L/AL/A

L/AL/A

L/AL/A

L/AST

ATUS

10 11

0 1L/A

L/AL/A

L/AL/A

L/AL/A

L/AL/A

L/AL/A

L/AST

ATUS

669mm

（26.34 in.）442mm（17.40 in.）

1600mm

（62.99 in.）

1

2

5

6

7

8

9

10

11

12

13

4

3

1. Air exhaust vent 2. Grounding terminal 3. LCD module 4. Rack-mounting ear 5. Fan module

6. Upper cabling trough 7. MPU 8. SFEB 9. Lower cabling trough 10. Board cage

11. Handle 12. Air intake frame 13. Power module

2.1.4 Slots layout of the NE5000EThis section describes slots layout of the NE5000E

Figure 2-3 shows the slots layout on the NE5000E.



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Figure 2-3 Slots layout on the NE5000E

MPU

LPULPULPULPU

LPULPU

LPULPULPUM

PUSFULPULPULPULPU

LPULPU

LPUSFUSFUSFU

1 2 3 4 17 18 5 6 7 8 9

10 11 12 13 19 20 21 22 14 15 16

ESD ESD

Table 2-1 describes the slots layout on the NE5000E.

Table 2-1 NE5000Eslots layout on the NE5000E

SlotNumber

Quantity

Slot Width Remarks

1-16 16 41 mm (1.6 inches) These slots are used to hold LPUs.

17-18 2 30 mm (1.2 inches) Slots 17 and 18 can hold two MPUs thatwork in 1:1 backup mode.

19-22 4 36 mm (1.4 inches) These slots are used to hold SFUs that workin 3+1 load balancing mode.

2.1.5 System ConfigurationsThis section describes the system configuration of the NE5000E.

Table 2-2 lists the system configurations.

Table 2-2 System configuration data list

Item Typical configuration Remarks

Processor Dominant frequency: 1 GHz -

BootROM 1 MB -

SDRAM 2 GB If the SDRAM on the current deviceis 1 GB, expand it to 2 GB beforeupgrading the device to V8R2C01.

NVRAM 512 KB -



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Item Typical configuration Remarks

Flash 32 MB -

Compact Flash (CF)card

512 MB x 2 Can be used as a mass storage device.

Table 2-3 lists the performance specifications.

Table 2-3 Performance specifications

Item NE5000E Remarks

Switchingcapacity

2.56 Tbit/s Bidirectional

Backplanecapacity

5.175 Tbit/s Bidirectional

Interface capacity 1060 Gbit/s Unidirectional

Number of LPUslots

16 LPU (optional)

Number of MPUslots

2 MPUs work in 1:1 backupmode.

Number of SFUslots

4 SFUs work in 3+1 loadbalancing mode.

Maximuminterface ratesupported byLPUs

100 Gbit/s Unidirectional

2.2 Power Supply SystemThis chapter describes the power supply system of the NE5000E.

2.2.1 Architecture of the Power Supply SystemThis section describes the features of the power supply system.

The NE5000E supports either DC or AC power supply.

The power supply system has the following features:l The power supply system consists of two AC or DC power frames that work in 1+1 backup

mode.l One AC power frame contains three AC rectifier modules.l One DC power frame has three channels of DC input.



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l Both the AC module and the DC module are equipped with the power alarm function.l Partitioned power supply is adopted.

2.2.2 Partitioned Power Supply on a CLCThis section describes partitioned power supply on NE5000E.

Figure 2-4 shows the power supply of the NE5000E.

Figure 2-4 Schematic diagram of the power supply on the NE5000E

LPU1

LPU3

LPU2

LPU4

MPU17

MPU18

LPU5

LPU10

LPU12

LPU11

LPU13

SFU19

SFU20

SFU21

LPU6

LPU8

LPU7

SFU22

LPU15

LPU14

LPU9

LPU16

Each channel supplies power for specific boards. The first channel supplies power for the boardsin the yellow area, the second channel supplies power for the boards in the blue area, and thethird channel supplies power for the boards in the grey area.

The three channels work independently. For example, if only the first channel is connected, onlythe boards in the yellow area are powered on.

Two power modules work in load balancing mode. If the first power input of one power modulebecomes faulty, the fist power input of the another power module supplies power for the boardsin the yellow area.

2.2.3 8000W DC Power Supply SystemThis section describes the appearance, functions, and technical parameters of the DC powersupply module.

Appearance

The DC power modules of the NE5000E work in 1+1 backup mode. The DC power modulesare located behind the plastic panel, and provide distributed DC power supply to the system.The power modules adopt the three-channel power supply method and the partitioned powersupply mode. Each of the power modules inputs three channels of –48 V DC power for differentmodules.

The –48 V DC power module is 3 U (133.35 mm or 5.25 in.) high. Figure 2-5 shows theappearance of a power supply module.



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Figure 2-5 Appearance of the DC power module

POWER1

RTN(+)

NEG(-)

IN1-48 - -60V;3X55A

IN2 IN3

IN1 IN2 IN3

POWER2 POWER3

Figure 2-6 shows the appearance of the panel of a power module.

Figure 2-6 Panel and components of a DC power module

POWER1

NEG(-)

RTN(+)

POWER2

IN2 IN3IN1

IN2 IN3IN1-48 - -60 V ;3X55 A

POWER3

1. First power input 2. Second power input 3. Third power input 4. Handle5. Switch of the first powersupply

6. Switch of the second powersupply

7. Switch of the third powersupply

Indicators of the power module are displayed on its plastic panel through light pipes. Table2-4 describes the indicators.

Table 2-4 Description of the indicators on the DC power module

Indicator Color Description

POWER1 Green Indicates proper functioning of the system. If it is steadilyon, the first power input and output are normal.

Red Indicates a power failure. If it is steadily on, the first powerinput or output is faulty.

POWER2 Green Indicates proper functioning of the system. If it is steadilyon, the second power input and output are normal.

Red Indicates a power failure. If it is steadily on, the secondpower input or output is faulty.



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POWER3 Green Indicates proper functioning of the system. If it is steadilyon, the third power input and output are normal.

Red Indicates a power failure. If it is steadily on, the thirdpower input or output is faulty.

Power Supply Solution

Figure 2-7 shows the DC power supply system.

Figure 2-7 Schematic diagram of DC power supply

Backplane

area 1

area 2

area 3

Power 1

Power 3

Power 2

Power 3

Power 2

Power 1

Power A

Power B

Boards

DCLPU1

LPU3

LPU2

LPU4

MPU17

MPU18

LPU5

LPU10

LPU12

LPU11

LPU13

SFU19

SFU20

SFU21

LPU6

LPU8

LPU7

SFU22

LPU15

LPU14

LPU9

LPU16

DC

DC

DC

DC

DC

The power modules can output primary straight-through power and secondary –48 V DCregulated voltage. Functions are described as follows:

l The primary straight-through power provides short-circuit protection.

l The secondary regulated voltage output provides protection against overcurrent,overvoltage, and short circuit.

l Power can be supplied for the boards in partitioned areas.

l Alarms of the lightning-proof failure and air circuit breakers are supported.

Technical Specifications

Table 2-5 list the technical specifications of DC power module.



16

Table 2-5 Technical specifications of the 8000 W DC power module

Parameter Description

Dimensions (W x D x H) 184 mm x 450 mm x 127 mm (7.24 in. x 17.72 in. x 5.00 in.)

Weight About 9 kg (19.85 lb)

Input voltage range –38 V to –72 V DC

Output current Primarypower

67.5 A x 3

Secondary power

13 A

Maximum output power 8000 W

Maximum input current 75 A x 3

Current of user's air circuitbreaker

≥80 A

2.2.4 8000W AC Power Supply SystemThis section describes the appearance, functions, and the technical parameters of the AC powersupply module.

The NE5000E AC power supply solution is to add an AC transverse system ahead of the 8000WDC power system. The NE5000E AC power supply system is composed of two 8000W DCpower modules , two AC power distribution cabinets , and six rectifier modules . In the system,AC power is sent to the three power inputs of each power distribution cabinet, in which threerectifier modules transform the AC power supply into the DC power supply and respectivelysend the DC power supply to the three DC power inputs of each DC power module.

Figure 2-8 Outline of the AC-DC power distribution frame(front view)



17

Figure 2-9 Outline of the AC-DC power distribution frame(rear view)

Figure 2-10 shows the appearance of an AC-DC power distribution frame.

Figure 2-10 Panel and components of an AC-DC power distribution frame

1. Power input 2. PGND 3. Power output 4. Air circuit breaker

Table 2-6 lists the technical specifications of the AC-DC power distribution frame.

Table 2-6 Technical parameters of the rectifier module

Item Technical specifications

Dimensions (W x D x H) 442 mm x 65 0mm x 88 mm (17.40 in. x 25.59 in. x 3.46 in.)

Input voltage range 200 V AC to 240 V AC(220V AC power grid)100 V AC to 120 V AC(110V AC power grid)

Maximum input current 18.5A/single module

Output voltage -53.5 V DC

Maximum output current 50A/single module

Maximum output power 2900 W/single module



18

2.3 Heat Dissipation SystemThis section describes the appearance, functions, and specifications of the heat dissipationsystem.

2.3.1 System Air ChannelThis section describes the system air channel.

The NE5000E has two fan modules. Each fan module contains three fans.

The locations of the fan modules and air intake vent are shown in Figure 2-11.

Figure 2-11 Locations of the fan modules and air intake vent

1

2

1. Fan module 2. Air intake vent

The NE5000E draws air from the front and exhausts air from the back. This helps heat dissipationin the board insertion area. The system draws air for heat dissipation. Figure 2-12 shows airflows.



19

Figure 2-12 Diagram of air flows

2.3.2 Fan Speed AdjustmentThis section describes the fan Speed adjustment.

When the NE5000E is in full configuration, the system adjusts the fan speed according to thetemperatures reported by the temperature sensors located on the LPUs, SFUs, and MPUs.General principles are listed as follows:

l When the ambient temperature is 27°C (80.6°F) or below, fans rotate at a fixed low speed(60% of the maximum rotational speed), which meets the heat dissipation requirement ofthe system with standard configuration.

l When the ambient temperature is between 27°C (80.6°F) and 45°C (113°F), the speed offans is raised little by little without sharp increase in noise.

l When the ambient temperature is above 45°C (113°F), fans rotate at high speed (100% ofthe maximum rotational speed) to meet the heat dissipation requirements.

2.3.3 System Fan ModuleThis section describes the appearance of the fan module.



20

Appearance of the Fan ModuleThe fan module of the NE5000E is located on the air exhaust vent. Each fan module containsthree fans. When a single fan fails, the system can still work normally in a short period of timeat ambient temperature of 40°C (104°F). Figure 2-13 shows the fan module.

Figure 2-13 Diagram of the fan module

G R

Fan indicators are displayed on the LCD panel through light pipes. Figure 2-14 shows the panelof the fan module, and Figure 2-15 shows the panel of the LCD module.

Figure 2-14 Panel of the fan module



21

Figure 2-15 Fan module indicators

1. Indicator of fan module 1 2. Indicator of fan module 2

Table 2-7 describes the indicators on the panel of the fan module.

Table 2-7 Description of the fan module indicators


RUN Green If the indicator blinks once every 1s (0.5 Hz), fan moduleworks normally.

ALM Red If the indicator is always on, fan module is faulty.

Technical SpecificationsTable 2-8 describes technical specifications of a fan module.

Table 2-8 Technical specifications of a fan module

Item Description

Dimensions(W x D x H) 193 mm x 520 mm x 177 mm (7.60 in. x 20.47 in. x 6.97in.)

Weight 7.2 kg (15.88 lb)

Power consumption 316.8 W

Maximum blast pressure 690 Pa

Maximum blast volume 679.2 m3 /h (4.25E+07 in.3/h)



22

2.3.4 Air FilterThe black sponge air filter placed at the air intake vent is used for dust proof. The air filter canbe removed for cleaning. It is recommended that the air filter be cleaned once every three months.

The NE5000E has one air filter, whose location is shown in Figure 2-16.

Figure 2-16 Location of the air filter

2.4 LCD ModuleThis section describes the appearance, panel, display mode, displayed contents, and technicalspecifications of the LCD module.

2.4.1 Appearance and Front Panel of the LCDThis section describes the appearance and panel of the LCD.

The Liquid Crystal Display (LCD) module displays information about and status of boards,environments, fan modules, and power modules.

The LCD consists of the screen and key panel, as shown in Figure 2-17.



23

Figure 2-17 Plastic panel and components of the LCD

1. LCD screen 2. Key

LCD ScreenThe LCD screen displays information about and status of boards, environments, fan modules,and power modules.

KeysTable 2-9 describes the keys on the LCD panel.

Table 2-9 Keys on the LCD panel

Item Description

Menu Pressing this key switches between the query mode and standbymode of the LCD.

Cancel Pressing this key returns to the previous menu option.

Enter Pressing this key enters the selected submenu.

Mute Pressing this key silents an alarm.

△ Pressing this key scrolls up the screen.

△ Pressing this key scrolls down the screen.

△ Pressing this key scrolls to the left of the screen.

△

Pressing this key scrolls to the right of the screen.

2.4.2 Display ModeThis section describes the conversion between display modules of the LCD.



24

The LCD supports the idle and query modes. The idle mode is the default mode. Figure 2-18shows the conversion between the two modes.

Figure 2-18 Conversion between LCD display modes

Idle timeoutIdle mode Query mode

MENU

Automatic or manual page down

NOTE

"Menu" in Figure 2-18 indicates that you press the Menu button.

Idle Mode

The idle mode displays information about the running status of the system.

After the startup, the LCD displays interfaces of initialization and self-test, and then enters theidle mode.

When no action is done for a certain period of time, the LCD returns to the home screen and theback light goes off. The last line on the LCD displays the running status of each module orprocessing unit.

Query Mode

Table 2-10 describes the operations in query mode.

Table 2-10 Description of operations in query mode

Action Description

Press the Menubutton Enters the query mode.

Press

and

Selects a menu. The selected menu is highlighted.

Press the Enterbutton Enters the submenu of the selected menu or operates the selectedmenu.

Press the Cancelbutton Returns to the previous menu, which is highlighted.

2.4.3 Display ContentsThis section describes the information that is output in various display modes.



25

Idle Mode

Figure 2-19 shows the contents displayed in idle mode.

Figure 2-19 Schematic diagram of the interface in idle mode

The output is displayed as follows:

Item Description

HUAWEI NE5000E # Equipment name

2days 3hours 50minutes # Displays how long the system has beenoperated

LPU1 normal # Information about the working status of thekey part

Here, the last line repeatedly displays the running status of the key parts. N indicates a specificfigure.

Item Description

LPUN normal | abnormal # N indicates 1-16

MPUN normal | abnormal # N indicates 17, 18

SFUN normal | abnormal # N indicates 19-22

FanFrameN normal | abnormal # N indicates 27, 28

PowerModuleN normal | abnormal # N indicates 25, 26

CLKN normal | abnormal # N indicates 23, 24

NOTE

The name of a menu consists of the type of a board and the slot number, such as MPU 17 and LPU 1.

Query Mode



26

In idle mode, press Menu. The main interface of the status query mode is displayed, as shownin Figure 2-20.

Figure 2-20 Schematic diagram of the main interface in query mode

Press and to select the desired contents, and press Enter to enter the selected interface.Press Cancel to return to the previous menu.

LCD Setting Interface

In the interface of the status query mode, select LCD Setting and then press Enter. Figure2-21 shows the display of the LCD setting interface.

Figure 2-21 Schematic diagram of the LCD setting interface

The information is displayed as follows:

Enhance Brightness # Enhance the back light of LCD.Slack Brightness # Weaken the back light of LCD. Beep Test # Test the sound of buzzer. Reset LCD # Reset LCD.

NOTE

l If you press Enter after selecting Enhance Brightness, the brightness of the back light of the LCD isenhanced. You can repeat the operations to get the maximum brightness.

l If you press Enter after selecting Slack Brightness, the brightness of the back light of the LCD isweakened. You can repeat the operations to get the minimum brightness.

Board Info Interface

On the main interface in status query mode, select Board Info and press Enter. The BoardInfo interface is displayed, as shown in Figure 2-22.



27

Figure 2-22 Schematic diagram of the board info interface

Board information includes the slot ID, board name board-in-position information, boardregistration, MonitorBus registration, and master/slave status.

The following describes the interfaces of the MPU, SFU and LPU.

l MPU interface

1. On the Board Info interface, select MPU and then press Enter. The MPU interface isdisplayed, as shown in Figure 2-23. It displays only information about whether the boardis installed.

Figure 2-23 Schematic diagram of the MPU interface

2. For example, select MPU17 and press Enter . The MPU17 interface is displayed, as shownin Figure 2-24.

Figure 2-24 Schematic diagram of the MPU17 interface

The information is displayed as follows:Slot=17 # Slot number. Name is MPU17 # Board name. MonitorBus registered # Information about MonitorBus.CPU 13% # The CPU usage information. MEM 60% # The memory usage information.

l SFU interface



28

1. In the Board Info interface, select SFU and then pressEnter. The SFU informationinterface is displayed, as shown in Figure 2-25. It displays only information about whetherthe board is installed.

Figure 2-25 Schematic diagram of the SFU interface

2. For example, select SFU19 and press Enter. The SFU19 interface is displayed, as shown

in Figure 2-26.

Figure 2-26 Schematic diagram of the SFU19 interface

The information is displayed as follows:Slot=19 # Slot number Name is SFU19 # Board name Board in position, registered # Board status MonitorBus registered #Information about MonitorBus. CPU 13% # The CPU usage information. MEM 60% # The memory usage information.

l LPU interface

1. On the Board Info interface, select LPU and then press Enter. The LPU interface isdisplayed, as shown in Figure 2-27. It displays only information about whether the boardis installed.

Figure 2-27 Schematic diagram of the LPU interface

2. For example, select LPU2 and pressEnter. The LPU2 interface is displayed, as shown in

Figure 2-28.



29

Figure 2-28 Schematic diagram of the LPU2 information interface

The display information is as follows:Slot=2 # Slot number Name is LPU2 # Board name Board in position, registered # Board status MonitorBus registered # Information about MonitorBusCPU 13% # The CPU usage information. MEM 60% # The memory usage information.

Environment Info Interface

In the interface of the status query mode, select Environment Info and press Enter. TheEnvironment Info interface is displayed, as shown in Figure 2-22.

The Environment Info interface displays the temperature and the voltage of the equipment.You can view the interface of any board such as MPU, SFU and LPU.

For example, Figure 2-29 shows the Environment Info interface of the MPU17.

Figure 2-29 Schematic diagram of the MPU17 Environment Info interface

The display information is as follows:

T info # Temperature informationV info # Voltage information Normal | Abnormal # Status

NOTE

You can view the environment information of SFU and LPU by following the above method. The interfacesare the same as shown in Figure 2-29.

FAN and POWER Info Interface

In the interface of the status query mode, select FAN and POWER Info and press Enter. TheFAN and POWER Info interface is displayed, as shown in Figure 2-30.



30

Figure 2-30 Schematic diagram of the FAN and POWER Info interface

l FAN interface

The FAN interface shows the fan speed, temperature, and information about fan in position, fanregistration, and cable in position.

1. In the FAN and POWER Info interface, select FAN and press Enter. The FAN interfaceis displayed, as shown in Figure 2-31.

Figure 2-31 Schematic diagram of the FAN interface

2. For example, select FanFrame27 and press Enter. The FanFrame27 interface displayed,

as shown in Figure 2-32.

Figure 2-32 Schematic diagram of the FanFrame27 interface

The display information is as follows:Fan1-1 # Fan name Speed=60% # Percentage of fan rev Temp Normal # Temperature informationFan in position # Fan in position Fan registered # Fan registered Fan hardware normal # Fan operating status Cable in position # Cable in position

l POWER interface

The POWER interface displays information about power in position, and power and cable inposition.



31

1. In the FAN and POWER Info interface, select POWER and press Enter to display thePOWER interface, as shown in Figure 2-33.

Figure 2-33 Schematic diagram of the power interface

2. For example, select POWER25 and press Enter. The POWER25 interface is displayedas shown in Figure 2-34.

Figure 2-34 Schematic diagram of the POWER25 interface

The display information is as follows:Power in position Power Normal Cable in position

2.4.4 Technical SpecificationsThis section describes the technical parameters of the LCD.

Table 2-11 lists the technical specifications of the LCD.

Table 2-11 Technical specifications of the LCD

Parameter Value

Dimensions( W xD x H)

390 mm x 32 mm x 180 mm (15.35 in. x 1.26 in. x 7.09 in.)

Powerconsumption

8 W

Number ofdisplayed lines

100



32

2.5 Switching FabricThis section describes the functions of the SFU.

2.5.1 Introduction to the Switching FabricThis section describes the principle of SFU.

The switching fabric is the core component of the NE5000E. The switching fabric chip is locatedon the SFU. The whole switching fabric performs switching through cells. Upstream traffic isbuffered, and downstream traffic is scheduled. The switching fabric receives data from theupstream line card, performs data switching, and then routes traffic to the correspondingdownstream line card.

The entire switching fabric is divided into 16 switching planes, as shown in the following figure.Switching planes are logically independent of each other and perform load balancing. Cells canonly be switched through one switching plane.

Two types of switching fabric units are available on the NE5000E, that is, SFU and SFE.

Figure 2-35 NE5000ERelationships between line cards and switching planes

Crossbar

ForwardingTable

ForwardingDecision

IP DATA

ForwardingTable

ForwardingDecision

IP DATA

ForwardingTable

ForwardingDecision

IP DATA

Memory Memory

Memory Memory

Memory Memory

IP DATA

IP DATA

IP DATA

SFU

LPU LPU

In a single chassis system, 16 switching planes are located evenly on four SFUs (each SFUholding four switching planes). One switching plane can switch data between 16 line cards.

In a BTB system, 16 switching planes are located evenly on eight SFEs (each SFE holding twoswitching planes). One switching plane can switch data between 32 line cards.



33

In a cluster, one switching plane is located on both the SFE and the SFU simultaneously. Thereare a total of 16 switching planes, and one switching plane can switch data between up to 1024line cards.

Therefore, different product forms (single chassis system, BTB system, and cluster) adoptdifferent switching fabric units to meet the actual service requirements. A single chassis systemcan use both the SFU and SFE, whereas the BTB system and the cluster can only use the SFE.

The NE5000E has a total of 16 switching planes for data switching between line cards. Eachtraffic pair can choose multiple paths, giving the device much extensibility. In a BTB system,the two chassis are connected through high-speed optical fibers, which ensures that traffic isforwarding free of congestion.

One chassis has four SFUs/SFEs working with 3+1 redundancy.

2.5.2 SFEBThis section describes the functions, panel, interfaces, and technical specifications of an SFEB.

An SFEB is developed based on an old NE5000E chassis and provides multiple switching planes.With SFEBs, a single NE5000E can be expanded from 2.56 Tbit/s to 5.12 Tbit/s (bidirectional).

Figure 2-36 shows the appearance of an SFEB.

Figure 2-36 SFEB appearance

Figure 2-37 shows the SFEB panel appearance.

Figure 2-37 SFEB panel appearance

1. CXP optical interface 2. OFL indicator 3. OFL button

4. RUN indicator 5. ACT indicator 6. CXP insertion indicator

Table 2-12 describes the components on an SFEB panel.



34

Table 2-12 Components on an SFEB panel

Component Description

OFL button To remove a board, you must press the OFL button. Hold the button forsix seconds until the OFL indicator turns on. Then, the board can beremoved.

OFL indicator(red)

If the indicator is on, you can remove the board.

RUN indicator(green)

Before the SFEB is powered on and registers, the indicator status ischanged in the sequence of off–blinks quickly (4 Hz)–off– steady on–blinks slowly (0.5 Hz).After the SFEB is powered on and registers: If the indicator blinks at 0.5Hz, the system is working properly.NOTE

The possible reasons why the indicator is off are listed below:

l BootROM is damaged.

l The SFEB cannot be powered on.

The possible reasons why the indicator blinks quickly are listed below:

l The flash memory is faulty.

l The network port is faulty.

CXP insertionindicator

If the indicator blinks in green, the optical module runs properly. If theindicator is constantly on in green or the indicator is off, the optical modulebecomes faulty.

CXP interface In a back-to-back system: connects the SFEs on the master and slavechassis.In a cluster: connects SFEs on CLCs to OFCs on CCCs.

ACT indicator(green)

If the indicator is on, the ACT is in the normal state.If the indicator is off, the ACT is in the abnormal state.

Table 2-13 lists technical specifications of an SFE.

Table 2-13 Technical specifications of an SFEB

Item Description

Silkscreen SFEB

Power consumption About 200 W

Heat dissipation 649 BTU/hour


Dimensions (width xdepth x height)




35

2.6 Control PlaneThis section describes the control plane of the NE5000E.

2.6.1 Introduction to the Control PlaneThis section describes the functions of the control plane.

As the main control unit, the MPU controls and manages the system in a concentrated way andexchanges data. The MPUs work in 1:1 backup mode. The MPU consists of the main controlunit, switching unit, system clock unit, synchronous clock unit, and system maintenance unit.

System Control and Management UnitAs the system control and management unit, the MPU provides the following functions:

l Route calculation: All routing protocol packets are sent by the forwarding engine to theMPU for processing. In addition, the MPU broadcasts and filters pickets, and downloadsrouting policies from the policy server.

l Outband communication between boards: The LAN switch modules integrated on the MPUprovide outband communications between boards. In this manner, communication betweenMPUs, LPUs, and SFUs is controlled and maintained, and messages are exchanged.

l Device management and maintenance: Devices are managed and maintained through themanagement interfaces (for example, the serial interface) provided by the MPU.

l Data configuration: The MPU stores configuration data, startup files, charging information,upgrade software, and system logs.

l Data storage: The MPU provides two interfaces for CF cards, which serve as mass storagedevices to store data files.

System Clock UnitAs the system clock unit, the MPU provides accurate and reliable Synchronous Digital Hierarchy(SDH) clock signals for LPUs. The MPU can provide two-channel 2.048-MHz synchronousclock signals for the downstream devices, or receive 2.048-MHz or 2.048-Mbit/s externalreference clock signals.

System Maintenance UnitThe system maintenance unit collects monitored information to test system units locally orremotely, or to upgrade system units.

The system maintenance unit periodically collects information about the operation of systemunits through the Monitorbus. Based on the collected information, the system maintenance unitgenerates related control information, for example, detecting the available of boards andadjusting fan speeds. Through the JTAG bus, the system maintenance unit collects monitoredinformation to test system units locally or remotely, or to upgrade system units.

ReliabilityThe main control module, clock module, and LAN switch module of the MPU all work with 1+1 hot backup, providing better system reliability.



36

The MPUs work in 1:1 backup mode. The two MPUs monitor each other's status. If the masterMPU is faulty, the slave MPU automatically becomes the master MPU.

2.6.2 MPUThis section describes the functions,panel and interface of the MPU.

Appearance

Figure 2-38 shows the appearance of the MPU.

Figure 2-38 Appearance of the MPU

Panel

Figure 2-39 shows the panel of the MPU.

Figure 2-39 Panel appearance of the MPU



37

Table 2-14 describes the buttons and indicators on the MPU panel.

Table 2-14 Buttons and indicators on the MPU panel

Indicator/Button

Description

OFL button To remove a board, you must hold the button for six seconds until theOFL indicator turns on.Note: This button takes effect only with the slave MPU.

OFL indicator(red)

If the indicator is on, the board can be pulled out safely.


Before the MPU is powered on and registers, the indicator status ischanged in the sequence of off-blinks quickly (4 Hz)-off-steady on-blinks slowly (0.5 Hz).After the MPU is powered on and registers: If the indicator blinks at 0.5Hz, the system is working properly.NOTE



l The MPU cannot be powered on.


l The CF card is faulty.

l The other control chips on the MPU are faulty, causing the MPU not to beable to initialize.

ALM indicator(red)

If the indicator is steady on, it indicates that the system is in the alarmstate.If the indicator is steady off, it indicates that the system is in the normalstate.

ACT active/standby indicator(green)

If the indicator is steady on, it indicates that the MPU is in the activestate.If the indicator is off, it indicates that the MPU is in the standby state.

Reset button The button is used for resetting the MPU.

CF ACT indicator(green)

If the indicator is on, it indicates that the CF is in position.If the indicator is blinking, it indicates that data is being read or written.If the indicator is off, it indicates that the CF is not in position or can beremoved.

CF OFL button Before removing the CF card, press and hold the CF OFL button forabout six seconds till the OFL indicator is on. Then, you can remove theCF card.



38

Indicator/Button

Description

LINK indicator(green) (on theEthernetinterface)

If the indicator is steady on, it indicates that the link is normal.If the indicator is off, it indicates that the link is Down.

ACT indicator(amber) (onEthernetinterfaces)

If the indicator is blinking, it indicates that data is being transmitted.If the indicator is off, it indicates that no data is being transmitted.

Table 2-15 lists the interfaces on the MPU and their functions.

Table 2-15 Interfaces on the MPU and their functions

Item Connector Description

ETH0 (10M/100M/1000M Base-TXauto-sensing)

RJ45 It connects to the Network Management System(NMS) workstation and has LINK and ACTindicators.

ETH1 (10M/100M/1000M Base-TXauto-sensing)

RJ45 It serves as the system cascading interface.

Console interface RJ45 It connects to the console for on-site configurations ofthe system.

AUX interface RJ45 It connects to the Modem for remote maintenancethrough dialing.

CF interface TYPE I/II It is used to hold a CF card as a mass storage deviceto store data.

CLK-IN1 SMB(Sub-miniature B)

It is used to receive the external 2.048 MHz or 2.048Mbit/s clock signal.

CLK-IN2

CLK-OUT1 SMB It is used to output the 2.048 MHz or 2.048 Mbit/sclock signal to downstream devices.

CLK-OUT2

Interface AttributesTable 2-16 lists the attributes of the 10Base-T/100Base-TX/1000Base-T-RJ45 interface.



39

Table 2-16 Attributes of the 10Base-T/100Base-TX/1000Base-T-RJ45 interface

Attribute Description

Connector RJ45

Working mode 10M/100M/1000M auto-sensing interfaces, supporting half-duplex andfull-duplex modes

Compliantstandard

IEEE802.3-2002

Cablespecifications

Category 5 unshielded twisted pair (UTP) cables are recommended whenthe interface rate is 10 Mbit/s or 100 Mbit/s; super category 5 ShieldedTwisted Pair (STP) cables recommended when the interface rate is 1000Mbit/s

Table 2-17 lists the attributes of the Console interface.

Table 2-17 Attributes of the Console interface


Connector RJ45

Working mode Duplex Universal Asynchronous Receiver/Transmitter (UART)

Electricalattribute

RS-232

Baud rate 9600 bit/s (default value), which can be changed as required

Data equipmenttype

Data Circuit-terminating Equipment (DCE)

Cablespecifications

8-core shielded cable

Table 2-18 lists the attributes of the AUX interface.

Table 2-18 Attributes of the AUX interface


Connector RJ45

Working mode Duplex UART

Electricalattribute

RS-232

Baud rate 9600 bit/s (default value), which can be changed as required



40


Data equipmenttype

Data Terminal Equipments (DTE)

Cablespecifications

8-core shielded cable

Table 2-19 lists the external clock interface attributes.

Table 2-19 External clock interface attributes


Connector SMB

Cablespecifications

75-ohm clock cable

Compliantstandard

G.703


Table 2-20 lists the technical specifications of the MPU.

Table 2-20 Technical specifications of the MPU

Item Specifications

Silk screen of theboard name

MPU

Power consumption 70 W

Heat dissipation 227.1 BTU/hour


Dimensions (W x D xH)


Clock input Two channels of 2.048 Mbit/s or 2.048 MHz signals

Clock output Two channels of 2.048 Mbit/s or 2.048 MHz signals

Active CPU Type PowerPC

Dominantfrequency

1000 MHz

Digit 32 bits



41

Item Specifications

Memory DDR SDRAM 2 GB.

BootROM 1 MB

Flash ROM 32 MB

NVROM 512 KB

CF card 512 MB

2.7 Physical SpecificationsThis section describes the specifications of the chassis and boards.

2.7.1 Chassis SpecificationsThis section describes the physical parameters of the NE5000E.

Table 2-21 lists the physical parameters of the NE5000E.

Table 2-21 Chassis specifications of the NE5000E

Item Item

Dimensions (W x D x H) 442 mm x 669 mm x 1600 mm (17.40 in. x26.34 in. x 63.00 in.)

Installation The chassis can be installed in an N68E-22cabinet or a standard 19-inch cabinet.

Maximum power 7000 W (in full configuration)


Weight Empty chassis 120 kg (264.6 lb)

In fullconfiguration

310 kg (683.55 lb)

DC input voltage Rated voltage -48 V

Maximum voltagerange

–38 V to –72 V

AC input voltage Rated voltage 200 V AC to 240 V AC(220V)100 V AC to 120 V AC(220V)

Maximum voltagerange

90 V AC to 290 V AC

Ambient temperature Long-term 0°C to 40°C (32°F to 104°F)



42

Item Item

Short-term –5°C to 50°C (23°F to 122°F)

Storage temperature –40°C to 70°C (-40°F to 158°F)

Relative humidity Long-term 5%–85%

Short-term 5%–95%

Storage humidity 5%–95%

Long-term altitude Lower than 3,000 m (9842.4 ft.)

Storage altitude Lower than 5,000 m (16404 ft.)

NOTE

The width [442 mm (17.40 in.)] in the preceding table does not count the size of rack-mounting ears.

The measurement point of the temperature and humidity is 1.5 m (4.92 ft.) over the floor and 0.4 m (1.31 ft.) infront of the cabinet with no protection board on the front or back of the cabinet.

Short-term means that the continuous working time does not exceed 48 hours and the accumulated time per yeardoes not exceed 15 days. Otherwise, it is referred to as long-term operation.

2.7.2 Board SpecificationsThis section describes specifications of boards supported by the NE5000E.

Table 2-22 lists the specifications of boards supported by the NE5000E.

Table 2-22 Specifications of boards supported by the NE5000E

Type Description Silkscreen

MPU 2.6.2 MPU MPU

Switch FabricExtended Unit B

2.5.2 SFEB SFEB

Flexible Card LineProcessing Unit

Flexible Card LineProcessing Unit(LPUF-100,4 sub-slots)

NE5000ELPUF-100

FPIC 3.1.1 5-Port 10GBaseLAN-XFP Flexible Card(2 sub-slots)

CP100-5x10GEBase LAN-XFP

3.1.2 5-Port 10GBaseLAN/WAN-XFPFlexible Card(2 sub-slots)

CP100-5x10GEBase LAN/WAN-XFP

3.1.3 2-Port 10GBaseLAN-XFP Flexible Card(1 sub-slot)

CP100-2x10GEBase LAN-XFP



43


3.1.4 2-Port 10GBaseLAN/WAN-XFPFlexible Card(1 sub-slot)

CP100-2x10GEBase LAN/WAN-XFP

3.1.5 2-Port OC-192c/STM-64c POS/OTU2-XFP Flexible Card(1sub-slot)

CP100-2xOC192c/STM64c POS-OTU2-XFP

3.1.6 1-port OC-768c/STM-256c POS-LCFlexible Card(2 sub-slots)

CP100-1xOC768c/STM256c POS-LC

3.1.7 24-port 1000Base-X-SFP Flexible Card(2sub-slots)

CP100-24xFE/GE-SFP

LPUI 3.2 1-Port 100GBase-CFP Integrated LineProcess Unit(LPUI-100)

NE5000ELPUI-1001x100GE-CFP

Line Processing Unit 3.3.1 10-port 1000Base-X-SFP optical interfaceLPU

10×1000Base-SFP

3.3.2 20-port 1000Base-X-SFP optical interfaceLPU

20×1000Base-SFP

3.4.1 1-port 10GBaseLAN-XFP opticalinterface LPU

1×10GBase LAN-XFP

3.4.2 1-port 10GBaseWAN-XFP OpticalInterface LPU

1×10GBase WAN-XFP


2×10GBase LAN-XFP

3.4.4 2-port 10GBaseWAN-XFP opticalinterface LPU

2×10GBase WAN-XFP


4×10GBase LAN-XFP

3.4.6 4-port 10GBaseWAN-XFP opticalinterface LPU

4×10GBase WAN-XFP



44


8-port OC-3c/STM-1cPOS-SFP optical interfaceLPU

8×POS/STM1-SFP


16×POS/STM1-SFP


4×POS/STM4-SFP


8×POS/STM4-SFP

3.5.1 1-port OC-48c/STM-16c POS-SFPoptical interface LPU

1×POS/STM16-SFP


2×POS/STM16-SFP


4×POS/STM16-SFP


8×POS/STM16-SFP

3.6.1 1-port OC-192c/STM-64c POS-XFPoptical interface LPU

1×POS/STM64-XFP


2×POS/STM64-XFP


4×POS/STM64-XFP



45

3 Boards

About This Chapter

This chapter describes the boards of the device.

3.1 Flexible Card Line Processing Unit(LPUF100,4 sub-slots)This chapter describes the structure and specifications of the Flexible Card Line Processing UnitLPUF-100 .

3.2 1-Port 100GBase-CFP Integrated Line Process Unit(LPUI-100)

3.3 1000Base-X-SFP Optical Interface LPUThis section describes the application, functions, panel, interface attributes, and technicalspecifications of the 1000 M Ethernet optical interface LPU.

3.4 10G Ethernet Optical Interface LPUThis section describes the application, functions, panel, interface attributes, and technicalspecifications of the 10G optical interface LPU.

3.5 OC-48c/STM-16c POS-SFP Optical Interface LPUThis section describes the application, functions, panel, interface attributes, and technicalspecifications of the OC-48c/STM-16c POS-SFP optical interface LPU.

3.6 OC-192c/STM-64c POS-XFP Optical Interface LPUThis section describes the application, functions, panel, interface attributes, and technicalspecific ations of the OC-192c/STM-64c POS-XFP optical interface LPU.

3.7 Combination LPUThis section describes the application, functions, panel, interface attributes, and technicalspecifications of the combination LPU.

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description 3 Boards


46

3.1 Flexible Card Line Processing Unit(LPUF100,4 sub-slots)This chapter describes the structure and specifications of the Flexible Card Line Processing UnitLPUF-100 .

OverviewFigure 3-1 shows the appearance of the LPUF-100.

Figure 3-1 Appearance of the LPUF-100

PanelTable 3-1 lists the indicators on the panel.

Table 3-1 Indicators on the panel of the LPUF-100


OFL button An offline button. Before removing a board, press and hold the OFLbutton for about 6s till the OFL indicator is on.

OFL indicator (red) If the indicator is on, you can remove the board.


Before the LPU is powered on and registers, the indicator status ischanged in the sequence of off – blinks quickly (4 Hz) – off – steadyon – blinks slowly (0.5 Hz).After the LPU is powered on and registers: If the indicator blinks at0.5 Hz, the system is working properly.NOTE



l The LPU cannot be powered on.






47


Table 3-2 lists the technical specifications of the LPUF-100.

Table 3-2 Technical specifications of the LPUF-100

Item Specifications


NE5000ELPUF-100

Dimensions (widthx depth x height)


Power consumption(Typical value)

About246 W


Board weight About 7.6 kg (16.76 lb)

Lowest SoftwareVersion

V800R002

Product Specifications

Table 3-3 lists the product specifications of the LPUF-100.

Table 3-3 Product Specifications of the LPUF-100

Item Specifications

Reliability andavailability

The LPUF-100 supports hot swap.The FPIC of the LPUF-100 supports hot swap.

NMS Enhanced command-line interfaceSNMP and MIB support

Operatingenvironment

Long-term ambient temperature: 0°C to 45°C (32°F to 113°F)Short-term ambient temperature: –5°C to 55°C (23°F to 131°F)Long-term relative humidity: 5% to 85%Short-term relative humidity: 0% to 95%

Storageenvironment

Storage temperature: –40°C to 70°C (-40°F to 158°F)Storage humidity: 0% to 95%

3.1.1 5-Port 10GBase LAN-XFP Flexible Card(2 sub-slots)



48

OverviewFigure 3-2 shows the appearance of the 5-Port 10GBase LAN-XFP FPIC.

Figure 3-2 Appearance of the 5-Port 10GBase LAN-XFP FPIC

Features and Functionsl Provides types of loopback functions.l Supports hot swapping.l Provides power supply status and interface status indicators.l Monitors the power supply and temperature of a board.

PanelFigure 3-3 shows the appearance of the panel.

Figure 3-3 Appearance of the Panel

Table 3-4 lists the indicators on the panel.

Table 3-4 Indicators on the panel of the 5-port 10GBase LAN-XFP FPIC


STATUSindicator (green)

If the indicator blinks once every 2s (0.5 Hz), the LPU is in the normalstate. Otherwise, it indicates that the board fails to run normally.

LINK/ACTindicator(green)

If the indicator is on, the link is Up. If the indicator is blinking, the datais being read or written. If the indicator is off, the link is Down.



49

Interface AttributesTable 3-5 lists the interface attributes of the 5-port 10GBase LAN-XFP FPIC.

Table 3-5 Interface attributes of the 5-port 10GBase LAN-XFP FPIC

Attributes Description

Connector type LC

Opticalinterfaceattributes

Compliant with the selected XFP optical module. (For the attributes of XFPmodules, see Table 3-6)

Working mode Full-duplex

Compliantstandard

IEEE 802.3ae

Frame format Ethernet_II, Ethernet_SAP, and Ethernet_SNAP

Networkprotocol

IP

Table 3-6 Attributes of 10G XFP optical modules


Transmissiondistance

0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm

Minimumtransmittingpower

-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm

Maximumtransmittingpower

-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm

Receivingsensitivity

-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype

Multi-mode Single-mode Single-mode Single-mode

The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fiberswith different cores. Table 3-7 lists the relationship between the core, the modal/bandwidth, andthe transmission distance. During configuration, the length of optical fibers is restricted by the



50

transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type. If this type of optical fibers are required, you need to purchaseit additionally.

Table 3-7 The transmission distance of 10G XFP optical modules

Core Fiber(μm) Modal/Bandwidth(Mhz*km)

Transmission distance(km)(mi)

50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-8 lists the technical specifications of the 5-port 10GBase LAN-XFP FPIC.

Table 3-8 Technical specifications of the 5-port 10GBase LAN-XFP FPIC

Item Specifications

Silk screen of the board name CP100-5×10GBase LAN-XFP

Power consumption(Typicalvalue)

About 50.3 W



Dimensions (width x depth xheight)


Connector type LC

Lowest Software Version V800R002

3.1.2 5-Port 10GBase LAN/WAN-XFP Flexible Card(2 sub-slots)

OverviewFigure 3-4 shows the appearance of the 5-port 10GBase LAN/WAN-XFP flexible card.



51

Figure 3-4 Appearance of the 5-port 10GBase LAN/WAN-XFP flexible card

Features and Functionsl Connects to the LPU to forward packets at 50 Gbps and process the 1588 protocol.

l Provides types of loopback functions.

l Supports hot swapping.

l Provides power supply status and interface status indicators.

l Monitors the power supply and temperature of a board.

Panel

Figure 3-5 shows the appearance of the panel.



Table 3-9 Indicators on the panel of the 5-port 10GBase LAN/WAN-XFP flexible card

Indicator Description



LINK/ACTindicator (green)




52

Interface AttributesTable 3-10 lists the interface attributes of the 5-port 10GBase LAN/WAN-XFP flexible card.

Table 3-10 Interface attributes of the 5-port 10GBase LAN/WAN-XFP flexible card


Connector type LC/PC


Compliant with the selected XFP optical module (for the attributes of XFPmodules, see Table 3-11)


Compliantstandard

IEEE 802.3ae


Networkprotocol

IP

Table 3-11 Attributes of the 10G XFP optical module



0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype


The 10G XFP multi-mode optical module supports two types of multi-mode optical fibers withdifferent cores. Table 3-12 lists the relationship between the core, modal/bandwidth, andtransmission distance. During configuration, the length of optical fibers is restricted by the



53

transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type. If this type of optical fibers are required, you need to purchaseit additionally.

Table 3-12 Transmission distance of the 10G XFP optical module

Core Fiber (μm) Modal/Bandwidth(MHz*km)

Transmission distance(km)(mi.)

50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-13 lists the technical specifications of the 5-port 10GBase LAN/WAN-XFP flexiblecard.

Table 3-13 Technical specifications of the 5-port 10GBase LAN/WAN-XFP flexible card

Item Specifications

Silk screen of the board name CP100-5×10GBase LAN/WAN-XFP

Power consumption (typicalvalue)

About 50.3 W





Connector type LC

Lowest software version V800R002

3.1.3 2-Port 10GBase LAN-XFP Flexible Card(1 sub-slot)

OverviewFigure 3-6 shows the appearance of the 2-Port 10GBase LAN-XFP FPIC.



54

Figure 3-6 Appearance of the 2-Port 10GBase LAN-XFP FPIC

Features and Functionsl Provides types of loopback functions.




Panel




Table 3-14 Indicators on the panel of the 2-port 10GBase LAN-XFP FPIC








55

Interface AttributesTable 3-15 lists the interface attributes of the 2-port 10GBase LAN-XFP FPIC.

Table 3-15 Interface attributes of the 2-port 10GBase LAN-XFP FPIC


Connector type LC




Compliantstandard

IEEE 802.3ae


Networkprotocol

IP




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype


The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fiberswith different cores. Table 3-17 lists the relationship between the core, the modal/bandwidth,and the transmission distance. During configuration, the length of optical fibers is restricted by



56

the transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type. If this type of optical fibers are required, you need to purchaseit additionally.




50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-18 lists the technical specifications of the 2-port 10GBase LAN-XFP FPIC.

Table 3-18 Technical specifications of the 2-port 10GBase LAN-XFP FPIC

Item Specifications

Silk screen of the board name CP100-2×10GBase LAN-XFP


About 28.13 W





Connector type LC


3.1.4 2-Port 10GBase LAN/WAN-XFP Flexible Card(1 sub-slot)

OverviewFigure 3-8 shows the appearance of the 2-port 10GBase LAN/WAN-XFP FPIC.



57

Figure 3-8 Appearance of the 2-port 10GBase LAN/WAN-XFP FPIC

Features and Functionsl Provides types of loopback functions.




Panel




Table 3-19 Indicators on the panel of the 2-port 10GBase LAN/WAN-XFP FPIC








58

Interface AttributesTable 3-20 lists the interface attributes of the 2-port 10GBase LAN/WAN-XFP FPIC.

Table 3-20 Interface attributes of the 2-port 10GBase LAN/WAN-XFP FPIC


Connector type LC




Compliantstandard

IEEE 802.3ae


Networkprotocol

IP




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype


The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fiberswith different cores. Table 3-22 lists the relationship between the core, the modal/bandwidth,and the transmission distance. During configuration, the length of optical fibers is restricted by



59

the transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type. If this type of optical fibers are required, you need to purchaseit additionally.




50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-23 lists the technical specifications of the 2-port 10GBase LAN/WAN-XFP FPIC.

Table 3-23 Technical specifications of the 2-port 10GBase LAN/WAN-XFP FPIC

Item Specifications

Silk screen of the board name CP100-2×10GBase LAN/WAN-XFP


About 28.13 W





Connector type LC


3.1.5 2-Port OC-192c/STM-64c POS/OTU2-XFP Flexible Card(1 sub-slot)

OverviewFigure 3-10 shows the appearance of the 2-Port OC-192c/STM-64c POS/OTU2-XFP FlexibleCard.



60

Figure 3-10 Appearance of the 2-Port OC-192c/STM-64c POS/OTU2-XFP Flexible Card

Features and Functionsl Connects to the LPU to forward packets at 20 Gbps and process the 1588 protocol.

l Provides types of loopback functions.




Panel

Figure 3-11shows the panel appearance of the 2-Port OC-192c/STM-64c POS/OTU2-XFPFlexible Card. Table 3-24 lists the indicators on the panel.

Figure 3-11 Panel appearance of the 2-Port OC-192c/STM-64c POS/OTU2-XFP Flexible Card

Table 3-24 Indicators on the panel of the 2-Port OC-192c/STM-64c POS/OTU2-XFP FlexibleCard

Indicator Description







61

Interface AttributesTable 3-25 lists the interface attributes of the 2-Port OC-192c/STM-64c POS/OTU2-XFPFlexible Card.

Table 3-25 Interface attributes of the 2-Port OC-192c/STM-64c POS/OTU2-XFP Flexible Card



Optical interfaceattributes

Compliant with the selected XFP optical module (for the attributes ofXFP modules, see Table 3-26)


Compliantstandard

STM-64c SDH/OC-192c SONET RFC 2615 (1619) /1662

Link protocol PPP or HDLC

Network protocol IP

Table 3-26 Attributes of the 10G XFP optical module



10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71 mi)

Center wavelength 1310 nm 1550 nm 1550 nm

Minimumtransmitting power

-6.0 dBm -1.0 dBm 0 dBm

Maximumtransmitting power

-1.0 dBm 2.0 dBm 4.0 dBm


-11.0 dBm -15.0 dBm -24.0 dBm

Overload power 0.5 dBm -1.0 dBm -7.0 dBm

Optical fiber type Single-mode Single-mode Single-mode

The 10G XFP multi-mode optical module supports two types of multi-mode optical fibers withdifferent cores. Table 3-27 shows the relationship between the core, modal/bandwidth, andtransmission distance. During configuration, the length of optical fibers is restricted by thetransmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type. If this type of optical fibers are required, you need to purchaseit additionally.



62

Table 3-27 Transmission distance of the 10G XFP optical module

Core Fiber (μm) Modal/Bandwidth(MHz*km)

Transmission distance(km)(mi.)

50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-28 lists the technical specifications of the 2-Port OC-192c/STM-64c POS/OTU2-XFPFlexible Card.

Table 3-28 Technical specifications of the 2-Port OC-192c/STM-64c POS/OTU2-XFP FlexibleCard

Item Specifications


CP100-2×OC192c/STM64c POS-OTU2-XFP

Power consumption(typical value)

About 28.13 W





Connector type LC

Lowest softwareversion

V800R002

3.1.6 1-port OC-768c/STM-256c POS-LC Flexible Card(2 sub-slots)

OverviewFigure 3-12 shows the appearance of the 1-port OC-768c/STM-256c POS-LC flexible card.



63

Figure 3-12 Appearance of the 1-port OC-768c/STM-256c POS-LC flexible card

Features and Functionsl Implements the 40-Gbit/s POS frame processing and interface functions, including

encapsulation or decapsulation of POS frames and SDH/SONET mapping or demappingof POS frames.

l Provides one channel of 39.813 Gbit/s optical interface.l Provides a group of Interlaken interfaces within the system.l Supports the extraction and insertion of the DCC field.l Provides status indicators (link and active indicators) for 40-Gbit/s interfaces.l Provides types of loopback functions.l Provides the environment monitoring function of the board.

PanelFigure 3-13 shows the appearance of the 1-port OC-768c/STM-256c POS-LC flexible card.

Figure 3-13 Appearance of the 1-port OC-768c/STM-256c POS-LC flexible card

Table 3-29 describes the indicators on the panel of the 1-port OC-768c/STM-256c POS-LCflecible card.



64

Table 3-29 Descriptions of the indicators on the panel of the 1-port OC-768c/STM-256c POS-LC flexible card

Button/Indicator

Description

STATUS (green) If the indicator flashes once every 2s (0.5 Hz), it indicates that the systemis running normally.

L/A (green) If the indicator is steady on, it indicates that the link is Up.If the indicator flashes, it indicates that data is being received or sent. Ifthe indicator is off, it indicates that the link is Down.

Interface AttributesTable 3-30 lists the interface attributes of the 1-port OC-768c/STM-256c POS-LC flexible card.

Table 3-30 Interface attributes of the 1-port OC-768c/STM-256c POS-LC flexible card


Connector type LC

Compliant standard STM-256c/OC-768c SONET

Link protocol PPP and HDLC

Table 3-31 Attributes of the 40 G optical module



2 km (1.24 mi)

Center wavelength 1550 nm

Minimum outputoptical power

0 dBm

Maximum outputoptical power

3 dBm


-6 dBm

Overload opticalpower

3 dBm

Optical fiber type Single-mode



65


Table 3-32 lists the technical specifications of the 1-port OC-768c/STM-256c POS-LC flexiblecard.

Table 3-32 Technical specifications of the 1-port OC-768c/STM-256c POS-LC FPIC

Item Specifications


CP100-1×OC768c/STM256c POS-LC

Power consumption 37 W


Board weight 0.75 kg (1.65 lb)



Storage temperature -40°C to 70°C (-40°F to 158°F)

Operatingtemperature

Long-term: 0°C to 40°C (32°F to 104°F)Short-term: -5°C to 50°C (23°F to 122°F)

Relative humidity ofworkingenvironment

Long-term: 5% to 85%Short-term: 0% to 95%

3.1.7 24-port 1000Base-X-SFP Flexible Card(2 sub-slots)

Overview

Figure 3-14 shows the appearance of the 24-port 1000Base-X-SFP FPIC.

Figure 3-14 Appearance of the 24-port 1000Base-X-SFP FPIC



66

Features and Functionsl Processes gigabit Ethernet MAC frames in compliance with IEEE 802.3-2002.

l Provides PMD sublayer functions in compliance with IEEE 802.3-2002 and supports1000Base-SX and 1000Base-LX.

l Supports local and remote loopbacks.

l Monitors the environment of boards such as temperature and the voltage.

l Stores and searches the production information on the LPU such as the board type and theboard components.

l Searches the information on optical modules.

Panel




Table 3-33 Indicators on the panel of the 24-port 1000Base-X-SFP FPIC






Interface Attributes

Table 3-34 lists the interface attributes of the 24-port 1000Base-X-SFP FPIC.

Table 3-34 Interface attributes of the 24-port 1000Base-X-SFP FPIC


Connector type LC


Compliant with the selected SFP optical module. For the attributes ofSFP modules, see Table 3-35 and Table 3-36.



67



Compliant standard IEEE 802.3-2002


Network protocol IP

Table 3-35 Attributes of 1000M SFP optical modules



0.55 km(0.34 mi)

10 km(6.21 mi)

40 km(24.86mi)

40 km(24.86mi)

80 km(49.71mi)

100 km(62.14mi)

Center wavelength 850 nm 1310 nm 1310 nm 1550 nm 1550 nm 1550 nm

MinimumTransmittingpower

-9.5 dBm -9.5 dBm -4.5 dBm -4.0 dBm -2.0dBm

0 dBm

MaximumTransmittingpower

-2.5 dBm -3.0 dBm 3.0 dBm 1.0 dBm 5.0 dBm 5.0 dBm


-17.0dBm

-20.0dBm

-22.5dBm

-21.0dBm

-23.0dBm

-30.0dBm

Overload power 0 dBm -3.0 dBm -3.0 dBm -3.0 dBm -3.0dBm

-9.0 dBm

Optical fiber type Multi-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Table 3-36 Attributes of 1000M colorized optical modules



70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50 mi)

70 km(43.50mi)

Centerwavelength

1470nm

1490nm

1510nm

1530nm

1550nm

1570nm

1590nm

1610nm


0 dBm 0 dBm 0 dBm 0 dBm 0 dBm 0 dBm 0dBm

0 dBm



68




5 dBm


-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

Overloadpower


0 dBm

Optical fibertype

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Technical SpecificationsTable 3-37 lists the technical specifications of the 24-port 1000Base-X-SFP FPIC.

Table 3-37 Technical specifications of the 24-port 1000Base-X-SFP FPIC

Item Specifications

Silk screen of the board name CP100-24×FE/GE-SFP


About 42 W





Connector type LC


3.2 1-Port 100GBase-CFP Integrated Line Process Unit(LPUI-100)



69

Overview

Figure 3-16 Appearance of the 1-Port 100GBase-CFP Integrated Line Process Unit

Applicable Environment

The 1-Port 100GBase-CFP Integrated Line Process Unit supports packet forwarding at the linespeed of 100-Gbit/s on a single interface, and provides low-cost and customized solutions forusers.

Features and Functionsl Processes packets at 100 Gbit/s by the MAC/PHY functional module on the Ethernet

interface.l Supports jumbo frames.l Provides an 100 GE optical interface.l Provides a group of Interlaken interfaces to be connected to the 100 G LPU.l Provides status indicators for the CFP module.l Provides types of loopback functions.l Provides power supply status and interface status indicators.l Monitors the power supply and temperature of a board.

Panel

Figure 3-17 shows the panel of the 1-Port 100GBase-CFP Integrated Line Process Unit.

Figure 3-17 1-Port 100GBase-CFP Integrated Line Process Unit panel

Table 3-38 describes the buttons and indicators on the 1-Port 100GBase-CFP Integrated LineProcess Unit panel.



70

Table 3-38 Description of the buttons and indicators on the 1-Port 100GBase-CFP IntegratedLine Process Unit panel

Indicator/Button

Description

OFL button It is an OFL button. Before removing a board, press the OFL button.Hold the button for six seconds till the OFL indicator is on. Then, theboard can be pulled out.

OFL indicator(red)

If the indicator is steady on, it indicates that you can remove the board.

RUN (green) Before the LPU is powered on and registers, the indicator status ischanged in the sequence of off – blinks quickly (4 Hz) – off – steady on– blinks slowly (0.5 Hz).After the LPU is powered on and registers: If the indicator blinks at 0.5Hz, the system is working properly.NOTE







LINK/ACT(green)

If the indicator is steady on, it indicates that the link is normal. If theindicator blinks, it indicates that data is being transmitted. If the indicatoris off, it indicates that the link is Down.


Table 3-39 lists the interface attributes of the 1-Port 100GBase-CFP Integrated Line ProcessUnit.

Table 3-39 Interface attributes of the 1-Port 100GBase-CFP Integrated Line Process Unit


Connector type SC/LC


Compliant with the selected CFP optical module. (For the attributes of CFPmodules, see Table 3-40)



Networkprotocol

IP



71



Transmission distance 10 km (6.21 mi)

Center wavelength 1310 nm

Minimum transmitting power -4.3 dBm

Maximum transmitting power 4.5 dBm

Receiving sensitivity -8.6 dBm

Overload power 4.5 dBm

Optical fiber type Single-mode

Technical SpecificationsTable 3-41 lists technical specifications of the 1-Port 100GBase-CFP Integrated Line ProcessUnit.

Table 3-41 Technical specifications of the 1-Port 100GBase-CFP Integrated Line Process Unit

Item Specifications

Silk screen of the board name NE5000ELPUI-1001×100GE-CFP



Dimensions (width x depth x height) 400 mm x 520 mm x 40 mm (15.75 in. x 20.47in. x 1.57 in.)

Weight About 9.0 kg (19.85 lb)

3.3 1000Base-X-SFP Optical Interface LPUThis section describes the application, functions, panel, interface attributes, and technicalspecifications of the 1000 M Ethernet optical interface LPU.

3.3.1 10-port 1000Base-X-SFP optical interface LPU

OverviewThe 1000Base-X-SFP optical interface LPU combines the flexibility of software and the highperformance of hardware. The LPU can thus flexibly satisfy the carrier's requirements. It



72

provides high-density Layer 2 and Layer 3 interfaces. It can be used on the convergence nodeof the MPLS backbone network and can access the Layer 2 and Layer 3 networks, minimizingthe customer's investment.

Figure 3-18 shows the appearance of the 10-port 1000Base-X-SFP optical interface LPU.

Figure 3-18 Appearance of the 10-port 1000Base-X-SFP optical interface LPU

ApplicationThe 1000Base-X-SFP optical interface LPU can:

l Be used on the convergence node of the MPLS backbone network.l Provide 1000 Mbit/s bandwidth for upstream individual broadband users.l Support a long transmission distance to build a Metropolitan Area Network (MAN).l Support Eth-Trunk.l Provide high-density interfaces that can be bound to provide required bandwidth for service

expansion without increasing investment.

Features and FunctionsThe 1000Base-X-SFP optical interface LPU functions as follows:

l Processes gigabit Ethernet MAC frames in compliance with IEEE 802.3-2002.l Provides PMD sublayer functions in compliance with IEEE 802.3-2002 and supports

1000Base-SX and 1000Base-LX.l Supports local and remote loopbacks.l Monitors the environment of boards such as temperature and the voltage.l Stores and searches the production information on the LPU such as the board type and the

board components.l Searches the information on optical modules.

Based on the hierarchical structure, the 1000Base-X-SFP optical interface LPU is logicallydivided into the service control plane and the packet forwarding plane. In this way, couplingratio and complexity between modules are decreased and reliability is improved.

The service control plane uses the universal CPU and the packet forwarding plane uses the NPor the ASIC.



73

The 1000Base-X-SFP optical interface LPU has a software abnormality detection mechanismto detect the following abnormalities:

l Task abnormality

l Signaling abnormality

l Data abnormality

The system prompts an alarm when an abnormality occurs.

Panel

Figure 3-19 shows the panel appearance of the 1000Base-X-SFP optical interface LPU.

Figure 3-19 Panel appearance of the 10-port 1000Base-X-SFP optical interface LPU

Table 3-42 lists the buttons and indicators on the panel of the 10-port 1000Base-X-SFP opticalinterface LPU.

Table 3-42 Indicators on the panel of the 10-port 1000Base-X-SFP optical interface LPU


OFL button An offline button.Before drawing a board out, press the OFL buttonfor about 6s till the OFL indicator is on.

OFL indicator (Red) If the indicator is on, you can draw the board out.



74


RUN indicator(Green)








LINK/ACT indicator(Green)

If the indicator is on, the link is Up.If the indicator is blinking, thedata is being read or written.If the indicator is off, the link is Down.

The 10-port 1000Base-X-SFP optical interface LPU that uses the SFP optical module has tenLC optical interfaces to send and receive 1000M Ethernet optical signals. The card number ofthe LPU is 0. Its interface number ranges from 0 to 9 from top to bottom.

Interface AttributesTable 3-43 lists the interface attributes of the 10-port 1000Base-X-SFP.

Table 3-43 Interface attributes of the 10-port 1000Base-X-SFP optical interface LPU








Network protocol IP



75




0.5 km(0.31 mi)

10 km(6.21 mi)

40 km(24.86mi)

40 km(24.86mi)

80 km(49.71mi)

100 km(62.14mi)




0 dBm




-17.0dBm

-20.0dBm

-22.5dBm

-21.0dBm

-23.0dBm

-30.0dBm


-9.0 dBm


Single-mode

Single-mode

Single-mode

Single-mode

Single-mode




70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50 mi)

70 km(43.50mi)

Centerwavelength

1470nm

1490nm

1510nm

1530nm

1550nm

1570nm

1590nm

1610nm



0 dBm



5 dBm


-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

Overloadpower


0 dBm

Optical fibertype

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode



76

Technical SpecificationsTable 3-46 lists the technical specifications of the 10-port 1000Base-X-SFP optical interfaceLPU.

Table 3-46 Technical specifications of the 10-port 1000Base-X-SFP optical interface LPU

Item Specifications

Silk screen of the board name 10x1000Base-SFP

Dimensions (width * depth * height) 400 mm x 520 mm x 41mm (15.75 in. x 20.47 in. x1.61 in.)



Board weight About 6 kg (13.23 lb)

Rate 1000 Mbit/s

3.3.2 20-port 1000Base-X-SFP optical interface LPU

OverviewThe 1000Base-X-SFP optical interface LPU combines the flexibility of software and the highperformance of hardware. The LPU can thus flexibly satisfy the carrier's requirements. Itprovides high-density Layer 2 and Layer 3 interfaces. It can be used on the convergence nodeof the MPLS backbone network and can access the Layer 2 and Layer 3 networks, minimizingthe customer's investment.

Figure 3-20 shows the appearance of the 20-port 1000Base-X-SFP optical interface LPU.

Figure 3-20 Appearance of the 20-port 1000Base-X-SFP optical interface LPU

ApplicationThe 1000Base-X-SFP optical interface LPU can:



77

l Be used on the convergence node of the MPLS backbone network.l Provide 1000 Mbit/s bandwidth for upstream individual broadband users.l Support a long transmission distance to build a Metropolitan Area Network (MAN).l Support Eth-Trunk.l Provide high-density interfaces that can be bound to provide required bandwidth for service

expansion without increasing investment.

Features and FunctionsThe 1000Base-X-SFP optical interface LPU functions as follows:

l Processes gigabit Ethernet MAC frames in compliance with IEEE 802.3-2002.l Provides PMD sublayer functions in compliance with IEEE 802.3-2002 and supports

1000Base-SX and 1000Base-LX.l Supports local and remote loopbacks.l Monitors the environment of boards such as temperature and the voltage.l Stores and searches the production information on the LPU such as the board type and the

board components.l Searches the information on optical modules.

Based on the hierarchical structure, the 1000Base-X-SFP optical interface LPU is logicallydivided into the service control plane and the packet forwarding plane. In this way, couplingratio and complexity between modules are decreased and reliability is improved.

The service control plane uses the universal CPU and the packet forwarding plane uses the NPor the ASIC.

The 1000Base-X-SFP optical interface LPU has a software abnormality detection mechanismto detect the following abnormalities:

l Task abnormalityl Signaling abnormalityl Data abnormality


PanelFigure 3-21 shows the panel appearance of the 20-port 1000Base-X-SFP optical interface LPU.



78

Figure 3-21 Panel appearance of the 20-port 1000Base-X-SFP optical interface LPU

Table 3-47 lists the buttons and indicators on the panel of the 1000Base-X-SFP optical interfaceLPU.

Table 3-47 Indicators on the panel of the 20-port 1000Base-X-SFP optical interface LPU



OFL indicator (Red) If the indicator is on, you can draw the board out.









LINK/ACT indicator(Green)

If the indicator is on, the link is Up.If the indicator is blinking, thedata is being read or written.If the indicator is off, the link is Down.



79

The 20-port GE optical interface LPU adopts the pluggable SFP optical module and has 20 pairsof LC optical interfaces for transmitting and receiving GE optical signals. It has two cards. Theupper care number is 0, and the lower card number is 1. The ports for both the cards are numberedfrom 0 to 9 from the top down.

Interface AttributesTable 3-48 lists the interface attributes of the 20-port 1000Base-X-SFP optical interface LPU.

Table 3-48 Interface attributes of the 20-port 1000Base-X-SFP optical interface LPU








Network protocol IP




0.55 km(0.34 mi)

10 km(6.21 mi)

40 km(24.86mi)

40 km(24.86mi)

80 km(49.71mi)

100 km(62.14mi)




0 dBm




-17.0dBm

-20.0dBm

-22.5dBm

-21.0dBm

-23.0dBm

-30.0dBm


-9.0 dBm


Single-mode

Single-mode

Single-mode

Single-mode

Single-mode



80




70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50 mi)

70 km(43.50mi)

Centerwavelength

1470nm

1490nm

1510nm

1530nm

1550nm

1570nm

1590nm

1610nm



0 dBm



5 dBm


-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

Overloadpower


0 dBm

Optical fibertype

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Technical SpecificationsTable 3-51 lists the technical specifications of the 20-port 1000Base-X-SFP optical interfaceLPU.

Table 3-51 Technical specifications of the 20-port 1000Base-X-SFP optical interface LPU

Item Specifications

Silk screen of the board name 20x1000Base-SFP

Dimensions (width * depth *height)

400 mm x 520 mm x 41 mm (15.75 in. x 20.47 in. x 1.61in.)


Heat dissipation 779BTU/hour


3.4 10G Ethernet Optical Interface LPUThis section describes the application, functions, panel, interface attributes, and technicalspecifications of the 10G optical interface LPU.



81

3.4.1 1-port 10GBase LAN-XFP optical interface LPU

OverviewThe 10G Ethernet optical interface LPU provides:

l 10G WAN interfacesl 10G LAN interfaces

Combining the flexibility of software and the high performance of hardware, the 10G Ethernetoptical interface LPU can thus flexibly satisfy the carrier's requirements. Combining theadvantages of routing and switching, the LPU provides high-density Layer 2 and Layer 3interfaces and can be used on the convergence node of the MPLS backbone network.

Figure 3-22 show the appearance of the 1-port 10GBase LAN-XFP optical interface LPU.

Figure 3-22 Appearance of the 1-port 10GBase LAN-XFP optical interface LPU

ApplicationThe 10GBase LAN interface can be connected with only 10G Ethernet LAN interfaces toconstruct the high speed LAN.

The 10GBase Ethernet interface LPU supports MPLS and can access the Layer 2 and Layer 3networks at the same time.

Features and FunctionsThe 10GBase Ethernet optical interface LPU functions as follows:

l The 10GBase Ethernet LAN LPU provides 10G Ethernet LAN interfaces, processes gigabitEthernet MAC frames, and provides Physical Coding Sublayer (PCS) functions incompliance with IEEE 802.3ae.

l The 10GBase Ethernet WAN LPU provides 10G Ethernet WAN interfaces, processesgigabit Ethernet MAC frames, and provides PCS functions and Wide Area InterfaceSublayer (WIS) functions in compliance with IEEE 802.3ae.

l Supports pluggable XFP optical modules.



82

l Supports local and remote loopback functions.l Monitors the environment of boards, such as the temperature and the voltage.l Stores and searches the production information on the LPU such as the board type and the

board components.l Searches information about optical modules.

Based on the hierarchical structure, the 10GBase Ethernet optical interface LPU is logicallydivided into the service control plane and the packet forwarding plane. In this way, couplingdegree and complexity between modules are decreased and reliability is improved.

The service control plane uses the universal CPU, and the packet forwarding plane uses the NPor the ASIC.

The 10GBase Ethernet optical interface LPU has a mechanism for detecting softwareabnormality such as:



PanelFigure 3-23 shows the panel appearance of the 1-port 10GBase LAN-XFP LPU.

Figure 3-23 Panel appearance of the 1-port 10GBase LAN-XFP LPU

RUN

OFLLPU

RX0-0

TX

RX0-0

TX

Table 3-52 lists the buttons and indicators on the panel of the 10GBase LAN-XFP LPU.



83

Table 3-52 Buttons and indicators on the panel of the 10GBase LAN-XFP LPU


OFL button An offline button. Before removing a board, press and hold theOFL button for about 6s till the OFL indicator is on.










LINK/ACT indicator(green)

If the indicator is on, the link is Up. If the indicator is blinking, thedata is being read or written. If the indicator is off, the link is Down.

The 1-port 10GBase LAN-XFP LPU uses the pluggable optical module. You can select theoptical module of different transmission distances as required. The board has an LC opticalinterface that is used to receive and send 10G Ethernet optical signals. The card number and theinterface number of the board are 0.


Table 3-53 lists the interface attributes of the 1-port 10GBase LAN-XFP optical interface LPU.

Table 3-53 Interface attributes of the 1-port 10GBase LAN-XFP optical interface LPU




Compliant with the selected XFP optical module. For the attributesof XFP modules, see Table 3-54.


Compliant standard IEEE 802.3ae


Network protocol IP



84




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype


The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fiberswith different cores. Table 3-55 lists the relationship between the core, the modal/bandwidth,and the transmission distance. During configuration, the length of optical fibers is restricted bythe transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type. If this type of optical fibers are required, you need to purchaseit additionally.




50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-56 lists the technical specifications of the 1-port 10GBase LAN/WAN-XFP LPU.



85

Table 3-56 Technical specifications of the 1-port 10GBase LAN/WAN-XFP LPU

Item Specifications

Silk screen of the board name 1 x 10GBase LAN-XFP



Dimensions (width x depth x height) 400 mm x 520 mm x 41 mm (15.75 in. x 20.47 in.x 1.61 in.)


Rate 10 Gbit/s

3.4.2 1-port 10GBase WAN-XFP Optical Interface LPU

Overview10G Ethernet optical interface LPUs include WAN LPUs and LAN LPUs.

l WAN LPUs encapsulate Ethernet frames in SDH/SONET frames before transmitting themthrough optical fibers. Interfaces on a WAN LPU can be connected to interfaces on otherWAN LPUs or connected to SDH/SONET transmission devices. WAN LPUs are mainlyused for WAN interconnection.

l LAN LPUs implement electro-optic conversion in transmitting Ethernet frames throughoptical fibers. Interfaces on a LAN LPU can be connected to only the interfaces on otherLAN LPUs. LAN LPUs are mainly used for the LAN interconnection.


Figure 3-24 show the appearance of the 1-port 10GBase WAN-XFP optical interface LPU.

Figure 3-24 Appearance of the 1-port 10GBase WAN-XFP optical interface LPU



86

ApplicationThe 10GBase WAN interface can be connected with transmission devices to construct the high-speed WAN.

The 10GBase LAN interface can be connected with only 10G Ethernet LAN interfaces toconstruct the high speed LAN.




l Supports pluggable XFP optical modules.l Supports local and remote loopback functions.l Monitors the environment of boards, such as the temperature and the voltage.l Stores and searches the production information on the LPU such as the board type and the







PanelFigure 3-25 shows the panel appearance of the 1-port 10GBase WAN-XFP optical interfaceLPU.



87

Figure 3-25 Panel appearance of the 1-port 10GBase WAN-XFP LPU

RUN

OFLLPU

RX0-0

TX

RX0-0

TX

Table 3-57 lists the buttons and indicators on the panel of the 1-port 10GBase WAN-XFP opticalinterface LPU.

Table 3-57 Buttons and indicators on the panel of the 10GBase WAN-XFP LPU
















88

The 1-port 10GBase WAN-XFP LPU uses the pluggable optical module. You can select theoptical module of different transmission distances as required. The board has an LC opticalinterface that is used to receive and send 10G Ethernet optical signals. The card number and theinterface number of the board are 0.

Interface AttributesTable 3-58 lists the interface attributes of the 1-port 10GBase WAN-XFP optical interface LPU.

Table 3-58 Interface attributes of the 10GBase WAN-XFP LPU








Network protocol IP




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype




89

The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fiberswith different cores. Table 3-60 lists the relationship between the core, the modal/bandwidth,and the transmission distance. During configuration, the length of optical fibers is restricted bythe transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type, If this type of optical fibers are required, you need to purchaseit additionally.




50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-61 lists the technical specifications of the 1-port 10GBase WAN-XFP LPU.

Table 3-61 Technical specifications of the 1-port 10GBase WAN-XFP LPU

Item Specifications

Silk screen of the board name 1 x 10GBase WAN-XFP


Heat dissipation 454BTU/hour


400 mm x 520 mm x 41mm (15.75 in. x 20.47 in. x 1.61in.)


Rate 10 Gbit/s







90



ApplicationThe 10GBase LAN interface can be connected with only 10G Ethernet LAN interfaces toconstruct the high speed LAN.










l Task abnormality



91

l Signaling abnormalityl Data abnormality


PanelFigure 3-27 shows the panel appearance of the 2-port 10GBase LAN-XFP optical interfaceLPU.


Table 3-62 lists the buttons and indicators on the panel of the 2-port 10GBase LAN-XFP opticalinterface LPU.







92












The 2-port 10GBase LAN-XFP LPU uses the pluggable optical module. You can select theoptical module of different transmission distances as required. The board has two LC opticalinterfaces that is used to receive and send 10G Ethernet optical signals. The card number is 0,the interface number are 0 and 1.

Interface AttributesTable 3-63 lists the interface attributes of the 10GBase Ethernet optical interface LPU.

Table 3-63 Interface attributes of the 10GBase LAN-XFP LPU








Network protocol IP



93




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype






50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-66 lists the technical specifications of the 2-port 10GBase LAN-XFP LPU.



94

Table 3-66 Technical specifications of the 2-port 10GBase LAN-XFP LPU

Item Specifications

Silk screen of the board name 2 x 10 GBase LAN-XFP



Dimensions (width x depth x height) 400 mm x 520 mm x 41mm (15.75 in. x 20.47 in.x 1.61 in.)


Rate 10 Gbit/s


3.4.4 2-port 10GBase WAN-XFP optical interface LPU








95
















96


Table 3-67 lists the buttons and indicators on the panel of the 10GBase WAN-XFP LPU.

















97

The 2-port 10GBase WAN-XFP LPU uses the pluggable optical module. You can select theoptical module of different transmission distances as required. The board has two LC opticalinterfaces that is used to receive and send 10G Ethernet optical signals. The card number is 0,the interface number are 0 and 1.










Network protocol IP




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype


The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fiberswith different cores. Table 3-70 lists the relationship between the core, the modal/bandwidth,



98

and the transmission distance. During configuration, the length of optical fibers is restricted bythe transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type. If this type of optical fibers are required, you need to purchaseit additionally.




50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-71 lists the technical specifications of the 2-port10GBase WAN-XFP LPU.


Item Specifications

Silk screen of the board name 2 x 10 GBase WAN-XFP



Dimensions (width x depth x height) 400 mm x 520 mm x 41mm (15.75 in. x 20.47in. x 1.61 in.)


Rate 10 Gbit/s








99



Application



Features and Functions

The 10GBase Ethernet optical interface LPU functions as follows:






The service control plane uses the universal CPU, and the packet forwarding plane uses two NPsor an ASIC.




100



PanelFigure 3-31 shows the panel appearance of the 4-port 10GBase LAN-XFP optical interfaceLPU.


Table 3-72 lists the buttons and indicators on the panel of the 10GBase LAN-XFP LPU.







101












The 4-port 10GBase LAN-XFP LPU uses the pluggable optical module. You can select theoptical module of different transmission distances as required. The board has four LC opticalinterfaces that is used to receive and send 10G Ethernet optical signals. It has two cards. Thenumber of the upper card is 0 and its ports are numbered from 0 to 1. The number of the lowercard is 1 and its ports are numbered from 0 to 1.


Table 3-73 Interface attributes of the 10GBase LAN-XFP LPU








Network protocol IP



102




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype






50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-76 lists the technical specifications of the 4-port10GBase LAN-XFP LPU.



103

Table 3-76 Technical specifications of the 4-port 10GBase LAN-XFP LPU

Item Specifications

Silk screen of the board name 4 x 10 GBase LAN-XFP



Dimensions (width x depth xheight) 400 mm x 520 mm x 41 mm (15.75 in. x 20.47 in.x 1.61 in.)


Rate 10 Gbit/s

3.4.6 4-port 10GBase WAN-XFP optical interface LPU









104















105


Table 3-77 lists the buttons and indicators on the panel of the 10GBase WAN-XFP LPU.

















106

The 4-port 10GBase WAN-XFP LPU uses the pluggable optical module. You can select theoptical module of different transmission distances as required. The board has four LC opticalinterfaces that is used to receive and send 10G Ethernet optical signals. It has two cards. Thenumber of the upper card is 0 and its ports are numbered from 0 to 1. The number of the lowercard is 1 and its ports are numbered from 0 to 1.


Table 3-78 lists the interface attributes of the 10GBase Ethernet optical interface LPU.









Network protocol IP




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype




107

The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fiberswith different cores. Table 3-80 lists the relationship between the core, the modal/bandwidth,and the transmission distance. During configuration, the length of optical fibers is restricted bythe transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type, If this type of optical fibers are required, you need to purchaseit additionally.




50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)


Table 3-81 lists the technical specifications of the 4-port10GBase WAN-XFP LPU.


Item Specifications

Silk screen of the board name 4 x 10 GBase WAN-XFP



Dimensions (width x depth xheight) 400 mm x 520 mm x 41 mm (15.75 in. x 20.47in. x 1.61 in.)


Rate 10 Gbit/s

3.5 OC-48c/STM-16c POS-SFP Optical Interface LPUThis section describes the application, functions, panel, interface attributes, and technicalspecifications of the OC-48c/STM-16c POS-SFP optical interface LPU.

3.5.1 1-port OC-48c/STM-16c POS-SFP optical interface LPU

Overview

The OC-48c/STM-16c POS-SFP optical interface LPU provides 2.5 Gbit/s optical interfaces.



108

The following figures show the appearance of the OC-48c/STM-16c POS-SFP optical interfaceLPU.

Figure 3-34 Appearance of the 1-port OC-48c/STM-16c POS-SFP optical interface LPU

ApplicationThe OC-48c/STMc-16c POS-SFP optical interface LPU can be used on the convergence nodeof the MPLS backbone network. In a MAN, it can be used as a backbone node and can provide2.5 G bandwidth.

Features and FunctionsThe OC-48c/STM-16c POS-SFP optical interface LPU functions as follows:

l Encapsulates or decapsulates POS frames of data stream and provides SDH/SONETmapping and demapping of POS frames.

l Supports pluggable SFP optical modules.l Supports local and remote loopback functions.l Monitors the environment of boards, such as the temperature and the voltage.l Stores and searches the production information on the LPU, such as the board type and the


Based on the hierarchical structure, the OC-48c/STM-16c POS-SFP optical interface LPU islogically divided into the service control plane and the packet forwarding plane. In this way,coupling degree and complexity between modules are decreased and reliability is improved.

The service control plane uses the universal CPU and the packet forwarding plane uses two NPsor an ASIC.

The OC-48c/STM-16c POS-SFP optical interface LPU has a mechanism for detecting softwareabnormality such as:





109

PanelThe following figures show the panel appearance of the OC-48c/STM-16c optical interface POS-SFP LPU.

Figure 3-35 Panel appearance of the 1-port OC-48c/STM-16c POS-SFP LPU

Table 3-82 lists the buttons and indicators on the panel of the OC-48c/STM-16c POS-SFP LPU.

Table 3-82 Buttons and indicators on the panel of the OC-48c/STM-16c POS-SFP LPU






110












The 1-port OC-48c/STM-16c POS-SFP LPU has an LC optical interface that is used to receiveand send OC-48c/STM-16c optical signals. The board and its interface are numbered 0.

Interface AttributesTable 3-83 lists the interface attributes of the OC-48c/STM-16c POS-SFP LPU.

Table 3-83 Interface attributes of the OC-48c/STM-16c POS-SFP LPU




Compliant with the selected SFP optical module. (For the attributesof SFP modules, see Table 3-84.)


Compliant standard STM-16c SDH/OC-48c SONET RFC 1619/1661/1662/2615


Network protocol IP

Table 3-84 Attributes of 2.5G SFP optical modules



2 km (1.24 mi) 15 km (9.32 mi) 40 km (24.86mi)

80 km (49.71 mi)



111


Centerwavelength

1310 nm 1310 nm 1310 nm 1550 nm


-10.0 dBm -5.0 dBm -2.0 dBm -2.0 dBm


-3.0 dBm 0 dBm 3.0 dBm 3.0 dBm


-21.0 dBm -21.0 dBm -30.0 dBm -30.0 dBm

Overloadpower

-3.0 dBm 0 dBm -9.0 dBm -9.0 dBm

Optical fibertype


Technical SpecificationsTable 3-85 lists the technical specifications of the OC-48c/STM-16c POS-SFP LPU.

Table 3-85 Technical specifications of the 1-port OC-48c/STM-16c POS-SFP LPU

Item Specifications

Silk screen of the board name 1 x POS/STM16-SFP




400 mm x 520 mm x 41mm (15.75 in. x 20.47 in. x 1.61 in.)


Rate 2.5 Gbit/s


OverviewThe OC-48c/STM-16c POS-SFP optical interface LPU provides 2.5 Gbit/s optical interfaces.




112


Application

The OC-48c/STMc-16c POS-SFP optical interface LPU can be used on the convergence nodeof the MPLS backbone network. In a MAN, it can be used as a backbone node and can provide2.5 G bandwidth.


The OC-48c/STM-16c POS-SFP optical interface LPU functions as follows:


l Supports pluggable SFP optical modules.

l Supports local and remote loopback functions.

l Monitors the environment of boards, such as the temperature and the voltage.

l Stores and searches the production information on the LPU, such as the board type and theboard components.

l Searches information about optical modules.




l Task abnormality


l Data abnormality




113










114












The 2-port OC-48c/STM-16c POS-SFP LPU has two LC optical interfaces that are used toreceive and send OC-48c/STM-16c optical signals. The board number is 0. The interface numberranges from 0 to 1 from top to bottom.


Table 3-87 lists the interface attributes of the OC-48c/STM-16c POS-SFP LPU.









Network protocol IP




2 km (1.24 mi) 15 km (9.32 mi) 40 km (24.86mi)

80 km (49.71 mi)



115


Centerwavelength

1310 nm 1310 nm 1310 nm 1550 nm


-10.0 dBm -5.0 dBm -2.0 dBm -2.0 dBm




-21.0 dBm -21.0 dBm -30.0 dBm -30.0 dBm

Overloadpower

-3.0 dBm 0 dBm -9.0 dBm -9.0 dBm

Optical fibertype




Item Specifications

Silk screen of the boardname

2 x POS/STM16-SFP



Dimensions (width * depth* height)



Rate 2.5 Gbit/s






116


Application













l Task abnormality


l Data abnormality




117










118












The 4-port OC-48c/STM-16c POS-SFP LPU has four LC optical interfaces that are used toreceive and send OC-48c/STM-16cc optical signals. The board number is 0. The interfacenumber ranges from 0 to 3 from top to bottom.


Table 3-91 lists the interface attributes of the OC-48c/STM-16c POS-SFP LPU.









Network protocol IP




2 km (1.24 mi) 15 km (9.32 mi) 40 km (24.86mi)

80 km (49.71 mi)



119


Centerwavelength

1310 nm 1310 nm 1310 nm 1550 nm


-10.0 dBm -5.0 dBm -2.0 dBm -2.0 dBm




-21.0 dBm -21.0 dBm -30.0 dBm -30.0 dBm

Overloadpower

-3.0 dBm 0 dBm -9.0 dBm -9.0 dBm

Optical fibertype




Item Specifications







Rate 2.5 Gbit/s






120


Application













l Task abnormality


l Data abnormality




121



RUN

OFLLPU

RX0-0

TX

LINK/A

CT

RX0-1

TX

LINK/A

CT








122












The 8-port OC-48c/STM-16c POS-SFP LPU has eight LC optical interfaces that are used toreceive and send OC-48c/STM-16c optical signals. You can select the pluggable SFP opticalmodule of different transmission distances as required. It has two cards. The number of the uppercard is 0 and its ports are numbered from 0 to 3. The number of the lower card is 1 and its portsare numbered from 0 to 3.

Interface AttributesTable 3-95 lists the interface attributes of the OC-48c/STM-16c POS-SFP LPU.









Network protocol IP



123




2 km (1.24 mi) 15 km (9.32 mi) 40 km (24.86mi)

80 km (49.71 mi)

Centerwavelength

1310 nm 1310 nm 1310 nm 1550 nm


-10.0 dBm -5.0 dBm -2.0 dBm -2.0 dBm




-21.0 dBm -21.0 dBm -30.0 dBm -30.0 dBm

Overloadpower

-3.0 dBm 0 dBm -9.0 dBm -9.0 dBm

Optical fibertype




Item Specifications







Rate 2.5 Gbit/s

3.6 OC-192c/STM-64c POS-XFP Optical Interface LPUThis section describes the application, functions, panel, interface attributes, and technicalspecific ations of the OC-192c/STM-64c POS-XFP optical interface LPU.



124

3.6.1 1-port OC-192c/STM-64c POS-XFP optical interface LPU

Overview

The OC-192c/STM-64c POS-XFP optical interface provides 10 Gbit/s optical interfaces.

Figure 3-42 shows the appearance of the OC-192c/STM-64c POS-XFP optical interface LPU.

Figure 3-42 Appearance of the 1-port OC-192c/STM-64c POS-XFP optical interface LPU

Application

The OC-192c/STM-64c POS-XFP optical interface LPU can be used on the convergence nodeof the MPLS backbone network.


The OC-192c/STM-64c POS-XFP optical interface LPU functions as follows:




Based on the hierarchical structure, the OC-192c/STM-64c POS-XFP optical interface LPU islogically divided into the service control plane and the packet forwarding plane. In this way,coupling degree and complexity between modules are decreased and reliability is improved.


The OC-192c/STM-64c POS-XFP optical interface LPU has a mechanism for detecting softwareabnormality such as:



125



PanelFigure 3-43 shows the panel appearance of the OC-192c/STM-64c POS-XFP LPU.

Figure 3-43 Panel appearance of the 1-port OC-192c/STM-64c POS-XFP LPU

Table 3-98 lists the buttons and indicators on the panel of the OC-192c/STM-64c POS-XFPLPU.

Table 3-98 Indicators on the panel of the OC-192c/STM-64c POS-XFP LPU


OFL button An offline button. Before removing a board, press the OFL button forabout 6s till the OFL indicator is on.




126











If the indicator is on, the link is Up.If the indicator is blinking, thedata is being read or written. If the indicator is off, the link is Down.

The interfaces of the OC-192c/STM-64c POS-XFP LPU are described as follows:

The 1-port OC-192c/STM-64c POS-XFP LPU has an LC optical interface that is used to receiveand send OC-192c/STM-64c optical signals. The LPU uses the pluggable XFP optical module.You can select the optical module of different transmission distances as required. The boardnumber and the interface number are 0.

Interface AttributesTable 3-99 lists the interface attributes of the OC-192c/STM-64c POS-XFP LPU.

Table 3-99 Interface attributes of the OC-192c/STM-64c POS-XFP LPU




Compliant with the selected XFP optical module. (For the attributesof XFP modules, see Table 3-100.)


Compliant standard STM-64c SDH/OC-192c SONET RFC 2615 (1619) /1662


Network protocol IP



127




10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71 mi)



-6.0 dBm -1.0 dBm 0 dBm


-1.0 dBm 2.0 dBm 4.0 dBm


-11.0 dBm -15.0 dBm -24.0 dBm



NOTE

The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fibers with differentcores. Table 3-101 lists the relationship between the core, the modal/bandwidth, and the transmission distance.During configuration, the length of optical fibers is restricted by the transmission distance. In addition, the opticalfiber with the 50-um core and 2000-MHz*km modal/bandwidth is a special type. If this type of optical fibersare required, you need to purchase it additionally.




50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)


Table 3-102 lists the technical specifications of the OC-192c/STM-64c POS-XFP LPU.

Table 3-102 Technical specifications of the OC-192c/STM-64c POS-XFP LPU

Item Specifications

Silk screen of the board name 1 x POS/STM64-XFP



128

Item Specifications






Rate 10 Gbit/s


OverviewThe OC-192c/STM-64c POS-XFP optical interface provides 10 Gbit/s optical interfaces.



ApplicationThe OC-192c/STM-64c POS-XFP optical interface LPU can be used on the convergence nodeof the MPLS backbone network.

Features and FunctionsThe OC-192c/STM-64c POS-XFP optical interface LPU functions as follows:



board components.



129





l Task abnormality


l Data abnormality


Panel

Figure 3-45 shows the panel appearance of the OC-192c/STM-64c POS-XFP LPU.





130
















The 2-port OC-192c/STM-64c POS-XFP LPU has an LC optical interface that is used to receiveand send OC-192c/STM-64c optical signals. The LPU uses the pluggable XFP optical module.You can select the optical module of different transmission distances as required. The cardnumber is 0, the interface number are 0 and 1.










Network protocol IP



131




10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71 mi)



-6.0 dBm -1.0 dBm 0 dBm


-1.0 dBm 2.0 dBm 4.0 dBm


-11.0 dBm -15.0 dBm -24.0 dBm



NOTE





50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)


Table 3-107 lists the technical specifications of the OC-192c/STM-64c POS-XFP LPU.


Item Specifications

Silk screen of the board name 2 x POS/STM64-XFP



132

Item Specifications

Power consumption About 246W





Rate 10 Gbit/s


OverviewThe OC-192c/STM-64c POS-XFP optical interface provides 10 Gbit/s optical interfaces.



ApplicationThe OC-192c/STM-64c POS-XFP optical interface LPU can be used on the convergence nodeof the MPLS backbone network.

Features and FunctionsThe OC-192c/STM-64c POS-XFP optical interface LPU functions as follows:






133






PanelFigure 3-47 shows the panel appearance of the OC-192c/STM-64c POS-XFP LPU.





134
















The 4-port OC-192c/STM-64c POS-XFP LPU has an LC optical interface that is used to receiveand send OC-192c/STM-64c optical signals. The LPU uses the pluggable XFP optical module.You can select the optical module of different transmission distances as required. It has twocards. The number of the upper card is 0 and its ports are numbered from 0 to 1. The number ofthe lower card is 1 and its ports are numbered from 0 to 1.










Network protocol IP



135




10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71 mi)



-6.0 dBm -1.0 dBm 0 dBm


-1.0 dBm 2.0 dBm 4.0 dBm


-11.0 dBm -15.0 dBm -24.0 dBm



NOTE





50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)

Technical SpecificationsTable 3-112 lists the technical specifications of the OC-192c/STM-64c POS-XFP LPU.



136


Item Specifications

Silk screen of the board name 4 x OC-192c/STM-64c POS-XFP



Dimensions (width * depth * height) 400 mm x 520 mm x 41 mm (15.75 in. x 20.47 in. x1.61 in.)


Rate 10 Gbit/s

3.7 Combination LPUThis section describes the application, functions, panel, interface attributes, and technicalspecifications of the combination LPU.

3.7.1 Overview

The combination LPU supports the mixing of various interfaces. That is, an LPU can provideboth Ethernet and POS interfaces. The combination LPU falls into the following types:

l 2*OC-192c/STM-64c POS-XFP+4*OC-48c/STM-16c POS-SFP optical interface LPUl 2*OC-192c/STM-64c POS-XFP+10*1000Base-SFP optical interface LPUl 2*OC-192c/STM-64c POS-XFP+2*10GBase LAN-XFP optical interface LPUl 2*OC-192c/STM-64c POS-XFP+2*10GBase WAN-XFP optical interface LPUl 2*10GBase LAN-XFP+4*OC-48c/STM-16c POS-SFP optical interface LPUl 2*10GBase WAN-XFP+4*OC-48c/STM-16c POS-SFP optical interface LPUl 4*OC-48c/STM-16c POS-SFP+10*1000Base-SFP optical interface LPU

Figure 3-48 shows the appearance of the 2*OC-192c/STM-64c POS-XFP+2*10GBase WAN-XFP optical interface LPU.

Figure 3-48 Appearance of 2*OC-192c/STM-64c POS-XFP+2*10GBase WAN-XFP opticalinterface LPU



137

3.7.2 Application

The combination LPU can be used on the convergence node of the backbone network.

3.7.3 Features and Functions

FunctionsThe combination LPU functions as follows:

l Provides SPI4.2.l Supports pluggable optical modules.l Supports local and remote loopbacks.l Monitors the environment of boards such as temperature and voltage.l Stores and queries the production information on the LPU such as the board type and the

board components.l Queries the information on optical modules.

ReliabilityBased on the hierarchical structure, the multiple types interfaces LPU is logically divided intothe service control plane and the packet forwarding plane. In this way, coupling ratio andcomplexity between modules are decreased and the reliability is improved.


Recovery MechanismThe combination LPU has a software abnormality detection mechanism to detect the followingabnormalities:


The system prompts an alarm when an abnormality occurs. In addition, the system restarts inthe case of a fatal abnormality.

ExpansibilityThe PIC and LPU modules of the LPU are isolated from each other and can be replacedindividually.

3.7.4 Panel

The combination LPU is classified into types of boards. The following takes the description ofthe 2*OC-192c/STM-64c POS-XFP + 2*10GBase WAN-XFP interface LPU as an example.



138

Figure 3-49 shows the panel appearance of the 2*OC-192c/STM-64c POS-XFP+2*10GBaseWAN-XFP optical interface LPU.

Figure 3-49 Panel appearance of the 2-port OC-192c/STM-64c POS-XFP+2-port 10GBaseWAN-XFP optical interface LPU

Buttons and Indicators on the Panel

Table 3-113 lists the buttons and indicators on the panel of the combination LPU.

Table 3-113 Indicators on the panel of the combination LPU



OFL indicator(Red)

If the indicator is on, you can draw the board out.


If the indicator blinks once every 2s (0.5 Hz), the LPU is in the normalstate.If the indicator blinks twice every 1s (2 Hz), the LPU is in thealarm state.

LINK/ACTindicator (Green)

If the indicator is on, the link is Up.If the indicator is blinking, the datais being read or written.If the indicator is off, the link is Down.



139

Interface

The 2-port 10GBase LAN-XFP+4-port OC-48c/STM-16c POS-SFP optical interface LPU hastwo 10G LAN Ethernet interfaces and four 2.5G POS interfaces. The 10G LAN interface usesthe pluggable XFP optical module, the 2.5G POS interface uses the pluggable SFP opticalmodule. You can select the optical module of different transmission distances as required. It hastwo cards. The number of the upper card is 0 and its ports are numbered from 0 to 1. The numberof the lower card is 1 and its ports are numbered from 0 to 3.

The 2-port 10GBase WAN-XFP+4-port OC-48c/STM-16c POS-SFP optical interface LPU hastwo 10G WAN Ethernet interfaces and four 2.5G POS interfaces. The 10G WAN interface usesthe pluggable XFP optical module, the 2.5G POS interface uses the pluggable SFP opticalmodule. You can select the optical module of different transmission distances as required. It hastwo cards. The number of the upper card is 0 and its ports are numbered from 0 to 1. The numberof the lower card is 1 and its ports are numbered from 0 to 3.

The 2-port OC-192c/STM-64c POS-XFP+4-port OC-48c/STM-16c POS-SFP optical interfaceLPU has two 10G POS interfaces and four 2.5G POS interfaces. The 10G POS interface usesthe pluggable XFP optical module. The 2.5G POS interface uses the pluggable SFP opticalmodule. You can select the optical module of different transmission distances as required. It hastwo cards. The number of the upper card is 0 and its ports are numbered from 0 to 1. The numberof the lower card is 1 and its ports are numbered from 0 to 3.

The 2-port OC-192c/STM-64c POS-XFP+10-port 1000Base-X-SFP optical interface LPU hastwo 10G POS interfaces and ten 1G Ethernet interfaces. The 10G POS interface uses thepluggable XFP optical module, the 1G Ethernet interface uses the pluggable SFP optical module.You can select the optical module of different transmission distances as required. It has twocards. The number of the upper card is 0 and its ports are numbered from 0 to 1. The number ofthe lower card is 1 and its ports are numbered from 0 to 9.

The 2-port OC-192c/STM-64c POS-XFP+2-port 10GBase LAN-XFP optical interface LPU hastwo 10G POS interfaces and two 10G LAN Ethernet interfaces. The 10G POS interface uses thepluggable XFP optical module, the 10G LAN Ethernet interface uses the pluggable XFP opticalmodule. You can select the optical module of different transmission distances as required. It hastwo cards. The number of the upper card is 0 and its ports are numbered from 0 to 1. The numberof the lower card is 1 and its ports are numbered from 0 to 1.

The 2-port OC-192c/STM-64c POS-XFP+2-port 10GBase WAN-XFP optical interface LPUhas two 10G POS interfaces and two 10G WAN Ethernet interfaces. The 10G POS interfaceuses the pluggable XFP optical module, the 10G LAN Ethernet interface uses the pluggable XFPoptical module. You can select the optical module of different transmission distances as required.It has two cards. The number of the upper card is 0 and its ports are numbered from 0 to 1. Thenumber of the lower card is 1 and its ports are numbered from 0 to 1.

The 4-port OC-48c/STM-16c POS-SFP+10-port 1000Base-X-SFP optical interface LPU hasfour 2.5G POS interfaces and ten 1G Ethernet interfaces. The 2.5G POS interface uses thepluggable SFP optical module, the 1G Ethernet interface uses the pluggable SFP optical module.You can select the optical module of different transmission distances as required. It has twocards. The number of the upper card is 0 and its ports are numbered from 0 to 3. The number ofthe lower card is 1 and its ports are numbered from 0 to 9.

3.7.5 Interface Attributes

Attributes of the 1000Base-X-SFP interface are shown in Table 3-114.



140

Table 3-114 Interface attributes of the 1000Base-X-SFP



Optical interfaceattribute

Determined by the SFP optical module. For the selectable opticalmodule, refer to Table 3-115.

Duplex mode Full-duplex

Standardcompliance

IEEE 802.3z

Frame format Ethernet_II, Ethernet_SAP and Ethernet_SNAP

Network protocol IP




70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50 mi)

70 km(43.50mi)

Centerwavelength

1470nm

1490nm

1510nm

1530nm

1550nm

1570nm

1590nm

1610nm



0 dBm



5 dBm


-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

Overloadpower


0 dBm

Optical fibertype

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Attributes of the 10GBase LAN/WAN interfaces are shown in Table 3-116.



141

Table 3-116 Interface attributes of the 10GBase LAN/WAN-XFP



Interface attributes Compliant with the selected XFP optical module. For the attributesof XFP modules, see Table 3-117.


Compliant standard IEEE 802.3z


Network protocol IP




0.3 km (0.19mi)

10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype


Attributes of the OC-192c/STM-64c POS-XFP interfaces are shown in Table 3-118.

Table 3-118 Interface attributes of the OC-192c/STM-64c POS-XFP





142



Determined by the selected XFP optical module. (For the selectableoptical module, refer to Table 3-117.)


Standard compliance Conforms to the STM-64c SDH/OC-192c SONET standard andsupports RFC 2615(1619)/1662


Network protocol IP

Attributes of the OC-48c/STM-16c POS-SFP interface are shown in Table 3-119.

Table 3-119 Interface attributes of the OC-48c/STM-16c POS-SFP




Determined by the selected SFP optical module. For the selectableoptical module, refer to Table 3-120.


Standard compliance Conforms to the STM-16c SDH/OC-48c SONET standard andsupports IETF RFC 1619/1661/1662/2615


Network protocol IP

Table 3-120 Attributes of the 2.5G SFP optical module



2 km (1.24 mi) 15 km (9.32 mi) 40 km (24.86mi)

80 km (49.71 mi)

Centerwavelength

1310 nm 1310 nm 1310 nm 1550 nm


-10.0 dBm -5.0 dBm -2.0 dBm -2.0 dBm





143



-21.0 dBm -21.0 dBm -30.0 dBm -30.0 dBm

Overloadpower

-3.0 dBm 0 dBm -9.0 dBm -9.0 dBm

Optical fibertype

Single-mode Single-mode Single-mode Single-mode

3.7.6 Technical Specifications

Table 3-121 shows the technical specifications of the combination LPU.

Table 3-121 Technical specifications of the combination LPU

Item Specifications

Power consumption 2×10G POS+4×2.5G POS: 302W2×10G POS+10×GE: 268W2×10G POS+2×10G LAN: 309W2×10G POS+2×10G WAN: 328W4×2.5G POS+10×GE: 248W2×10G LAN+4×2.5G POS: 285W2×10G WAN+4×2.5G POS: 308W

Heat dissipation 2×10G POS+4×2.5G POS: 981 BTU/hour2×10G POS+10×GE: 870 BTU/hour2×10G POS+2×10G LAN: 1003 BTU/hour2×10G POS+2×10G WAN: 1064 BTU/hour4×2.5G POS+10×GE: 805 BTU/hour2×10G LAN+4×2.5G POS: 925 BTU/hour2×10G WAN+4×2.5G POS: 999 BTU/hour

Dimensions (widthx depth x height)





144

4 Cables

About This Chapter

This chapter describes the structure and specifications of the external cables.

4.1 DC-Input Power CableThis section describes the structure and technical specifications of the DC-input power cable.

4.2 AC-input Power CableThis section describes the structure and technical specifications of the AC-input power cable.

4.3 Chassis and Cabinet Grounding CableThis section describes the structure and technical specifications of the chassis and cabinetgrounding cable.

4.4 Console Port CableThis section describes the structure and technical specifications of the Console port cable.

4.5 Auxiliary Port CableThis section describes the structure and technical specifications of the auxiliary port cable.

4.6 Clock CableThis section describes the structure and technical specifications of the clock cable.

4.7 Ethernet CableThis section describes the structure and technical specifications of the Ethernet cable.

4.8 CXP FiberThe is section describes the structure and technical specifications of CXP fiber optics.

4.9 Optical FiberThis section describes the structure and technical specifications of the optical fiber.

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description 4 Cables


145

4.1 DC-Input Power CableThis section describes the structure and technical specifications of the DC-input power cable.

4.1.1 8000W DC-Input Power CableThis section describes the structure and technical specifications of the DC-input power cable.

CAUTIONIf the distance of power supply is more than 35 m (114.83 ft.), it requires the user to set PowerDistribution Frame (PDF) as near as possible. For cables see Power Distance Less Than 25 m(82.02 ft.).

Deliver different cables according to the surveyed power supply distance between the router andthe power distribution.

Power Distance Less Than 25 m (82.02 ft.)If the power distance is less than 25 m (82.02 ft.), use the power cables of 25mm^2 (0.039in.^2)to connect the power cabinet to the power supply, as shown in Table 4-1.

Table 4-1 Cables for Power Distance Less than 25 m (82.02 ft.)

Item Description

Terminal Naked Crimping Terminal,OT,25mm^2,M6,Tin Plating,Width LessThan 12.4mm,For OEM

Naked Crimping Terminal,OT,25mm^2,M8,Tin Plating, Naked RingTerminal

Cable type Wire,450/750V,227 IEC 02(RV)25mm^2,blue,110A

Wire,450/750V,227 IEC 02(RV)25mm^2,black,110A

Power Distance More than 25 m (82.02 ft.) but Less than 35 m (114.83 ft.)If the power distance is more than 25 m (82.02 ft.) but less than 35 m (114.83 ft.), use the powercables of 35mm^2 (0.054in.^2) to connect the power cabinet to the power supply, as shown inTable 4-2.



146

Table 4-2 Cables for Power Distance More than 25 m (82.02 ft.) but Less than 35 m (114.83ft.)

Item Description

Terminal Naked Crimping Terminal,OT,35mm^2,M6,Tin Plating,Naked RingTerminal

Naked Crimping Terminal,OT,35mm^2,M8,Tin Plating,Naked RingTerminal

Cable type Wire,450/750V,227 IEC 02(RV)35mm^2,Blue,135A


4.2 AC-input Power CableThis section describes the structure and technical specifications of the AC-input power cable.

4.2.1 8000W AC-input Power CableThis section describes the structure and technical specifications of the AC-input power cable.

Table 4-3 Length for NE5000E chassis and power module

Length in the Site Survey Configurations of external cables andterminals

Length equal to or less than 4 m (13.12 ft.) Wire,450/750V,227 IEC 02(RV)25mm^2,blue


Naked Crimping Terminal,OT,25mm^2,M6,Tin Plating, Width Less Than12.4mm,For OEM

Naked CrimpingConnector,JG2,25mm^2,M6,150A,TinPlating,For OEM

Length greater than 4 m (13.12 ft.) The DC chassis is better placed close to theAC power module.If implementation faces difficulties, theconfiguration of power cables between theDC chassis and the AC power module canfollow the principle for external power cablesfor the DC power supply solution.



147

Table 4-4 Length for connecting the AC power module with the AC PDF

Length in the Site Survey Configurations of external cables andterminals

Length equal to or less than 20 m (65.62 ft.) Power Cable,300/500V,227IEC10(BVV),6mm^2,Black Jacket(Cores: Blue,Brown),43A,2 Equivalent Cores

Naked Crimping Terminal,OT,6mm^2,M6,Tin Plating, Insulated RingTerminal,12~10AWG,yellow

Naked Crimping Terminal,OT,6mm^2,M8,Tin Plating, Insulated RingTerminal,12~10AWG,yellow

Length greater than 20 m (65.62 ft.) Cables for connecting the nearest PDF or thefirst power cabinet to the device

4.3 Chassis and Cabinet Grounding CableThis section describes the structure and technical specifications of the chassis and cabinetgrounding cable.

4.3.1 Introduction

The chassis and cabinet grounding cable connect the chassis and cabinet to the ground. Ensurethat the grounding cables in the front, back and side doors of the cabinet are correctly connectedbefore delivery.

4.3.2 Structure

The grounding cable connector of the chassis and cabinet is the same as that of the DC-inputpower cable.


The technical specifications of the chassis and cabinet grounding cable are shown in Table4-5.

Table 4-5 Technical specifications of the chassis and cabinet grounding cable

Item Description

PGND cable Terminal Naked Crimping Terminal,OT,25mm^2,M6,TinPlating,Width Less Than 12.4mm,For OEM

Naked Crimping Terminal,OT,25mm^2,M8,Tin Plating,Naked Ring Terminal



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Item Description

Naked Crimping Connector,JG2,25mm^2,M6,150A,TinPlating,For OEM

Cable type Power cable-450V/750V-227 IEC 02(RV)-25mm^2-olivine-110A.

Fireproof class CM.

4.4 Console Port CableThis section describes the structure and technical specifications of the Console port cable.

4.4.1 Introduction

The Console cable is used to connect the NE5000E Console port to the serial port of the Consoledevice to transmit configuration data of the device.

The Console cable is an 8-core shielded cable. One end of the cable uses the RJ45 connectorthat is connected to the Console port of the MPU. The other end has two connectors with DB9female and DB25 female, respectively, and is connected to the serial port of the computer. Youcan choose one of them to plug into the computer serial port as required.

4.4.2 Structure

The Console cable is shown in Figure 4-1 and the pin assignments are shown in Table 4-6.

Figure 4-1 Console cable

1. A direction 2. DB25 Female 3. Label 4. Network port connector RJ455. B direction 6. C direction 7. DB9 Female W1 and W2 communication cable



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Table 4-6 Pin assignments of the Console cable

RJ45 Direction DB25 DB9 Signal

1 -> 5 8 CTS (Clear to Send)

2 -> 6 6 DSR (Data Set Ready)

3 -> 3 2 RXD (Receive Data)

4 - 7 5 GND

5 - 8 1 GND

6 <- 2 3 TXD (Transmit Data)

7 <- 20 4 DTR (Data Terminal Ready)

8 <- 4 7 RTS (Request to Send)


Table 4-7 shows the technical specifications of the Console port cable.

Table 4-7 Technical specifications of the Console port cable

Item Description

Connector X1 Network interface connector-crystal connector -8PIN-8bit-shielded plug.

Connector X2 Cable connector-D style-25PIN-female.

Connector X3 Cable connector-D style-9PIN-female.

Cable type (1) the symmetrical twisted cable-120-ohm-SEYVPV-0.5mm-24AWG-8core-PANTONE 430U(2) the symmetricaltwisted cable-100-ohm-SEYVP-0.48mm-26AWG-8core-black.

Number ofcores

8.

Fireproof class CM.

Availablelength

15 m (49.21 ft.) for 120-ohm cable ,3 m (9.84 ft.) for 100-ohm cable.

4.5 Auxiliary Port CableThis section describes the structure and technical specifications of the auxiliary port cable.

4.5.1 Introduction



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The AUX port cable is used to connect the NE5000E auxiliary (AUX) port to the modem forremote transmission of configuration data.

The AUX port cable is an 8-core shielded cable. One end uses the RJ45 connector that isconnected to the AUX port of the MPU. The other end has two connectors with DB9 female andDB25 female, respectively, and is connected to the computer serial port. You can choose one ofthem to plug into the computer serial port as required.

4.5.2 Structure

The structure of the AUX cable is the same as that of the Console cable as shown in Figure4-2. Table 4-8 shows the pin assignments.

Figure 4-2 The structure of the AUX cable

1. A direction 2. DB25 Female 3. Label 4. Network port connector RJ455. B direction 6. C direction 7. DB9 Female W1 and W2 communication cable

Table 4-8 Pin assignments of the AUX cable

RJ-45 Direction DB-25 DB-9 Signal

1 -> 4 7 RTS

2 -> 20 4 DTR

3 -> 2 3 TXD

4 - 8 1 GND

5 - 7 5 GND

6 <- 3 2 RXD

7 <- 6 6 DSR

8 <- 5 8 CTS



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Table 4-9 shows the technical specifications of the AUX port cable.

Table 4-9 Technical specifications of the AUX port cable

Item Description

Connector X1 Network interface connector-crystal connector-8PIN-8bit-shielded plug.

Connector X2 Cable connector-D type-25PIN-female.

Connector X3 Cable connector-D type-9PIN-female.

Cable type The symmetrical twisted cable-120-ohm-SEYVPV-0.5mm-24AWG-8core-PANTONE 430U.The symmetrical twisted cable-100-ohm-SEYVP-0.48mm-26AWG-8core-black.

Number of cores 8.

Fireproof class CM.

Availablelength

15 m (49.21 ft.) for 120-ohm cable,3 m (9.84 ft.) for 100-ohm cable.

4.6 Clock CableThis section describes the structure and technical specifications of the clock cable.

4.6.1 Introduction

The common SRU/MPU

The clock cable is used to connect the NE5000E with the clock interface of the externalequipment. With the cable, the NE5000E can receive two channels of 2.048 MHz or 2.048 Mbit/s synchronous clocks provided by the upstream device. It can also offer two channels of 2.048MHz or 2.048 Mbit/s synchronous clock signals to the downstream device.

One end of the clock cable uses the SMB connector that is connected to the clock interface onthe MPU and the other end is connected to the external clock equipment.

The clock cable has two types:

l 75-ohm clock cablel 120-ohm clock cable

The SRU/MPU that supports the 1588v2 protocol

The clock cable is used to connect the NE5000E with the clock interface of the externalequipment. With the cable, the NE5000E can receive 2 Mbit/s clock signals,2 MHz clocksignals,clock signals of combining 1 PPS and ASCII,clock signals of combining 1 PPS and



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RS232,two channels of DCLS clock signals.It can also offer 2 Mbit/s clock signals,2 MHz clocksignals,clock signals of combining 1 PPS and ASCII,clock signals of combining 1 PPS andRS232,two channels of DCLS clock signals.

One end of the clock cable uses the SMB/RJ45 connector that is connected to the clock interfaceon the SRU/MPU and the other end is connected to the external clock equipment.

SMB connector is used along with the 75ohm Coaxial cable. RJ45 connector is used along withthe 120ohm relay cable.

NOTEThe wire sequence of the relay cable used as a clock cable is different from that used as a common Ethernetcable.

4.6.2 Structure

75-ohm Clock CableFigure 4-3 shows the structure of the 75-ohm clock cable.

Figure 4-3 75-ohm clock cable

1. Coaxial connector-SMB 2. Label

NOTE

l The NE5000E provides only the 75-ohm clock. If you need the 120-ohm clock, use a transfer cableshown in Figure 4-4 and Figure 4-5. Choose the one-channel or two-channel architecture as required.

l One section of the coaxial cable for clock transfer is 200 mm (7.87 in.) long, which is unchangeableand ensures the transfer connector is installed inside or near the equipment.

One-channel Clock Transfer CableFigure 4-4 shows the one-channel clock transfer cable.

Figure 4-4 One-channel clock transfer cable

1. Coaxial connector-SMB-75 ohm-straight/plug-female 2. Main label3. 75-ohm/120-ohm transfer PCB



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Two-channel Clock Transfer Cable

Figure 4-5 shows the two-channel clock transfer cable.

Figure 4-5 Two-channel clock transfer cable

1. Coaxial connector-SMB-75-ohm-straight/plug-female 2. Label1:"1#" 3. Main label4. 75-ohm/120-ohm transit PCB 5. Label3:"1#" 6. Label 4:"2#"7. Label 2:"2#"

Table 4-10 shows the pin assignments of the two-channel clock transfer cable.

Table 4-10 Pin assignments of the two-channel clock transfer cable

Connector 75-ohm Cable Color 120-ohm Cable

X1 Pin line Blue W3

Shielded layer White

X2 Pin line Blue W4

Shielded layer White

120-ohm relay cable

Figure 4-6 shows the 120-ohm relay cable adopts the RJ-45 connector and the cable structure.

Figure 4-6 Structure of 120-ohm relay cable

The pin assignments of the 120-ohm relay cable are shown in Table 4-11.



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Table 4-11 Pin assignments of the 120-ohm relay cable

Connector X1 Connector X2 Relationship

X1.5 X2.2 Pair

X1.4 X2.1

X1.2 X2.5 Pair

X1.1 X2.4

X1.3 X2.7 Pair

X1.6 X2.8

X1.7 X2.3 Pair

X1.8 X2.6


Table 4-12 shows the technical specifications of the 75-ohm clock cable.

Table 4-12 Technical specifications of the 75-ohm clock cable

Item Description

Connector Coaxial connector-SMB plug-75 ohm inline female

Cable Type Coaxial cable-75ohm-3.9mm-2.1mm-0.34mm-shield

Diameter of theprotection layer-Diameter of the internalinsulation-Diameter ofthe internal conductor

3.9mm-2.1mm-0.34mm

Available length 10 m (32.81 ft.), 15 m (49.21 ft.), 20 m (65.62 ft.) and30 m (98.42 ft.)

Table 4-13 shows the technical specifications of the one-channel 75 ohm transfer 120 ohm clockcable.

Table 4-13 Technical specifications of the one-channel clock transfer cable

Item Description

Connector Coaxial connector-SMB plug-75 ohm inline female



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Item Description

75-ohmcable

Type Coaxial cable-75ohm-3.9mm-2.1mm-0.34mm-shield


3.9mm-2.1mm-0.34mm

120-ohmcable

Type Symmetrical twisted cable -120ohm-SEYPVPV-0.4mm-26AWG-2 pairs-Pantone 430U

Diameter of the internalconductor

0.4mm/26AWG

Available length 30 m (98.42 ft.)

Table 4-14 shows the technical specifications of the two-channel 75 ohm transfer 120 ohm clocktransfer cable.

Table 4-14 Technical specifications of the two-channel clock transfer cable

Item Description

X1/X2 connector Coaxial connector-SMB plug-75 ohm inline female

75-ohmcable

Type Coaxial cable-75ohm-3.9mm-2.1mm-0.34mm-shield


3.9mm-2.1mm-0.34mm

120-ohmcable

Type Symmetrical twisted cable -120ohm-SEYPVPV-0.4mm-26AWG-2 pairs-Pantone 430U

Diameter of the internalconductor

0.4mm/26AWG

Available length 30 m (98.42 ft.)

Table 4-15 shows the technical specifications of the 120-ohm relay cable.

Table 4-15 Technical specifications of the 120-ohm relay cable

Item Description

120-ohmcable

Connector Network interface connector-8 PIN-8 bit-shielded-crystal modelplug



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Item Description

Type Cable,120ohm,1E1,0.4mm,MP8-II,120CC4P0.4P430U(S),MP8-II,Expert 2.0

Length 3 m (9.84 ft.), 15 m (49.21 ft.), 30 m (98.42 ft.), 60 m (196.85ft.) and 80 m(262.46 ft.)

4.7 Ethernet CableThis section describes the structure and technical specifications of the Ethernet cable.

4.7.1 Introduction

Ethernet cable is of two types: the straight-through cable and the crossover cable.

Straight-through Cable

The straight-through cable is used to connect the Ethernet interfaces between the followingdevices:

l router and concentrator

l router and Ethernet switch

l Computer and Ethernet switch

l Computer and concentrator

Crossover Cable

The crossover Cable is used to connect the Ethernet interfaces between the following devices:

l router and router

l router and computer

l Concentrator and concentrator

l Concentrator and switch

l Switch and switch

l Computer and computer

4.7.2 Structure

As shown in Figure 4-7, the straight-through cable and the crossover cable are standard shieldednetwork cables and adopt the RJ45 connector. Figure 4-8 shows the structure of the RJ45.



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Figure 4-7 Network cable

1. Connector - RJ45 2. Label 1 3. Main label 4. Label 2

Figure 4-8 Connetor RJ45

Table 4-16 and Table 4-17 show the pin assignments of the straight-through cable and thecrossover cable respectively.

Table 4-16 Pin assignments of the straight-through cable

Connector X1 Connector X2 Color Relationship

X1.2 X2.2 Orange Twisted pair

X1.1 X2.1 White/Orange

X1.6 X2.6 Green Twisted pair

X1.3 X2.3 White/Green

X1.4 X2.4 Blue Twisted pair

X1.5 X2.5 White/Blue

X1.8 X2.8 Brown Twisted pair

X1.7 X2.7 White/Brown



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Table 4-17 Pin assignments of the crossover cable

Connector X1 Connector X2 Color Relationship

X1.6 X2.2 Orange Twisted pair

X1.3 X2.1 White/Orange

X1.2 X2.6 Green Twisted pair

X1.1 X2.3 White/Green

X1.4 X2.4 Blue Twisted pair

X1.5 X2.5 White/Blue

X1.8 X2.8 Brown Twisted pair

X1.7 X2.7 White/Brown


The technical specifications of the straight-through cable and crossover cable are shown in Table4-18 and Table 4-19 respectively.

Table 4-18 Technical specifications of the straight-through cable

Item Description

Connector X1/X2 Network port connector-crystal connector-8PIN-8bit-shield-plug-24-26AWG-CAT 6/SFTP network cable

Cable type Communication cable-100±15ohm-shielded enhanced 5 types-CAT5ESFTP 24AWG-8 core PANTONE 445U

Number of cores 8

Fireproof class CM

Available length 5 m (16.40 ft.), 10 m (32.81 ft.), 20 m (65.62 ft.) and 30 m (98.42 ft.)

Table 4-19 Technical specifications of the crossover cable

Item Description

Connector X1/X2 Network port connector-crystal connector-8PIN-8bit-shield-plug-24~26AWG-CAT 6/SFTP network cable

Cable type Communication cable-100±15ohm-shielded enhanced 5 types-CAT5ESFTP 24AWG-8 core PANTONE 646U

Number of cores 8



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Item Description

Fireproof class CM

Available length 5 m (16.40 ft.) and 30 m (98.42 ft.)

4.8 CXP FiberThe is section describes the structure and technical specifications of CXP fiber optics.

4.8.1 Overview of CXP Fiber Optics

CXP fiber optics are used to connect different chassis in the NE5000E-X16 cluster.

4.8.2 Structure

Figure 4-9 shows the appearance of a CXP fiber optic.

Figure 4-9 CXP fiber optic appearance

Figure 4-10 and Figure 4-11 show the diagram of an 84-pin connector used by a CXP fiberoptic.



160

Figure 4-10 84-pin connector used by a CXP fiber optics



161

Figure 4-11 84-pin connector used by a CXP fiber optics


Table 4-20 lists technical specifications of a CXP fiber optic.

Table 4-20 Technical specifications of a CXP fiber optic

Item Description Unit Remarks

Module form CXP - -

Number oflanes

12 Tx and 12 Rx - -

Maximumdata rate

126 Gb/s -

Maximumdata rate perlane

10.5 Gb/s -



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Item Description Unit Remarks

Standardcable lengths

3(9.84), 5(16.40), 10(32.81), 20(65.62), 30(98.42), 50(164.04),and 100(328.08)

m(ft.) Other lengths may beavailable upon request,up to 300 meters(984.24 ft.).

Supportedprotocol

Typical applicationsinclude Infiniband,Fibre Channel, 100GEthernet, SATA/SAS3

- -

Electricalinterface andpin-out

84-pin connector - Pin-out as defined inthe CXP Specificationby the IBTA

Standard fiberoptic type

Multi-mode ribbonfiber cable assembly,riser-rated

- -

Maximumpowerconsumptionper end

3.5 W -

Managementinterface

Serial, I2C-based, 450kHz maximumfrequency

- As defined by the CXPSpecification

4.9 Optical FiberThis section describes the structure and technical specifications of the optical fiber.

4.9.1 Introduction

Table 4-21 shows the types of fibers that the NE5000E uses.

Table 4-21 Types of optical fibers

No. Cable and Use Local Connector Remote Connector Cable Mode

1 Fiber connectingthe local interfaceboard to the ODF

LC/PC FC/PC Single-mode

2 Fiber connectingthe local interfaceboards

LC/PC LC/PC or SC/PC Single-mode /multi-mode



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No. Cable and Use Local Connector Remote Connector Cable Mode

3 Fiber connectingthe local interfaceboard to the otherequipment

LC/PC LC/PC or SC/PC Single-mode /multi-mode

CAUTIONThe optical transmission module of the multi-transverse mode needs to be connected to the multi-mode fiber. The optical transmitting module of the single-longitudinal mode or multi-longitudinal mode needs to be connected to the single-mode fiber.

4.9.2 Structure

The NE5000E uses the following types of optical connectors:

l LC/PC optical connectorl SC/PC optical connectorl FC/PC optical connector

The outlines and operations of the connectors and the precautions that you should take whenplugging and unplugging the connectors are described in the following sections.

LC/PC Optical ConnectorFigure 4-12 shows the outline of the LC/PC optical connector.

Figure 4-12 LC/PC optical connector

The plugging/unplugging of LC/PC optical interface only needs an axial operation instead of arotation.

The operation procedures and precautions are as follows:



164

l Cautiously align the head of the fiber jumper with the optical interface on the optical boardand push in the fiber with proper strength.

l Press the clip before pulling it out. Push in the fiber connector inward slightly, and thenpull out the connector.

SC/PC Optical ConnectorFigure 4-13 shows the outline of the SC/PC optical connector.

Figure 4-13 SC/PC optical connector

FC/PC Optical ConnectorFigure 4-14 shows the outline of the FC/PC optical connector.

Figure 4-14 FC/PC optical connector


Table 4-22 shows the technical specifications of the optical fiber.

Table 4-22 Technical specifications of the optical fiber

Item Description

Fiber transmission mode Single-mode/Multi-mode



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Item Description

Fiber connector 1 LC/PC and SC/PC

Fiber connector 2 LC/PC, SC/PC and FC/PC

Fiber outer diameter 2 mm (0.08 in.)



166

A Appendix A List of Indicators

This chapter presents the list of indicators.

A.1 Indicators of NE5000EThis chapter presents the indicators of NE5000E.

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description A Appendix A List of Indicators


167

A.1 Indicators of NE5000EThis chapter presents the indicators of NE5000E.

A.1.1 Fan Module Indicators

The indicators of the fan module are on the LCD plastic panel. Table A-1 shows the status anddescription of the indicators.

Table A-1 Indicators of the fan module


RUN indicator Green If the indicator blinks (1Hz), the FAN and FCB worknormally.

ALM indicator Red If the indicator is on, the FAN or FCB works abnormally.

A.1.2 Power Module Indicators

The indicators of the power module are on the plastic panel of the power supply. Table A-2shows the status and meaning of the indicators of the DC-input power module.

Table A-2 Indicators of the DC-input power module


POWER1 Green Indicates normal power input and output of part1. If the indicatoris on, it indicates normal input and output of part1.

Red Indicates abnormal power input or output of part1. If the indicatoris on, it indicates abnormal input and output of part1.





Table A-3 shows the status and meaning of the indicators of the AC-input power module.



168

Table A-3 Indicators of the AC-input power module

Condition Power Supply Led State MonitoringSignals(ReferencedTo Com)

AC OK(Green)

DC OK(Green)

Service(Amber)

Fault(Red)

Fault ModulePresent

OK 1 1 0 0 LO LO

Thermal Alarm (5Cbefore shutdown)

1 1 1 0 HI LO

Thermal Shutdown 1 0 1 1 HI LO

Defective Fan (Nocontrol or I2C)

1 1 0/Blinks 1 HI LO

Input High-VoltagePulse

1 0 0 1 HI LO

NO AC >15mS(single pulse)

0 1 0 0 HI LO

AC Present But NotWithin Limits

Blinks Indefinitely 0 0 HI LO

AC Not Present 0 0 0 0

Boost Stage Failure 1 Indefinitely 0 1 HI LO

Over VoltageLatched Shutdown

1 0 0 1 HI LO

Over Current 1 Blinks 0 0 HI LO

Non-catastrophicInternal Failure (notemp)

1 1 0 1 HI LO

I2C ServiceRequest

1 1 Blinks 0 HI LO

A.1.3 MPU Indicators

Table A-4 lists the status and descriptions of MPU indicators.



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Table A-4 MPU indicators


OFL indicator Red If the indicator is on, you can remove a board.

RUN indicator Green Before the MPU is powered on and registers, the indicatorstatus is changed in the sequence of off-blinks quickly (4Hz)-off-steady on-blinks slowly (0.5 Hz).After the MPU is powered on and registers: If the indicatorblinks at 0.5 Hz, the system is working properly.NOTE



l The MPU cannot be powered on.

The possible reasons why the indicator blinks quickly are listedbelow:

l The CF card is faulty.

l The other control chips on the MPU are faulty, causing theMPU not to be able to initialize.

ALM indicator Red If the indicator is on, the system is in the alarm state. If theindicator is off, the system is in the normal state.

ACT indicator Green If the indicator is on, the MPU is in the active state. If theindicator is off, the MPU is in the standby state.

CF read-writeindicator

Green If the indicator is on, it indicates that the CF is in position.If the indicator is blinking, it indicates that data is beingread or written.If the indicator is off, it indicates that the CF is not inposition or can be removed.NOTE

When the indicator is blinking, do not remove the CF card.

LINK indicator (onthe Ethernetinterface)

Green If the indicator is off, the link is Down. If the indicator ison, the link is Up.

LINK indicator (onthe Ethernetinterface)

Yellow If the indicator is off, no data is being read or written. If theindicator is blinking, data is being read or written.

A.1.4 SFU Indicators

Table A-5 lists the status and descriptions of SFU indicators.



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Table A-5 SFU indicators


OFL indicator Red If the indicator is on, you can remove a board.

RUN indicator Green Before the SFU is powered on and registers, the indicatorstatus is changed in the sequence of off – blinks quickly (4Hz) – off – steady on – blinks slowly (0.5 Hz).After the SFU is powered on and registers: If the indicatorblinks at 0.5 Hz, the system is working properly.NOTE



l The SFU cannot be powered on.

The possible reasons why the indicator blinks quickly are listedbelow:



ACT Indicator Green If the indicator is on, the SFU is in the normal state. If theindicator is off, the SFU is in the abnormal state.

A.1.5 SFEB Indicators

Table A-6 lists the buttons and indicators on the panel of the SFEB.

Table A-6 Components on the SFEB panel


OFL button It is an OFL button. Before removing a board, press the OFL button. Holdthe button for six seconds until the OFL indicator turns on. Then, the boardcan be removed.

OFL indicator(red)

If the indicator is on, you can remove the board.



171



Before the SFEB is powered on and registers, the indicator status ischanged in the sequence of off – blinks quickly (4 Hz) – off – steady on –blinks slowly (0.5 Hz).After the SFEB is powered on and registers: If the indicator blinks at 0.5Hz, the system is working properly.NOTE



l The SFEB cannot be powered on.




CXP insertionindicator

If the indicator blinks in green, the optical module runs properly. If theindicator is constantly on in green or the indicator is off, the optical modulebecomes faulty.

CXP interface In a back-to-back system: connects the SFEBs on the master and slavechassis.In a cluster: connects SFEBs on CLCs to Optical Flexible Cards(OFC100Bs) on CCCs.

A.1.6 LPU Indicators

Table A-7 lists the status and descriptions of LPU indicators.

Table A-7 LPU indicators


OFL indicator Red If the indicator is on, you can remove the board.

RUN indicator Green l If the indicator blinks once every 2s (0.5 Hz), the LPUis in the normal state.

l Otherwise, it indicates that the board fails to runnormally.

Link/ACTindicator

Green l If the indicator is off, the link is Down.l If the indicator is on, the link is Up.l If the indicator is blinking, data is being receive or

transmit.



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B Appendix B List of Boards

This chapter presents the list of boards.

B.1 Boards

B.2 Power Consumption and Weight

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description B Appendix B List of Boards


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B.1 Boards

Table B-1 lists the Basic Configuration of the NE5000E. Table B-2 shows the LPUs supportedby the NE5000E.

Table B-1 Basic Configuration of the NE5000E

ProductName

BoardName forOrder

Full Name

NE5000ECLC

CR52K-BKPC-36U-8KW

NE5000E Integrated Chassis Components

CR52-MPUB

Main Processing Unit

CR5DSFEBA06B

SFEB

CCC CR55C-BKPA

NE5000E Cluster Chassis

CR5D0MPUA450

Main Processing Unit A

CR5DSFUIA050

Cluster 100G Central Switch Fabric Unit

CR55C-ICUA

Cluster Internal Communication Unit A

CR5DECUFA050

Cluster 100G Electric Cross Unit

CR5M0OFCA060

100Gbps Cluster Optical Flexible Card

Table B-2 LPUs and the corresponding FPICs

Order Name Name

CR5MLPUFA060 Flexible Card Line Processing Unit(LPUF100,4 subslots)

CR5M00E5XX60 5-Port 10GBase LAN-XFP Flexible Card

CR5M00L5XX60 5-Port 10GBase LAN/WAN-XFP Flexible Card

CR5M00E2XX60 2-Port 10GBase LAN-XFP Flexible Card

CR5M00L2XX60 2-Port 10GBase LAN/WAN-XFP Flexible Card



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Order Name Name

CR5M00P2XX60 2-Port OC-192c/STM-64c POS/OTU2-XFP Flexible Card

CR5M00P1MZ60 1-port OC-768c/STM-256c POS-LC Flexible Card

CR5M00EFGF60 24-port 1000Base-X-SFP Flexible Card

CR5D00E1NC60 1-Port 100GBase-CFP Integrated Line Process Unit

CR52K-10x1000Base-X-SFP

10-Port 1000Base-X-SFP Line Processing Unit

CR52K-20x1000Base-X-SFP

20-Port 1000Base-X-SFP Line Processing Unit

CR52K-1x10GBase-LAN-XFP

1-Port 10GBase LAN-XFP Line Processing Unit

CR52K-1x10GBase-WAN-XFP

1-Port 10GBase WAN-XFP Line Processing Unit









CR52E2XP4UM 2-Port 10GBase LAN-XFP and 4-Port OC-48c/STM-16c POS-SFP Line Processing Unit

CR52W2XP4UM 2-Port 10GBase WAN-XFP and 4-Port OC-48c/STM-16c POS-SFP Line Processing Unit

CR52P4UEAGM 4-Port OC-48c/STM-16c POS-SFP and 10-Port 1000Base-X-SFPLine Processing Unit

CR52P2XP4UM 2-Port OC-192c/STM-64c POS-XFP and 4-Port OC-48c/STM-16cPOS-SFP Line Processing Unit

CR52P2XEAGM 2-Port OC-192c/STM-64c POS-XFP and 10-Port 1000Base-X-SFP Line Processing Unit

CR52P2XE2XM 2-Port OC-192c/STM-64c POS-XFP and 2-Port 10GBase LAN-XFP Line Processing Unit

CR52P2XW2XM 2-Port OC-192c/STM-64c POS-XFP and 2-Port 10GBase WAN-XFP Line Processing Unit

CR52K-8xPOS/STM1-SFP

8-Port OC-3c/STM-1c POS-SFP Line Processing Unit



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Order Name Name















CR52K-1xPOS/STM64-XFP

1-Port OC-192c/STM-64c POS-XFP Line Processing Unit





B.2 Power Consumption and Weight

Table B-3 shows the nominal weight and power consumption of the boards.

Table B-3 Power consumption and weight of the boards

Board Name Powerconsumption(Typicalvalue)

HeatDissipation

Weight

Main Processing Unit 70 W 227 BTU/hour

3.84 kg (8.47lb)

Switch Fabric Extended Unit B 200 W 649 BTU/hour

5.55 kg(12.24 lb)

Flexible Card Line Processing Unit(LPUF–100,4 sub-slots)

278 W 902 BTU/hour

8 kg (17.64lb)



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HeatDissipation

Weight

5-Port 10GBase LAN-XFP Flexible Card 50.3 W 163 BTU/hour

0.9 kg (1.98lb)

5-Port 10GBase LAN/WAN-XFP FlexibleCard

50.3 W 163 BTU/hour

0.9 kg (1.98lb)

2-Port 10GBase LAN-XFP Flexible Card 28.13 W 91 BTU/hour

0.49 kg (1.08lb)

2-Port 10GBase LAN/WAN-XFP FlexibleCard

28.13 W 91 BTU/hour

0.49 kg (1.08lb)

2-Port OC-192c/STM-64c POS-XFPFlexible Card

28.13 W 91 BTU/hour

0.49 kg (1.08lb)

1-port OC-768c/STM-256c POS-LCFlexible Card

37 W 120 BTU/hour

0.75 kg (1.65lb)

24-port 1000Base-X-SFP Flexible Card 42 W 136 BTU/hour

0.9 kg (1.98lb)

1-port 100GBase-CFP Integrated LineProcess Unit(LPUI-100)

333 W 1080 BTU/hour

9.6 kg (21.17lb)

10-Port 1000Base-X-SFP Line ProcessingUnit

139 W 451BTU/hour

6 kg (13.23lb)

20-Port 1000Base-X-SFP Line ProcessingUnit

240 W 779 BTU/hour

6 kg (13.23lb)

1-Port 10GBase LAN-XFP Line ProcessingUnit

139 W 451 BTU/hour

6 kg (13.23lb)

1-Port 10GBase WAN-XFP LineProcessing Unit

140 W 454 BTU/hour

6 kg (13.23lb)


166 W 539 BTU/hour

6 kg (13.23lb)


172 W 558 BTU/hour

6 kg (13.23lb)


280 W 908 BTU/hour

6 kg (13.23lb)


278 W 902 BTU/hour

6 kg (13.23lb)

2-Port OC-192c/STM-64c POS-XFP and 4-Port OC-48c/STM-16c POS-SFP LineProcessing Unit

302W 981 BTU/hour

6.35 kg(14.00 lb)



177


HeatDissipation

Weight

2-Port OC-192c/STM-64c POS-XFP and 10-Port 1000Base-X-SFP Line Processing Unit

289W 939 BTU/hour

6.35 kg(14.00 lb)

2-Port OC-192c/STM-64c POS-XFP and 2-Port 10GBase LAN-XFP Line ProcessingUnit

309W 1003 BTU/hour

6.35 kg(14.00 lb)

2-Port OC-192c/STM-64c POS-XFP and 2-Port 10GBase WAN-XFP Line ProcessingUnit

328W 1064 BTU/hour

6.35 kg(14.00 lb)

2-Port 10GBase LAN-XFP and 4-PortOC-48c/STM-16c POS-SFP Line ProcessingUnit

285W 925 BTU/hour

6.35 kg(14.00 lb)

2-Port 10GBase WAN-XFP and 4-PortOC-48c/STM-16c POS-SFP Line ProcessingUnit

308W 999 BTU/hour

6.35 kg(14.00 lb)

4-Port OC-48c/STM-16c POS-SFP and 10-Port 1000Base-X-SFP Line Processing Unit

267W 867 BTU/hour

6.35 kg(14.00 lb)

1-Port OC-48c/STM-16c POS-SFP LineProcessing Unit

141 W 457 BTU/hour

6 kg (13.23lb)


136 W 441 BTU/hour

6 kg (13.23lb)


145 W 470 BTU/hour

6 kg (13.23lb)


245 W 795 BTU/hour

6 kg (13.23lb)

1-Port OC-192c/STM-64c POS-XFP LineProcessing Unit

149 W 483 BTU/hour

6 kg (13.23lb)


246 W 798 BTU/hour

6 kg (13.23lb)


310 W 1006 BTU/hour

6 kg (13.23lb)



178

C Appendix C List of LPU InterfaceAttributes

This chapter presents the list of LPU Interface Attributes.

C.1 Interface Attributes of 1000Base-X-SFP

C.2 Interface Attributes of 10GBase LAN/WAN-XFP


C.4 Interface Attributes of OC-48c/STM-16c POS-SFP

C.5 Interface Attributes of OC-192c/STM-64c POS-XFP

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description C Appendix C List of LPU Interface Attributes


179

C.1 Interface Attributes of 1000Base-X-SFP

Table C-1 lists the interface attributes of 1000Base-X-SFP.

Table C-1 Interface attributes of the 1000Base-X-SFP



Interface attributes Compliant with the selected SFP optical module. (For the attributesof SFP modules, see Table C-2 and Table C-3.)



Network protocol IP

Table C-2 Attributes of 1000M SFP optical modules



0.55 km(0.34 mi)

10 km(6.21 mi)(6.21 mi)

40 km(24.86mi)

40 km(24.86mi)

80 km(49.71mi)

100 km(62.14mi)

Center wavelength 850 nm 1310 nm 1310 nm 1550 nm 1550nm

1550 nm



0 dBm


-2.5 dBm -3.0 dBm 3.0 dBm 1.0 dBm 5.0dBm

5.0 dBm


-17.0dBm

-20.0dBm

-22.5dBm

-21.0dBm

-23.0dBm

-30.0dBm


-9.0 dBm


Single-mode

Single-mode

Single-mode

Single-mode

Single-mode



180

Table C-3 Attributes of 1000M colorized optical modules



70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50mi)

70 km(43.50 mi)

70 km(43.50mi)

Centerwavelength

1470nm

1490nm

1510nm

1530nm

1550nm

1570nm

1590nm

1610nm



0 dBm



5 dBm


-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

-23.0dBm

Overloadpower


0 dBm

Optical fibertype

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode

Single-mode


The interface attributes of 10GBase WAN-XFP see Table C-4.

Table C-4 Interface attributes of the 10GBase WAN-XFP



Interface attributes Compliant with the selected XFP optical module. (For the attributesof XFP modules, see Table C-5.)



Network protocol IP



181

Table C-5 Attributes of 10G XFP optical modules



0.3 km (0.19 mi) 10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71mi)

Centerwavelength

850 nm 1310 nm 1550 nm 1550 nm


-7.3 dBm -6.0 dBm -1.0 dBm 0 dBm


-1.3 dBm -1.0 dBm 2.0 dBm 4.0 dBm


-7.5 dBm -11.0 dBm -15.0 dBm -24.0 dBm

Overloadpower

-1.0 dBm 0.5 dBm -1.0 dBm -7.0 dBm

Optical fibertype



The interface attributes of 10GBase WAN-XFP see Table C-6.

Table C-6 Interface attributes of the 10GBase WAN-XFP


Connector type SC/LC

Interface attributes Compliant with the selected CFP optical module. (For the attributesof CFP modules, see Table C-7.)



Network protocol IP



Transmission distance 10 km (6.21 mi) 40 km (24.86 mi)



182


Center wavelength 1310 nm 1550 nm

Minimum transmittingpower

-4.3 dBm -4.3 dBm

Maximum transmittingpower

4.5 dBm 4.5 dBm

Receiving sensitivity -8.6 dBm -8.6 dBm

Overload power 4.5 dBm 4.5 dBm

Optical fiber type Single-mode Single-mode

C.4 Interface Attributes of OC-48c/STM-16c POS-SFP

Table C-8 lists the interface attributes of OC-48c/STM-16c POS-SFP.

Table C-8 Interface attributes of the OC-48c/STM-16c POS-SFP



Interface attributes Compliant with the selected SFP optical module. (For the attributesof SFP modules, see Table C-9.)



Network protocol IP

Table C-9 Attributes of 2.5G SFP optical modules



2 km (1.24 mi) 15 km (9.32 mi) 40 km (24.86mi)

80 km (49.71 mi)

Centerwavelength

1310 nm 1310 nm 1310 nm 1550 nm


-10.0 dBm -5.0 dBm -2.0 dBm -2.0 dBm





183



-21.0 dBm -21.0 dBm -30.0 dBm -30.0 dBm

Overloadpower

-3.0 dBm 0 dBm -9.0 dBm -9.0 dBm

Optical fibertype


C.5 Interface Attributes of OC-192c/STM-64c POS-XFPTable C-10 lists the interface attributes of OC-192c/STM-64c POS-XFP.

Table C-10 Interface attributes of the OC-192c/STM-64c POS-XFP



Interface attributes Compliant with the selected XFP optical module. (For the attributesof XFP modules, see Table C-11.)



Network protocol IP




10 km (6.21 mi) 40 km (24.86 mi) 80 km (49.71 mi)


Minimumtransmitting power

-6.0 dBm -1.0 dBm 0 dBm

Maximumtransmitting power

-1.0 dBm 2.0 dBm 4.0 dBm


-11.0 dBm -15.0 dBm -24.0 dBm





184

The 10G XFP multi-mode optical transceiver supports two types of multi-mode optical fiberswith different cores. Table C-12 lists the relationship between the core, the modal/bandwidth,and the transmission distance. During configuration, the length of optical fibers is restricted bythe transmission distance. In addition, the optical fiber with the 50-um core and 2000-MHz*kmmodal/bandwidth is a special type. If this type of optical fibers are required, you need to purchaseit additionally.

Table C-12 The transmission distance of 10G XFP optical modules



50 2000 2~300 (1.24~186.42)

50 500 2~82 (1.24~50.95)

62.5 200 2~33 (1.24~17.82)



185

D Appendix D transceiver

This chapter presents the optical module.

D.1 Instructions on How to Use an Optical Module

D.2 1 Gbit/s Electrical Transceiver

D.3 1.25 Gbit/s GBIC Optical Module

D.4 1.25 Gbit/s SFP/eSFP Optical Module

D.5 2.5 Gbit/s eSFP Optical Module

D.6 10 Gbit/s XFP Optical Module

D.7 100Gbps CFP Optical Modules

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description D Appendix D transceiver


186

D.1 Instructions on How to Use an Optical Module

Precautions for the loosened optical modulel 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 maybecome Up. On the condition that the optical module tremors or collides with anotherobject, however, the optical module will be loosened or the optical signals will betemporarily cut off.

l When inserting the optical module, make sure that the tab is closed. (At this time, the latchboss locks the optical module.) After the optical module is inserted, try pulling it out to seeif it is installed in position. If the optical module cannot be pulled out, it is secured.

The tab is closed The tab is open

Precautions for receptacle contaminationl Clean tissues must be prepared for the deployment on site. You need to clean the optical

connector before inserting it in the receptacle. This protects the receptacle against thecontamination on the end surface of the optical connector.

NOTEUse at least three cleaning tissues. Wipe the end of an optical connector horizontally in one direction, andthen move the connector end to the unused part of the cleaning tissue to continue. Generally, one cleaningtissue can be used once for cleaning an optical connector.

l To prevent contamination, the optical module should be covered with either a dust cap oran optical connector.Cover an optical module with a dust cap



187

Cover an optical module with an optical connector

l Lay the optical fibers on the Optical-fiber Distribution Frame (ODF) or coil them up in afiber management tray. Make sure that the optical fibers are not squeezed.

l If a receptacle or an optical connector has not been used for a long time and not coveredwith a dust cap, you should clean it before using it. A cotton swab is used to clean areceptacle, and a cleaning tissue is used to clean an optical connector.

NOTEDuring the cleaning process, insert the cotton swab and turn it slowly in the receptacle. Do not use toomuch strength, because the receptacle may be damaged.



188

l If optical signals are lost during the operation of a device, use the preceding method toclean the receptacle or the optical connector. In this manner, the possibility of contaminationcan be excluded.

Precautions for the overload-caused burnt optical modulel 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 moduleis probably burnt.

l When performing a self-loop test, use an optical attenuator. Do not loosen the opticalconnector instead.

l It is required that a long-distance optical module input optical power smaller than –7 dBm.If the input optical power is larger than –7 dBm, you need to add an optical attenuator. Forexample, if the transmiting optical power is X dBm and the optical attenuation is Y dB, thereceiving optical power is X-Y, which must be smaller than –7dBm (X-Y<–7 dBm).

Other precautionsl The optical connector should be horizontally inserted in the receptacle to avoid damages

to the receptacle.

l Mixed use of multi-mode and single-mode optical fibers is prohibited. Otherwise, faultssuch as signal loss may occur.

D.2 1 Gbit/s Electrical Transceiver

The 1 Gbit/s electrical transceiver can be applied to the GE electrical interfaces. At present, thereare two types of electrical transceivers, namely, GBIC/RJ45 and SFP/RJ45.

Table D-1 lists the currently available 1 Gbit/s electrical transceivers.



189

Table D-1 1 Gbit/s electrical transceivers

ProductModel

BOMNumber

InterfaceStandard

TransmissionDistance

Mode Auto-negotiation

Remarks

GBIC/RJ45-GE-100m

34100044 1000BASE-T

100 m(328.08ft.)

RJ-45 Notsupported

-

SFP/RJ45-GE-100m

34100052 1000BASE-T

100 m(328.08ft.)

RJ-45 Supported -

SFP/RJ45-GE-100m

34100080 1000BASE-T

100 m(328.08ft.)

RJ-45 Supported -

Table D-2 Basic features of 1 Gbit/s electrical transceivers and the compliant standards

Item Description Remarks

Interface standard IEEE Std 802.3z, IEEE Std802.3abGBIC R5.5(34100044)SFP MSA(34100052,34100080)

-

Temperature 0-75°C (32°F to 167°F) -

Digital diagnosis N/A -

Environment standard RoHS(exempted) -

Security standard FCC class B, IEC 61000-4-3 -

ESD >500V Human body model

Table D-3 Specifications of 1 Gbit/s Electrical Transceivers

Parameter Unit Value Remarks

Interface standard - 1000BASE-T -

Transmission rate Mbit/s 10-1000 Complying withIEEE802.3

Interface type - RJ-45


m(ft.) 100 (328.08) Category 5 UTP,BER < 10-10, (GBIC/RJ45-GE-100)



190

Parameter Unit Value Remarks

Category 5 UTP,BER < 10-12, (SFP/RJ45-GE-100)

D.3 1.25 Gbit/s GBIC Optical Module

The 1.25 Gbit/s GBIC optical modules of different levels can be applied to the GE interface .The wavelength of these 1.25 Gbit/s GBIC optical modules can be 850 nm, 1310 nm, or 1550nm and the transmission distance ranges from 0.5 km to 100 km (0.31 mi to 62.14 mi).

Table D-4 lists the currently available 1.25 Gbit/s GBIC optical modules.

Table D-4 1.25 Gbit/s GBIC optical modules

ProductModel

BOMNumber

InterfaceStandard

TransmissionDistance(km)(mi)

Mode Wavelength (nm)

Remarks

GBIC-GE-MM850-500m

34060041 1000BASE-SX

0.5 (0.31) Multimode

850 -

GBIC-GE-SM1310-10Km

34060037 1000BASE-LX

10 (6.21) Single-mode

1310 -

GBIC-GE-SM1310-40Km

34060042 1000BASE-LX


1310 Whenperforming a self-loop test,use anopticalattenuator

GBIC-GE-SM1550-60Km

34060070 1000BASE-ZX





191

ProductModel

BOMNumber

InterfaceStandard



Remarks

GBIC-GE-SM1550-80Km

34060044 1000BASE-ZX



GBIC-GE-SM1550-100Km

34060205 1000BASE-ZX

100(62.14)

Single-mode


Table D-5 Basic features of 1.25 Gbit/s GBIC optical modules and the compliant standards


Interface standard IEEE802.3, GBIC R5.4 -

Bit Error Ratio (BER) < 1 x 10E -12 -

Temperature -5°C to +70°C (23°F to 158°F)

-

Digital diagnosis N/A -


Security standard FCC class B, IEC 60825-1Class 1

-


Table D-6 Specifications of the GBIC-GE-MM850-500 Optical Module

Parameter Unit Value

Interface standard - 1000BASE-SX

Transmission rate Mbit/s 1.25 G

Interface type - SC



192


Transmission distance m(ft.) 500(1640.4) (50/125 umMMF)

m(ft.) 220(721.78) (62.5/125 umMMF)

Optical transmitter

Optical source type VCSEL

Center wavelength nm 850

Operating wavelength range nm 830-860

Spectral characteristics

Maximum root mean square(RMS) Spectral Width

nm 0.85

Maximum spectral width(-20dB)

nm N/A

Minimum side modesuppression ratio (SMSR)

dB N/A

Average transmit optical power

Maximum transmit opticalpower

dBm -4

Minimum transmit opticalpower

dBm -9.5

Minimum extinction ratio dB 9.0

Optical receiver


Minimum receiversensitivity

dBm -17

Overload power dBm 0

Maximum optical channelcost

dB N/A

Maximum reflection factor dB -14

Table D-7 Specifications of the GBIC-GE-SM1310-10K optical module


Interface standard - 1000BASE-LX



193



Interface type - SC

Transmission distance km(mi) 10(6.21)

Optical transmitter

Optical source type FP-LD





nm 4


nm N/A


dB N/A



dBm -3


dBm -9

Minimum extinction ratio dB 9

Optical receiver



dBm -19

Overload power dBm -3


dB N/A

Maximum reflection factor dB N/A






194



Interface type - SC


Optical transmitter

Optical source type DFB-LD





nm 1.0


nm N/A


dB 30



dBm 1


dBm -4


Optical receiver



dBm -23



dB N/A




Interface standard - 1000BASE-ZX



195



Interface type - SC


Optical transmitter






nm 1.0


nm N/A


dB N/A



dBm 3


dBm -2


Optical receiver



dBm -23



dB N/A







196



Interface type - SC


Optical transmitter






nm 1.0


nm N/A


dB 30



dBm 4


dBm 0


Optical receiver



dBm -24



dB N/A


D.4 1.25 Gbit/s SFP/eSFP Optical Module

The 1.25 Gbit/s SFP/eSFP optical modules of different levels can be applied to the GE interface .The wavelength of the common 1.25 Gbit/s SFP/eSFP optical modules can be 850 nm, 1310nm, or 1550 nm and the transmission distance ranges from 0.5 km to 100 km (0.31 mi to 62.14



197

mi). The wavelength of the 1.25 Gbit/s SFP/eSFP CWDM optical module ranges from 1470 nmto 1610 nm and the transmission distance is 70 km (43.50 mi) (43.50 mi).

Table D-11 lists the currently available 1.25 Gbit/s SFP/eSFP optical modules.

Table D-11 1.25 Gbit/s SFP/eSFP optical modules

ProductModel

BOMNumber

InterfaceStandard



Remarks

eSFP-GE-MM850-500m

34060286 1000BASE-SX


850 Preferred

SFP-GE-MM850-500m

34060049 1000BASE-SX


850 -

eSFP-GE-SM1310-10Km

34060219 1000BASE-LX


1310 -

eSFP-GE-SM1310-10Km

34060473 1000BASE-LX


1310 Preferred

eSFP-GE-SMTx1310/Rx1490-10km

34060470 1000BASE-LX


Tx1310/Rx1490

-

eSFP-GE-SMTx1490/Rx1310-10km

34060475 1000BASE-LX


Tx1490/Rx1310

-

eSFP-GE-SM1310-40Km

34060298 1000BASE-LX

40(24.86) Single-mode

1310 PreferredWhenperforming a self-loop test,use anopticalattenuator



198

ProductModel

BOMNumber

InterfaceStandard



Remarks

SFP-GE-SM1310-40Km

34060207 1000BASE-LX



SFP-GE-SM1550-40Km

34060069 1000BASE-ZX



eSFP-GE-SM1550-40Km

34060333 1000BASE-ZX



eSFP-GE-SM1550-80Km

34060360 1000BASE-ZX



eSFP-GE-SM1550-80Km

34060274 1000BASE-ZX





199

ProductModel

BOMNumber

InterfaceStandard



Remarks

eSFP-GE-SM1550-100Km

34060295 1000BASE-ZX

100(62.14)

Single-mode


Table D-12 List of 1.25 Gbit/s SFP/eSFP CWDM optical modules

ProductModel

BOMNumber

InterfaceStandard



Remarks

eSFP-GE-SM1470-70Km

34060351 CWDM 70 (43.50) Single-mode

1470 -

eSFP-GE-SM1490-70Km

34060350 CWDM 70 (43.50) Single-mode

1490 -

eSFP-GE-SM1510-70Km

34060315 CWDM 70 (43.50) Single-mode

1510 -

eSFP-GE-SM1530-70Km

34060332 CWDM 70 (43.50) Single-mode

1530 -

eSFP-GE-SM1550-70Km

34060346 CWDM 70 (43.50) Single-mode

1550 -

eSFP-GE-SM1570-70Km

34060347 CWDM 70 (43.50) Single-mode

1570 -

eSFP-GE-SM1590-70Km

34060348 CWDM 70 (43.50) Single-mode

1590 -

eSFP-GE-SM1610-70Km

34060349 CWDM 70 (43.50) Single-mode

1610 -



200

Table D-13 Basic features of 1.25 Gbit/s SFP/eSFP optical modules and the compliant standards


Interface standard IEEE802.3, SFP MSA -

Bit Error Ratio (BER) < 1 x 10E -12 -

Temperature 0°C to +70°C (32°F to 158°F )

-

Digital diagnosis SFF-8472(exclude SFPoptical modules)

-



-


Table D-14 Specifications of the eSFP-GE-MM850-500 optical module


Interface standard - 1000BASE-SX


Interface type - LC

Transmission distance m(ft.) 500(1640.4) (50/125 umMMF)

m(ft.) 200(656.16) (62.5/125 umMMF)

Optical transmitter






nm 0.85


nm N/A


dB N/A




201



dBm -3


dBm -9


Optical receiver



dBm -17

Overload power dBm 0


dB N/A


Table D-15 Specifications of the eSFP-GE-SM1310-10K optical module




Interface type - LC


Optical transmitter

Optical source type FP Laser





nm 4


nm N/A


dB N/A




202



dBm -3


dBm -9


Optical receiver



dBm -20



dB N/A






Interface type - LC


Optical transmitter

Optical source type DFB Laser

Center wavelength nm Tx1310/Rx1490




nm N/A


nm 1


dB 30




203



dBm -3


dBm -9


Optical receiver



dBm -19.5



dB N/A


Table D-17 Specifications of the eSFP-GE-SMTx1490/Rx1310-10K optical module




Interface type - LC


Optical transmitter

Optical source type DFB Laser

Center wavelength nm Tx1490/Rx1310




nm N/A


nm 1


dB 30




204



dBm -3


dBm -9


Optical receiver



dBm -19.5



dB N/A






Interface type - LC


Optical transmitter






nm N/A


nm 1.0


dB 30




205



dBm 0(34060298)

5(34060207)


dBm -4.5(34060298)

0(34060207)


Optical receiver



dBm -22.5



dB N/A






Interface type - LC


Optical transmitter






nm N/A


nm 1.0


dB 30




206



dBm 0


dBm -5


Optical receiver



dBm -21



dB N/A






Interface type - LC


Optical transmitter






nm N/A


nm 1.0


dB 30




207



dBm 3


dBm -2


Optical receiver



dBm -22



dB N/A






Interface type - LC


Optical transmitter






nm N/A


nm 1.0


dB 30




208



dBm 5


dBm 0


Optical receiver



dBm -30



dB N/A


Table D-22 Specifications of the 1.25 Gbit/s CWDM 70 km (43.50 mi) eSFP optical module


Interface standard - CWDM


Interface type - LC


Optical transmitter


Center wavelength nm 1471 (eSFP-GE-SM1470-70K)

1491 (eSFP-GE-SM1490-70K)

1511 (eSFP-GE-SM1510-70K)

1531 (eSFP-GE-SM1530-70K)

1551 (eSFP-GE-SM1550-70K)

1571 (eSFP-GE-SM1570-70K)



209


1591 (eSFP-GE-SM1590-70K)

1611 (eSFP-GE-SM1610-70K)

Operating wavelength range nm 1464.5-1477.5 (eSFP-GE-SM1470-70K)

1484.5-1497.5 (eSFP-GE-SM1490-70K)

1504.5-1517.5 (eSFP-GE-SM1510-70K)

1524.5-1537.5 (eSFP-GE-SM1530-70K)

1544.5-1557.5 (eSFP-GE-SM1550-70K)

1564.5-1577.5 (eSFP-GE-SM1570-70K)

1584.5-1597.5 (eSFP-GE-SM1590-70K)

1604.5-1617.5 (eSFP-GE-SM1610-70K)



nm N/A


nm 1.0


dB 30



dBm 5


dBm 0


Optical receiver



dBm -23



210




dB N/A


D.5 2.5 Gbit/s eSFP Optical Module

The 2.5 Gbit/s eSFP optical modules of different levels can be applied to the STM-16/OC-48POS interface and ATM interface. The wavelength of these 2.5 Gbit/s eSFP optical modules canbe 1310 nm or 1550 nm and the transmission distance ranges from 2 km to 80 km (1.24 mi to49.71 mi).

Table D-23 lists the currently available 2.5 Gbit/s eSFP optical modules.

Table D-23 2.5 Gbit/s eSFP optical modules

ProductModel

BOMNumber

InterfaceStandard



Remarks

eSFP-STM16-SM1310-2Km

34060288 STM-16I-16

2(1.24) Single-mode

1310 -


34060278 STM-16S-16.1


1310 -


34060289 STM-16S-16.1




34060279 STM-16L-16.2





211

ProductModel

BOMNumber

InterfaceStandard



Remarks


34060488 STM-16L-16.2



Table D-24 Basic features of 2.5 Gbit/s eSFP optical modules and the compliant standards


Interface standard ITU-T G.957 STM-16, SFPMSA

-

Bit Error Ratio (BER) < 1 x 10E -12

Temperature 0-70°C (32°F to 158°F ) -

Digital diagnosis SFF-8472(exclude SFPoptical modules)

-



-


Table D-25 Specifications of the eSFP-STM16-SM1310-2K optical module


Interface standard - STM-16 I-16, OC-48


Interface type - LC


Optical transmitter

Optical source type FP Laser




212





nm 4


nm 1


dB 30



dBm -3


dBm -10


Optical receiver



dBm -18



dB 1




Interface standard - STM-16 S-16.1, OC-48


Interface type - LC


Optical transmitter





213





nm NA


nm 1.0


dB 30



dBm 0


dBm -5


Optical receiver



dBm -18



dB 1






Interface type - LC


Optical transmitter





214





nm N/A


nm 1.0


dB 30



dBm 3


dBm -2


Optical receiver



dBm -27



dB 1






Interface type - LC


Optical transmitter





215





nm N/A


nm 1.0


dB 30



dBm 3


dBm -2


Optical receiver



dBm -28



dB N/A


D.6 10 Gbit/s XFP Optical Module

The 10 Gbit/s XFP optical modules of different levels can be applied to the OC-192/STM-64POS interface, ATM interface, and 10 GE interface. The wavelength of the these 10 Gbit/s XFPoptical modules can be 850 nm, 1310 nm, or 1550 nm and the transmission distance ranges from0.3 km to 80 km(0.19 mi to 49.71 mi).

Table D-29 lists the currently available 10 Gbit/s XFP optical modules.



216

Table D-29 10 Gbit/s XFP optical modules

ProductModel

BOMNumber

InterfaceStandard



Remarks

XFP-10G-MM850-300m

34060362 10GBASE-SR/SW

0.3(0.19) Multimode

850 -

XFP-10G-SM1310-10Km

34060313 10GBASE-LR/LWSTM-64/OC-192


1310 -

XFP-10G-SM1550-40Km

34060322 10GBASE-ER/EWSTM-64/OC-192



XFP-10G-SM1550-80Km

34060361 10GBASE-ZR/ZWSTM-64/OC-192



Table D-30 Basic features of 10 Gbit/s XFP optical modules and the compliant standards


Interface standard IEEE802.3ae 10GE, SONETOC-192/SDH STM-64, XFPMSA

XFP-10G-MM850-300 donot support SONET OC-192/SDH STM-64

Bit Error Ratio (BER) < 1 x 10E -12

Temperature 0-70°C(32°F to 158°F ) -

Digital diagnosis XFP MSA INF8077i -


Security standard FCC class B, IEC 60825-1Class 1 laser eye safe

-




217

Table D-31 Specifications of the XFP-10G-MM850-300 optical module


Interface standard - 10GBASE-SR/SW

Transmission rate Mbit/s 10.3125 (10GBASE-SR/SW)

Interface type - LC

Transmission distance m(ft.) 300(984.24) (50/125umMMF, OM3)

m(ft.) 33(108.27) (62.5/125umMMF, OM1)

Optical transmitter






nm 0.45


nm N/A


dB N/A



dBm -1.3


dBm -7.3


Optical receiver



dBm -7.5



dB N/A




218

Table D-32 Specifications of the XFP-10G-SM1310-10K optical module


Interface standard - 10GBASE-LR/LW,STM-64/OC-192

Transmission rate Gbit/s 9.95328 (STM-64/OC-192)

10.3125 (10GBASE-LR/LW)

Interface type - LC


Optical transmitter






nm N/A


nm 1.0


dB 30



dBm -1


dBm -6


Optical receiver



dBm -11

Overload power dBm 0.5


dB 1




219



Interface standard - 10GBASE-ER/EW,STM-64/OC-192


10.3125 (10GBASE-ER/EW)

Interface type - LC


Optical transmitter

Optical source type EML





nm 1.0


nm N/A


dB 30



dBm 2


dBm -1


Optical receiver



dBm -14



dB 2




220



Interface standard - 10GBASE-ER/EW,STM-64/OC-192


10.3125 (10GBASE-ZR/ZW)

Interface type - LC


Optical transmitter

Optical source type EML





nm 1.0


nm N/A


dB 30



dBm 4


dBm 0


Optical receiver



dBm -22



dB 2




221

D.7 100Gbps CFP Optical Modules

Table D-35 lists the available 100-Gbps CFP optical modules.

Table D-35 100-Gbps CFP optical modules

Model BOMNumber

InterfaceStandard



Remarks

CFP-100G-SM-10k

34060570 100GBASE-LR4

10(6.21) Singlemode

1295130013041309

-

Table D-36 Attributes and standards of 100-Gbps CFP optical modules

Attribute and standard Description Remarks

Interface standard 100GBASE-LR4,ITU-T G.959.1 4I1-9D1F

-

Bit error rate (BER) < 1 x 10E –12 -

Operating temperature 0–70°C (32°F to 158°F) -

Digital diagnosis -

Environment standard RoHS (exempted) -

Safety standard FCC class B, IEC 60825-1Class 1 laser eye safe

-

ESD >500V Human Body Model (HBM)

Table D-37 CFP-100G-SM1310-10k optical module specifications

Item Unit Value

Interface standard - 100GBASE-LR4

Transmission rate Mbit/s 103.125

Interface type - SC/LC


Optical transmitter



222

Item Unit Value

Optical source type Semi-cooled EA-DFB


Working wavelength nm 1294.53~1296.591299.02~1301.091303.54~1305.631308.09~1310.19

Spectrum attributes

Maximum root-mean-square(RMS) spectral width

nm 0.45

Maximum spectrum width(-20 dB)

nm N/A

Minimum Side ModeSuppression Ratio (SMSR)

dB 30



dBm 4.5


dBm –4.3


Optical receiver

Working wavelength nm 1294.53~1296.591299.02~1301.091303.54~1305.631308.09~1310.19


dBm –8.6

Overload optical power dBm 4.5

Minimum optical channeloverhead

dB 1.5

Maximum reflectioncoefficient

dB –26



223

E Glossary

A

Asynchronization

Asynchronization does not use the exact data signals timed by the clock.The signals have different frequencies and phases. The asynchronizatioinusually encapsulates the bits into the control flag, which specifies thebeginning and end of the bits.

D

DCE Data Circuit-terminating Equipment is a network device composing theUNI. DCE provides the physical connection to the network, forwards thedata, and provides the clock signals for the DTE.

DRAM Dynamic Random Access Memory. The information stored in the RAMmust be refreshed periodically. When the contents of the DRAM are beingrefreshed, a user cannot access it. Delay can thus occur.

DTE Data terminal equipment is a user device composing the UNI. The DTEaccesses the data network through the DCE equipment (for example,model) and usually uses the clock signals produced by DCE.

F

Flash Flash is a kind of special Erasable Programmable Read Only Memory(EEPROM), which can be completely erased and rewritten one timeinstead of only one byte.

N

NVRAM Nonvolatile Random Access Memory. The data in NVRAM cannot belost when the system is Down.

R

RAM Random Access Memory is a memory that can be lost easily, and readand rewritten by the micro processor.

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description E Glossary


224

ROM Read Only Memory is a memory that cannot be lost easily, and can onlybe read, but not written by the micro processor.

S

SRAM Static Random Access Memory is a type of random access memory. Itscontents can be saved only if the SRAM is provided with the uninterruptedpower supply. Unlike the DRAM, the SRAM does not need to be refreshedrepeatedly.

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description E Glossary


225

F Acronyms and Abbreviations

A

AC Alternating Current

ATM Asynchronous Transfer Mode

AUX Auxiliary (port)

C

CAN Control Area Network

CE1 Channelized E1

CF Compact Flash

CLK Clock Card

CPU Central Processing Unit

CT1 Channelized T1

CTS Clear to Send

D

DC Direct Current

DCE Data Circuit-terminating Equipment

DSR Data Set Ready

DTE Data Terminal Equipments

DTR Data Terminal Ready

E

EMC Electro Magnetic Compatibility

F

HUAWEI NetEngine5000E Core RouterNE5000E Hardware Description F Acronyms and Abbreviations


226

FAD Fabric Adaptor

FC Patch Cord (Connector + Fiber)

FCB Fan Control Board

FPIC Flexible Plug-in Card

G

GND Ground

I

IEC International Electrotechnical Commission

L

LC Lucent Connector

LPU Line Processing Unit

M

MPU Main Processing Unit

N

NEG Negative

NVRAM Non-Volatile Random Access Memory

O

ODF Optical Distribution Frame

OFL Offline

P

PC Personal Computer

PCB Printed Circuit Board

PCS Physical Coding Sublayer

PGND Protection Ground

PMD Physical Medium Dependent

R

RJ45 Registered Jack 45

RTS Request to Send

RXD Receive Data



227

S

SC Square Connector

SDRAM Synchronous Dynamic Random AccessMemory

SFU Switch Fabric Unit

SMB Sub-miniature B

SRU Switch Router Unit

T

TXD Transmit Data

U

UART Universal Asynchronous Receiver/Transmitter

UTP Unshielded Twisted Pair

V

VRP Versatile Routing Platform



228

ne5000e hardware description(v800r002c01_01)

Documents

packet forwarding

insulated

air intake

air exhaust

physical coding

service control

maximum rotational

nm nm db