turn-up and comissioning r32

Alcatel-Lucent 1850Transport Service Switch (TSS-320 and TSS-160) | Release 3.1TURN-UP AND COMMISSIONING GUIDE

P/N 8DG 09019 JAAAJUNE 2009

ISSUE 01

This material is protected by the copyright laws of the United States and other countries. It may not be reproduced, distributed, or altered in any fashion by any entity (either internal or external to Alcatel-Lucent), except in accordance with applicable agreements, contracts, or licensing, without the express written consent of Alcatel-Lucent and the business management owner of the manual.

THIS PRODUCT COMPLIES WITH D.H.H.S. RADIATION PERFORMANCE STANDARDS 21 CFR, 1040.10, FOR A CLASS 1 LASER PRODUCT.

Notice

Every effort was made to ensure that this information product was complete and accurate at the time of printing. However, information is subject to change.

This manual applies to software. Release notes describing revisions to this software may impact operations described in this manual.

This transfer of commodities, technology, or software, if from the United States, is an export in accordance with the U.S. Export Administration Regulations. Diversion contrary to U.S. law is prohibited. The export or re-export (further transfer) of such commodities, technology, software or products made from such technology is prohibited without proper authorization(s) from the U.S. Department of Commerce or other appropriate U.S. government agency(s).

All rights reserved. No part of this manual may be reproduced, translated, stored in a retrieval system, or transmitted or distributed by any means, electronic or mechanical, by photocopying, recording, or otherwise, without the written permission of Alcatel-Lucent. Preparing derivative works or providing instruction based on the material is prohibited unless agreed to in writing by Alcatel-Lucent.

The product specification and/or performance levels contained in this document are for information purposes only and are subject to change without notice. They do not represent any obligation on the part of Alcatel. Such obligations will only be committed to in a written sales agreement signed by Alcatel.

Trademarks

Alcatel, Lucent, Alcatel-Lucent and the Alcatel-Lucent logo are trademarks of Alcatel-Lucent. All other trademarks are the property of their respective owners.

Conformance statement

Interference Information: Part 15 of FCC RulesNOTE: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy. If the equipment is not installed and used in accordance with the guidelines in this document, the equipment may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference, in which case the user will be required to correct the interference at the expense of the user.

Security Statement

In rare instances, unauthorized individuals make connections to the telecommunications network through the use of remote access features. In such an event, applicable tariffs require that the customer pay all network charges for traffic. Alcatel-Lucent cannot be responsible for such charges and will not make any allowance or give any credit for charges that result from unauthorized access.

Limited Warranty

For terms and conditions of sale, contact your Alcatel-Lucent Account Team.

Documentation

Product documentation is available on Alcatel-Lucent Online Support Documentation and Software web site at http://www.alcatel-lucent.com/osds.

To offer comments on this documentation, visit Alcatel-Lucent Online Support Documentation and Software web site at http://www.alcatel-lucent.com/osds and select Online Services Helpdesk.

Developed by Alcatel-Lucent

http://www.alcatel-lucent.com/osds

http://www.alcatel-lucent.com/osds

i i iP/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

Contents

About this document

Purpose ...................................................................................................................................................... xiii

Reason for reissue ..................................................................................................................................... xiii

Intended audience ...................................................................................................................................... xiii

How to use this document ......................................................................................................................... xiii

Safety information ......................................................................................................................................xiv

Conventions used .........................................................................................................................................xv

Related documentation ................................................................................................................................xv

Training ..................................................................................................................................................... xvi

Document support ..................................................................................................................................... xvi

Technical support ...................................................................................................................................... xvi

How to order .............................................................................................................................................. xvi

How to comment ....................................................................................................................................... xvi

Packaging collection and recovery requirements ..................................................................................... xvii

Recycling/take-back/disposal of product ................................................................................................. xvii

1 Introduction

General Rules ............................................................................................................................................ 1-2

2 Initial Turn-Up and Setting

Visual inspection for shelf installation and cabling .................................................................................. 2-2

HW setup ................................................................................................................................................... 2-3

Start up procedure ..................................................................................................................................... 2-4

Equipment Switch-on ................................................................................................................................ 2-5

General system check ................................................................................................................................ 2-7

PC Start-up ................................................................................................................................................ 2-8

Software download at the first installation ................................................................................................ 2-8

NE Start-up ................................................................................................................................................ 2-9

Software Download procedure ................................................................................................................ 2-13

NE Software settings ............................................................................................................................... 2-15

Remote inventory .................................................................................................................................... 2-17

............................................................................................................................................................................................................................................................

Contents

i v P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

3 Test and Measurements

Instruments, Accessories and related documents ...................................................................................... 3-3

Connection points position ....................................................................................................................... 3-5

Local Measures list and operating sequence ........................................................................................... 3-13

Free running frequency check ................................................................................................................. 3-14

Optical STM-1 and STM-4 ports test ..................................................................................................... 3-17

Optical STM-16 and STM-64 ports test ................................................................................................. 3-20

Optical GE and 10GE ports test .............................................................................................................. 3-23

GbE Transport on VC4-xV ..................................................................................................................... 3-26

10GbE Transport on VC4-xV ................................................................................................................. 3-29

Q-Bridge VLAN switching test, tagged frames ...................................................................................... 3-32

Provider Bridge VLAN switching test .................................................................................................... 3-39

CWDM ports tests ................................................................................................................................... 3-46

Local test in Line Terminal configuration in CWDM systems ............................................................... 3-52

Local test in OADM configuration in CWDM systems .......................................................................... 3-55

Link test in CWDM systems ................................................................................................................... 3-57

DWDM ports tests ................................................................................................................................... 3-59

Local test in Line Terminal configuration in DWDM systems ............................................................... 3-63

Local test in OADM configuration in DWDM systems .......................................................................... 3-66

Link test in DWDM systems ................................................................................................................... 3-68

SNCP protection check (line ports) ........................................................................................................ 3-70

Protection test Matrix EPS ...................................................................................................................... 3-72

Synchronism priority and Holdover (if present) ..................................................................................... 3-74

Alarms check (if connected) ................................................................................................................... 3-78

Remote alarms check (if present) ............................................................................................................ 3-81

Rack lamps check .................................................................................................................................... 3-82

Housekeeping controls & alarms check ................................................................................................. 3-83

Fan 19” alarm test ................................................................................................................................... 3-85

Final checks ............................................................................................................................................. 3-86

Point-to-point measures list and operating sequence .............................................................................. 3-87

Rx Optical “line port” power check ........................................................................................................ 3-88

Optical “line port” link margin ............................................................................................................... 3-90

Point-to-point error monitoring check .................................................................................................... 3-92

Contents

vP/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

............................................................................................................................................................................................................................................................

Ring error monitoring check ................................................................................................................... 3-94

4 Connections, Configurations and Characteristics

Bidirectional XC between an STM-4 and STM-64 ports ......................................................................... 4-2

Bidirectional protected XC between an STM-4 and STM-64 ports .......................................................... 4-4

Unprotected Bidirectional XC between a Remote data port (VC4-nV) and an STM-n port .................... 4-6

P2P XC between a local and a remote data port ....................................................................................... 4-8

XC in Provider scenario .......................................................................................................................... 4-11

Procedure to enable and disable the ALS ................................................................................................ 4-17

Procedure to manage a loopback ............................................................................................................. 4-18

SFP and XFP modules ............................................................................................................................. 4-21

CWDM mux/demux ................................................................................................................................ 4-29

DWDM mux/demux ................................................................................................................................ 4-36

EC320 card front view ............................................................................................................................ 4-37

MT320/MT320LO or MT160/MT160LO card front view ..................................................................... 4-38

5 Alcatel-Lucent 1850 TSS-320 and TSS-160 Test Report

Equipment acceptance sheet ...................................................................................................................... 5-2

A Technical support

Technical assistance ................................................................................................................................. A-2

Accessing and navigating the On-Line Customer Support (OLCS) web site .......................................... A-7

Other technical support services ............................................................................................................ A-12

GL Glossary

Acronyms and Abbreviations .................................................................................................................GL-1

IN Index

............................................................................................................................................................................................................................................................

Contents

v i P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

v i iP/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

List of figures

1 Introduction


2-1 Power connector ........................................................................................................................... 2-5

2-2 Connection to LAN port ............................................................................................................... 2-9

2-3 ZIC Craft Terminal - Main window ........................................................................................... 2-12


3-1 Common boards and connection points position for 1850 TSS-320 ........................................... 3-6

3-2 Common cards and connection points position for 1850 TSS-160 .............................................. 3-9

3-3 Free-running frequency check .................................................................................................... 3-15

3-4 STM-1/STM-4 Ports test ............................................................................................................ 3-18

3-5 STM-16/STM-64 Ports test ........................................................................................................ 3-21

3-6 Optical GE and 10GE Ports test ................................................................................................. 3-24

3-7 GbE Transport on VC4-xV test .................................................................................................. 3-27

3-8 10GbE Transport on VC4-xV test .............................................................................................. 3-30

3-9 Q-Bridge VLAN switching test, untagged frames test .............................................................. 3-33

3-10 Bridge configuration .................................................................................................................. 3-33

3-11 Module provisioned type selection ............................................................................................ 3-34

3-12 Port behaviour selection ............................................................................................................. 3-35

3-13 Auto-negotiation enabling .......................................................................................................... 3-35

3-14 Administrative state setting ........................................................................................................ 3-36

3-15 VLAN creation ........................................................................................................................... 3-36

3-16 VLAN assignment ...................................................................................................................... 3-37

3-17 VLAN list ................................................................................................................................... 3-37

3-18 Tagged/untagged selection ......................................................................................................... 3-38

3-19 Provider Bridge VLAN switching test ....................................................................................... 3-40

3-20 Provider Bridge configuration .................................................................................................... 3-40

3-21 Module provisioned type selection ............................................................................................ 3-41

3-22 Port behaviour selection ............................................................................................................. 3-42

3-23 Auto-negotiation enabling .......................................................................................................... 3-42

............................................................................................................................................................................................................................................................

List of figures

v i i i P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

3-24 Administrative state setting ........................................................................................................ 3-43

3-25 VLAN creation ........................................................................................................................... 3-43

3-26 VLAN assignment ..................................................................................................................... 3-44

3-27 VLAN list ................................................................................................................................... 3-44

3-28 Tagged/untagged selection ......................................................................................................... 3-45

3-29 Commissioning example ............................................................................................................ 3-46

3-30 Add&drop configuration *default configuration ....................................................................... 3-48

3-31 Line Terminal configuration in CWDM systems ....................................................................... 3-49

3-32 OADM configuration in CWDM systems ................................................................................. 3-50

3-33 Back-to-back (HUB) configuration in CWDM systems ............................................................ 3-51

3-34 Local test in Line Terminal configuration in CWDM systems .................................................. 3-53

3-35 Local test in OADM configuration in CWDM systems ............................................................. 3-56

3-36 Link Test in CWDM systems ..................................................................................................... 3-57

3-37 End-to-end stability test example in CWDM systems ............................................................... 3-58

3-38 Line Terminal configuration in DWDM systems ....................................................................... 3-60

3-39 OADM configuration in DWDM systems ................................................................................. 3-61

3-40 Back-to-back (HUB) configuration in DWDM systems ............................................................ 3-62

3-41 Local test in Line Terminal configuration in DWDM systems .................................................. 3-64

3-42 Local test in OADM configuration in DWDM systems ............................................................ 3-67

3-43 Link Test in DWDM systems ..................................................................................................... 3-68

3-44 End-to-end stability test example in CWDM systems ............................................................... 3-69

3-45 SNCP protection check .............................................................................................................. 3-70

3-46 Matrix/CRU EPS protection check ............................................................................................ 3-72

3-47 Synchronism priority and holdover ............................................................................................ 3-75

3-48 Alarms check ............................................................................................................................. 3-79

3-49 1850 TSS-320 Back panel electrical connectors location ......................................................... 3-84

3-50 1850 TSS-160 Back panel electrical connectors location ......................................................... 3-84

3-51 Rx Optical “line port” power check ........................................................................................... 3-88

3-52 Optical “line port” link margin .................................................................................................. 3-90

3-53 Point-to-point error monitoring check ....................................................................................... 3-92

3-54 Ring error monitoring check ...................................................................................................... 3-94


4-1 Bidirectional XC between an STM-4 and STM-64 ports ............................................................ 4-2

List of figures

i xP/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

............................................................................................................................................................................................................................................................

4-2 Bidirectional protected XC between an STM-4 and STM-64 ports ............................................ 4-4

4-3 P2P XC between a local and a remote data port .......................................................................... 4-8

4-4 XC in Provider scenario ............................................................................................................. 4-11

4-5 VCG creation - 1 ........................................................................................................................ 4-12

4-6 VCG creation - 2 ........................................................................................................................ 4-12

4-7 VCG creation - 3 ........................................................................................................................ 4-13

4-8 TD selection ............................................................................................................................... 4-14

4-9 XC creation - 1 ........................................................................................................................... 4-14

4-10 XC creation - 2 ........................................................................................................................... 4-15

4-11 XC creation - 3 ........................................................................................................................... 4-16

4-12 EC320 card (Equipment Controller) - front view ...................................................................... 4-37

4-13 MT320/MT320LO or MT160/MT160LO card - front view ...................................................... 4-38


A Technical support

............................................................................................................................................................................................................................................................

List of figures

x P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

x iP/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

List of tables

About this document

1 Introduction



3-1 Instruments ................................................................................................................................... 3-3

3-2 Accessories ................................................................................................................................... 3-3

3-3 EC debugger cable pinout ............................................................................................................ 3-4

3-4 Numbering and functions of common boards Connection Points ............................................... 3-5

3-5 1850 TSS-320 boards position ..................................................................................................... 3-6

3-6 1850 TSS-160 boards position ................................................................................................... 3-10

3-7 Alarms usage for both Channels in Add/Drop Configuration on CWLA3(OP) ........................ 3-48

3-8 Rack alarms (RA) connector pin-out ......................................................................................... 3-81

3-9 Housekeeping connector pin-out ................................................................................................ 3-83


4-1 B&W STM-1 SFPs: optical interfaces characteristics ............................................................... 4-21

4-2 B&W STM-4 SFPs : optical interfaces characteristics .............................................................. 4-22

4-3 B&W STM-16 SFPs : optical interfaces characteristics ............................................................ 4-22

4-4 B&W STM-16 SFPs: long-haul optical interfaces characteristics ............................................. 4-23

4-5 B&W multi-rate multi-format SFP: optical interfaces characteristics ....................................... 4-23

4-6 B&W GE SFPs: optical interfaces characteristics ..................................................................... 4-24

4-7 CWDM multi-rate (2100 to 2700 Mbps) SFPs optical interfaces characteristics ...................... 4-25

4-8 B&W 10G XFPs: optical interfaces characteristics ................................................................... 4-26

4-9 B&W 10G long-haul XFPs: optical interfaces characteristics ................................................... 4-27

4-10 DWDM 10G XFPs: optical interfaces characteristics ................................................................ 4-28

4-11 1-Channel OADM w/o and w/ supervision: CADM1 and CADM1S ........................................ 4-29



4-14 8-Channel MUX/DEMUX w/o and w/ supervision: CMDX8 and CMDX8S ........................... 4-32

............................................................................................................................................................................................................................................................

List of tables

x i i P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

4-15 2-Channel MUX/DEMUX w/ supervision: CMDX2S .............................................................. 4-34

4-16 1-Channel MUX/DEMUX w/ supervision: CMDX1S .............................................................. 4-35

4-17 OMDX8100: 8-channel mux/demux ......................................................................................... 4-36


5-1 Equipment acceptance sheet ........................................................................................................ 5-2

5-2 On-Site 1850 TSS-320 Final Test ................................................................................................ 5-3

5-3 On-Site 1850 TSS-160 Final Test ................................................................................................ 5-4

5-4 On-Site 1850 TSS-320/160 Final Test: SDH Local Measurements ............................................ 5-5

5-5 On-Site 1850 TSS-320/160 Final Test: Data Local Measurements ............................................. 5-6

5-6 On-Site 1850 TSS-320/160 Final Test: CWDM Local Measurements ....................................... 5-7

5-7 On-Site 1850 TSS-320/160 Final Test: CWDM Link Measurements ......................................... 5-8

5-8 On-Site 1850 TSS-320/160 Final Test: DWDM Local Measurements ..................................... 5-10

5-9 On-Site 1850 TSS-320/160 Final Test: DWDM Link Measurements ....................................... 5-11

5-10 On-Site Multiservice Node Final Test: Local Measurements .................................................... 5-12

5-11 On-Site Node Final Test: House keeping (not available in Rel. 3.0) ......................................... 5-12

5-12 On-Site Multiservice Node Final Test: Point-to-Point Measures .............................................. 5-13

A Technical support

xii iP/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

About this document

Purpose

This document provides the information and procedures necessary to test and turn up the Alcatel-Lucent 1850 Transport Service Switch 320 and 160 (Alcatel-Lucent 1850 TSS-320 and TSS-160) system.

Reason for reissue

This document is the first issue of Release 3.1.

History

Intended audience

This installation manual provides information and procedures necessary to test, and turn up the Alcatel-Lucent 1850 TSS-320 and TSS-160 system.

This manual is a service or operations manual. Refer to Transport Service Switch (TSS-320 and TSS-160) User Provisioning Guide, for any activities involving system settings, and Transport Service Switch (TSS-320 and TSS-160) Maintenance and Trouble-Clearing Guide, for trouble analysis.

How to use this document

The current procedure defines the commissioning modality for the 1850 TSS-320/160 equipment.

Particular attention is given to the fact that each component utilized on the links is tested at the Factory's Final Acceptance dept. during the system test phase.

The real conditions of the plant are simulated during this phase, i.e., the line is a real suitably long Optical Fiber line and the equipment is configured according to customer requirements and to the Link Description Table (LDT) supplied by the Link designers.

Issue Date Reason

01 June 2009 First validated issue of this guide

............................................................................................................................................................................................................................................................

About this document

xiv P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

The documentation of the tests carried out during the system test phase is provided with the equipment (TRS+LDT).

All the measurements necessarily executed to correctly insert the equipment into the network are repeated on site. To this concern, reference is made to the results of the factory tests carried out on the system.

Safety information

This information contains hazard statements for your safety. Hazard statements are given at points where risks of damage to personnel, equipment, and operation may exist. Failure to follow the directions in a hazard statement may result in serious consequences.

Safety precautions

Adhere to the following safety precautions:

• Electrostatic discharge (ESD)

You must be properly grounded when making contact with the Alcatel-Lucent 1850 TSS-320 and TSS-160 frame and handling circuit packs, disk drives, and tapes. Wrist strap ground cords should be routinely tested for the minimum 1-megohm resistance.

• Plug-in storage

Circuit packs should be stored in static-safe packaging or in a grounded cabinet.

For additional safety precautions, please see the Transport Service Switch (TSS-320 and TSS-160) Safety Guide (SG), 8DG 09019 FAAA.

Admonishments

To avoid hazardous conditions, observe the following admonishments:

DANGER

Possibility of personal injury.

CAUTION

Possibility of service interruption.

WARNING

Possibility of equipment damage.

About this document

............................................................................................................................................................................................................................................................P/N 8DG 09019 JAAAIssue 01 June 2009

xv

............................................................................................................................................................................................................................................................

Conventions used

Italic typeface denotes a particular product line or information product.

Trebuchet Bold typeface signifies a window, section, command or parameter used with the TL1 Command Builder.

Trebuchet typeface indicates a faceplate or Transport Service Switch (TSS-320 and TSS-160) label designation, as in the ACTIVE LED on a circuit pack.

Courier Bold indicates a text entered in a field by the user

Courier typeface indicates the system or PC response to a command.

For the remainder of this document, “Transport Service Switch (TSS-320 and TSS-160)” is used in place of Alcatel-Lucent 1850 Transport Service Switch 320 and 160 in most cases.

Related documentation

The following list provide additional information about the Transport Service Switch (TSS-320 and TSS-160) Release 3.0:

• 8DG 09019 AAAA — Product Information and Planning Guide. Provides information on Equipment description, composition, features of the equipment, detailed board description, characteristics, hardware settings, and documents common boards used in the different configurations of the product

• 8DG 09019 BAAA— TL1 Commands Guide. Provides comprehensive resource to all Translator Language 1 commands

• 8DG 09019 CAAA — Maintenance and Trouble-Clearing Guide. Provides information on Maintenance and Troubleclearing procedures.

• 8DG 09019 DAAA — TL1 User Provisioning Guide. Provides information on provisioning procedures by means of TL1

• 8DG 09019 EAAA — CLI User Provisioning Guide. Provides a comprehensive resource for all the Command Line Interface commands

• 8DG 09019 FAAA — Safety Guide. Provides information and safety guidelines to safeguard against personal injury and to prevent material damage to the equipment.

• 8DG 09019 GAAA — Engineering Rules. Provides the design constraints for engineering a WDM line system.

• 8DG 09019 HAAA — Installation Guide . Provides information on Equipment Installation.

• 8DG 09019 JAAA — Turn-Up & Commissioning Guide. Provides information on Turn-Up, Tests and Operation procedures. This Guide.

............................................................................................................................................................................................................................................................

About this document

xvi P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

• 8DG 09019 KAAA — User Provisioning Guide. Provides general Craft Terminal information, screens description and user provisioning procedures by means of the ZIC.

• 8DG 09021 AAAA — Documentation CD-ROM. It contains the electronic format of all the above listed documents.

Training

Alcatel-Lucent University provides courses for system planning, engineering, and ordering, as well as courses to train telecommunications technicians in installation, operations, and maintenance. Suitcasing of these courses is also available. Contact Alcatel-Lucent University at 1 (888) 582-3688 to enroll in training classes. To arrange suitcase sessions, call the Product Training Manager at 1 (800) 432-6317 (within USA) or +1 (614) 764-5542 (worldwide). For a list of available courses, see the Alcatel-Lucent University web site at https://training.lucent.com.

Document support

Alcatel-Lucent provides a referral telephone number for document support. Use this number to report errors or to ask questions about the document. This is a non-technical number. The referral number is 1 (888) 727-3615 (continental United States) or +1 (630) 713-5000 (for all countries).

Technical support

For technical support, contact your local Alcatel-Lucent customer support team. See the Alcatel-Lucent Support web site (http://alcatel-lucent.com/support) for contact information. For more information, refer to Refer to Appendix A, “Technical support” for more information.

How to order

To order Alcatel-Lucent documents, contact your local sales representative or use Online Customer Support (OLCS) (https://support.lucent.com).

How to comment

To comment on this information product, go to the Online Comment Form (http://www.lucent-info.com/comments) or email your comments to the Comments Hotline ([email protected]).

http://alcatel-lucent.com/support

http://alcatel-lucent.com/support

https://support.lucent.com


https://training.lucent.com


http://www.lucent-info.com/comments/enus

http://www.lucent-info.com/comments

About this document


xvi i

............................................................................................................................................................................................................................................................

Packaging collection and recovery requirements

Countries, states, localities, or other jurisdictions may require that systems be established for the return and/or collection of packaging waste from the consumer, or other end user, or from the waste stream. Additionally, reuse, recovery, and/or recycling targets for the return and/or collection of the packaging waste may be established.

For more information regarding collection and recovery of packaging and packaging waste within specific jurisdictions, please contact the Alcatel-Lucent Field Services/Installation - Environmental Health and Safety organization.

For installations not performed by Alcatel-Lucent, please contact the Alcatel-Lucent Customer Support Center at:

Technical Support Services, Alcatel-Lucent

• Within the United States: 1 (866) 582-3688, prompt 1

• From all other countries: +1 (630) 224 4672, prompt 2

Recycling/take-back/disposal of product

Electronic products bearing or referencing the symbol shown below, when put on the market within the European Union, shall be collected and treated at the end of their useful life in compliance with applicable European Union and local legislation. They shall not be disposed of as part of unsorted municipal waste. Due to materials that may be contained in the product, such as heavy metals or batteries, the environment and human health may be negatively impacted as a result of inappropriate disposal.

Note: In the European Union, a solid bar under the crossed-out wheeled bin indicates that the product was put on the market after 13 August 2005.

Moreover, in compliance with legal requirements and contractual agreements, where applicable, Alcatel-Lucent will offer to provide for the collection and treatment of Alcatel-Lucent products at the end of their useful life. Alcatel-Lucent will also offer to provide for the collection and treatment of existing products displaced by Alcatel-Lucent equipment.

............................................................................................................................................................................................................................................................

About this document

xvii i P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

For information regarding take-back of equipment by Alcatel-Lucent, or for more information regarding the requirements for recycling/disposal of product, please contact your Alcatel-Lucent Account Manager or Alcatel-Lucent Take-Back Support at [email protected].

1-1P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

1 Introduction

Overview

Purpose

The current procedure defines the commissioning modality for the Transport Service Switch (TSS-320 and TSS-160) equipment.

Safety, labels and norms

Please refer to Transport Service Switch (TSS-320 and TSS-160) Release 3.1 Safety Guide (8DG 09019 FAAA).

Main Safety Rules

The Safety Rules describe the operations and/or precautions to observe to safeguard operating personnel during the working phases and to guarantee equipment safety.

Please read them properly before starting each action on the equipment.

DANGER

Carefully observe the front-panel warning labels prior to working on the optical connections while the equipment is in-service.

............................................................................................................................................................................................................................................................

General RulesIntroduction

1-2 P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

General Rules

Important! All measures could be done at the ODF (OpticalDistribution Frame). or DDF (Digital Distribution Frame). points .In this case a further attenuation, due to the connectors and optcalcords presence, have to be considered in comparison with theexpected nominal value

WARNINGCheck that the equipment is operating with all the shields properly positioned (dummy covers, ESD connector protections, etc.).

DANGERCarefully observe the front-panel warning labels prior to working on optical connections while the equipment is in-service.

WARNINGTo reduce the risk of damaging the electrostatic sensitive devices, it is mandatory to use the elasticized band (worn around the wrist) and the coiled cord connected to the rack ground when having to touch the equipment.

WARNING

FIXING THE BOARDS (AND MODULES) INTO THE SUBRACK.

The screw tightening torque for fixing the boards (and modules, if any and if screw-fastened) into the subrack must be:

• 2.8 kg/cm (0.28 Newton/m) ± 10 %

Exceeding this value may result in screw breaking.


............................................................................................................................................................................................................................................................


Overview

Purpose

The paragraphs that follow list the instructions that must be sequentially executed as well as additional information.

Contents

The chapter contains the following topics:

“Visual inspection for shelf installation and cabling” (p. 2-2)

“HW setup” (p. 2-3)

“Start up procedure” (p. 2-4)

“Equipment Switch-on” (p. 2-5)

“General system check” (p. 2-7)

“PC Start-up” (p. 2-8)

“Software download at the first installation” (p. 2-8)

“NE Start-up” (p. 2-9)

“Software Download procedure” (p. 2-13)

“NE Software settings” (p. 2-15)

“Remote inventory” (p. 2-17)

............................................................................................................................................................................................................................................................

Visual inspection for shelf installation and cablingInitial Turn-Up and Setting


............................................................................................................................................................................................................................................................

Visual inspection for shelf installation and cabling

Check the following before start any procedure.

• Rack allocation: according to station layout.

• Shelf allocation in the rack: according to station layout.

• Shelf configuration (boards installed): according to plant documentation.

• Connections between equipment and DDF/ODF: according to plant documentation.

• Rack and Shelf ground connections (cable section).

• Power Supply connections (polarity and cable section).

• Verify that the system is spotlessly clean, e.g. not dust inside the fans, within the backplane and on the boards.

• Verify that all Dummy Plates are plugged and fixed with theirs screws

HW setupInitial Turn-Up and Setting


2-3

............................................................................................................................................................................................................................................................

HW setup

board setting options are factory pre-set. To check hardware set-up, following malfunction, proceed as instructed in the specific chapter of the Product Information and Planning Guide (8DG 09019 AAAA). (refer to the “Related documentation” (p. 1-xv)).

............................................................................................................................................................................................................................................................

Start up procedureInitial Turn-Up and Setting


............................................................................................................................................................................................................................................................

Start up procedure

Purpose

The scope of this procedure is to describe the start-up phases of the Equipment and the Craft Terminal (ZIC).

Contents

The start up procedure consist in:

• “Equipment Switch-on” (p. 2-5)

– “Voltage polarity test” (p. 2-5)

– “GENTRU Output Voltage for main shelf” (p. 2-5)

– “Equipment Power-on” (p. 2-6)

• “General system check” (p. 2-7)

• “PC Start-up” (p. 2-8)

• “Software download at the first installation” (p. 2-8)

• “NE Start-up” (p. 2-9)

– “Root Password” (p. 2-10)

– “Host address” (p. 2-10)

– “LAN address” (p. 2-10)

– “Site Identification” (p. 2-11)

– “Time Settings” (p. 2-11)

• “Software Download procedure” (p. 2-13)

• “NE Software settings” (p. 2-15)

• “Remote inventory” (p. 2-17)

Equipment Switch-onInitial Turn-Up and Setting


2-5

............................................................................................................................................................................................................................................................

Equipment Switch-on

The Equipment is started up through the two circuit breakers on the Top Rack Unit (when present).

Voltage polarity test

This test has to be done on each rack. The Branch Connectors of the racks are located on top or bottom of the frame.

Important! All Circuit Breakers, Step-up Converters or GENTRUExtension Bypass units have to be in OFF position.

1. Check branch -A and -B against "+" Line with the multi meter:

Input Power Range: -38 Vdc to -72 Vdc

2. Check the voltage of "+" Line against the rack frame.

GENTRU Output Voltage for main shelf

Important! All Step-up Converters have to be in OFF position.

1. Disconnect power cable from the PSFs

2. Turn on the Step-up Converters and check voltage at the power cable plugs.

Figure 2-1 Power connector

– Branch Input < -65 VDC --> Output Power GENTRU > -65 VDC

– Branch Input > -65 VDC --> Output Power GENTRU = Branch Voltage

– Output Power Range GENTRU: -65 VDC to -75 VDC

3. After the voltages have been measured, power off the Step-up Converters and reconnect the power cables

4. Fix the power cable screws

........................................................................................................................................................E N D O F S T E P S

DANGER

Never disconnect and connect power cable under load.

+ BATT.GND- BATT.-BATT.

+ BATT.2345

1

............................................................................................................................................................................................................................................................

Equipment Switch-onInitial Turn-Up and Setting


............................................................................................................................................................................................................................................................

Equipment Power-on1. Switch on all Step-up Converters, GENTRU BYPASS and Circuit Breakers located at

the top of each rack

2. Switch on the equipment by turning on any circuit breaker step by step for related equipment.

3. Switch on the peripheral devices (printer, etc.) connected to the CT

After FLC (EC320) boot-up with empty persistency, the hardware in the system has to be configured via Equipment Provisioning Dialog and CT (refer to the User Provisioning Guide, listed in “Related documentation” (p. 1-xv)).

Before starting the next test or any measurement, allow a warm-up period of the 1850TSS-320/160, for at least 30 min.

........................................................................................................................................................E N D O F S T E P S

General system checkInitial Turn-Up and Setting


2-7

............................................................................................................................................................................................................................................................

General system check

After equipment configuration is done, the 1850TSS-320/160 should be in the following state:

1. The EC320 boards (as FLC) are running in redundant state

2. The MT320/MT320LO or MT160/MT160LO boards (as SLC) are loaded and have state active/passive in these shelves.

3. No alarms "Critical" and "Major" are present in the system.

4. No other unexpected alarms are present in the alarm table list - if this is not the case, fix the problem

5. Check actual running software version is in accordance with customer requirement

Important! Record installed software versions and part numberin the“Equipment acceptance sheet” (p. 5-2).

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

PC Start-upInitial Turn-Up and Setting


............................................................................................................................................................................................................................................................

PC Start-up

Computer hardware configuration

Refer to the Transport Service Switch (TSS-320 and TSS-160) Release 3.0 — User Provisioning Guide, listed in “Related documentation” (p. 1-xv).

Computer software configuration and installation

Refer to the Transport Service Switch (TSS-320 and TSS-160) Release 3.0 — User Provisioning Guide, listed in “Related documentation” (p. 1-xv).

Important! FTP Server program installed and running ismandatory for software download.

Important! In case of a firewall is running on PC, it is required todisable it.

Important! Disable the pop-up blocker, if enabled.

Important! If a secure http is used (https://…), it is required tohave a temporary certification. The customer can get it, followingthe browser indications.

Software download at the first installation

WARNING

The procedure must be carried out by Alcatel-Lucent authorized personnel only.

NE Start-upInitial Turn-Up and Setting


2-9

............................................................................................................................................................................................................................................................

NE Start-up

1. Connect the LAN port of the CT to the CT Interface connector, as shown in Figure 2-2, located on the MT320/MT320LO or MT160/MT160LO board respectively (SLC, plugged in slots 10 and 11).

Figure 2-2 Connection to LAN port

2. Open a browser and enter the IP default address of the TSS-320/160 ZIC Craft Terminal (ZIC) port (e.g. http://10.0.0.1 ENTER). The Authentication dialog box will be displayed on the screen.

To access the NE, the operator has to be logged to the NE. Enter User and Password, then click on Login button.

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

MT320 / MT160Slot 10 or 11

E

M

RS 232 USB ETH

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Root Password

This procedure allows to change the password.

1. Follow the Security User Account Change Password menu path.

The Modify Password Identifier panel will be displayed, where is shown the current User Identifier.

2. In the Old Password ID: field, enter the current password.

3. In the New Password ID: field, enter the desired password.

4. Click on Save.

........................................................................................................................................................E N D O F S T E P S

Host address

It allows to modify the host address.

1. Follow the Xcom DCN Phys If IP Address menu path.

The IP Address Management panel will be displayed.

2. Enter the desired IP address in the IP Address: field.

3. Click on Save.

........................................................................................................................................................E N D O F S T E P S

LAN address

It allows to modify the LAN address.

1. Follow the Xcom DCN Phys If LAN manag. menu path.

The Customer LAN Management panel will be displayed.

2. Enter the desired IP address in the IP address of NE: field, and the Subnet Mask (if any).

In the panel there are some other fields: OSI Protocol (determines if the OSI Protocol will be run on the customer LAN or not), Internet Protocol (determines if the Internet Protocol will be run on the customer LAN or not), OSI Area (it is possible to enter as to which OSI Area the Customer LAN belongs to), Integrated ISIS (determines if the Integrated IS-IS Protocol will be run on the customer LAN or not), Proxy Address Resolution Protocol (determines if it is enabled or not), Channel user by (determines if the customer LAN is not used or if it is used by management plane or by control plane).

3. Click on Save.

........................................................................................................................................................E N D O F S T E P S



2-11

............................................................................................................................................................................................................................................................

Site Identification

It allows to modify the NE name.

1. Follow the System Management DB Management Set Site Identifier menu path.

The Set Site Identifier panel will be displayed.

2. Enter the desired name in the New Site Identifier field.

3. Click on Save.

........................................................................................................................................................E N D O F S T E P S

Time Settings

This procedure allows to set the Time and Network Time Protocol (NTP).

1. Follow the System Management Network Time Protocol menu path.

A window with Time and Date and Network Time Protocol panels will be displayed.

• The Time and Date panel allows to manually set the system date and time by means of six combo-boxes Year, Month, Day, Hour, Minute and Sec.

• The Network Time Protocol panel shows the current values and allows to ENABLE or DISABLE the time synchronization from the NTP server. When the NTP protocol is enabled and no NTP server is in service or reachable, then the time of day clock will keep it's current value and synchronize with the NE internal clock frequency.

2. If you want the time synchronization from the NTP server select the ENABLE option in the NTP Server Synchronization: field.

By means of the New Offset three combo-boxes (+/-, HH and MM) it is possible to apply at the NTP server the UTC (Universal Time Clock) time, for all events and time stamps reported by this NE. Factory default is +00-00.

3. Click on Save.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 2-3 ZIC Craft Terminal - Main window

Software Download procedureInitial Turn-Up and Setting


2-13

............................................................................................................................................................................................................................................................

Software Download procedure

Purpose

This procedure allows to load and install a new SW version.

Prerequisites

The new SW package had been already copied on the server from the upgrading CD-ROM.

Procedure1. Access the main menu of the TSS-320 or TSS-160 CT (ZIC), as described in previous

para. “NE Start-up” (p. 2-9), and proceed as in the following.

2. Follow the System Management DB Management Remote File Perform Copy menu path

The Copy Remote File panel will be displayed.

3. In the From field select the generic software on a remote file server (RFSSW) option by means of the combo-box.

4. In the To field select the standby software generic on the NE (STBYSW) option by means of the combo-box.

The other fields in the panel are relevant to the SW location on an RFS (Remote File Server) to be transferred, i.e.:

– User: the entry box allows to digit the user identifier used for the ftp connection on the RFS.

– Password: the entry box allows to digit the user password used for the ftp connection on the RFS.

– Host: the entry box allows to digit the IP address of the host (the Remote File Server)

– Port: the entry box allows to digit the port number to connect to. Most schemes designate protocols that have a default port number. The default port number for ftp is 21.

– URL Path: the entry box allows to digit the details of how the specified resource (i.e. the directory where the file(s) reside) can be accessed. It has the following syntax: /<server-path>/<swpkg> where:

CAUTION

This procedure could be traffic affecting.

............................................................................................................................................................................................................................................................

Software Download procedureInitial Turn-Up and Setting


............................................................................................................................................................................................................................................................

– <server-path> is the path which identifies the server directories location on FTP server (e.g.: ALCATEL-LUCENT/1850TSS320/3.1/SWPKG) according to the Customer standard

– <swpkg> is the path which identifies the Alcatel-Lucent directories location (i.e.: 1850TSS320-3.xx-xx/1850TSS320M/3_xx_xx.)

– Command Mode: the combo-box allows copying an RFS SW to the secondary backup database on the system. Select the blank option.

– Overwrite: it allows copying the secondary backup database to an RFS SW. Indicates whether existing files should be overwritten. Yes as default value.

5. Click on Apply, to download the new software version

........................................................................................................................................................E N D O F S T E P S

NE Software settingsInitial Turn-Up and Setting


2-15

............................................................................................................................................................................................................................................................

NE Software settings

Purpose

This procedure explains the basics actions can be undertaken in order to preset the equipment configuration.

1. Access the main menu of the TSS-320 or TSS-160 CT (ZIC), as described in previous para. “NE Start-up” (p. 2-9), and proceed as in the following.

2. In the Tree structure of the Main window, located on the left of the screen, refer to Figure 2-3, (pg. 2-12), click on the SLOT to be configured.

Adding a board:1. Select an empty slot (i.e. MDL-x-x-xx)

2. In the client area appears a panel, find the Provisioned Type field and, by means the combo-box, select the desired board. The available boards are summarized in Table 3-5, (pg. 3-6) and Table 3-6, (pg. 3-10).

The Automatic In Service Mode: field allows to choose NOWAIT or AINS (Automatically in service).

3. Click on Save.

The Auto-provisioning procedure allows to add all the cards, plugged in the shelf. This procedure is performed at NE level

4. Select the Network Element in the Tree structure, e.g. NE: xxx.xxx.xxx.xxx

5. Select the board level option

6. In Auto-Provisioning field, select ON option

7. Click on Save

........................................................................................................................................................E N D O F S T E P S

Setting a board out-of-service

1. Select a board (<Mnemonic>-x-x-xx: <Board>) or a XFP/SFP module (<Mnemonic>-x-x-xx-xx: <Module>).

2. In the client area appears a panel, find the Primary state field and, by means the combo-box, select the OOS option.

3. Click on Save.

........................................................................................................................................................E N D O F S T E P S

CAUTION

If the board is carrying traffic, the procedure can’t be executed. Before is necessary to perform “Forcing a board out-of-service” (p. 2-16).

............................................................................................................................................................................................................................................................

NE Software settingsInitial Turn-Up and Setting


............................................................................................................................................................................................................................................................

Forcing a board out-of-service

1. Select a board (<Mnemonic>-x-x-xx: <Board>) or a XFP/SFP module (<Mnemonic>-x-x-xx-xx: <Module>).


3. Find the Command Mode: field and, by means the combo-box, select the FRCD option.

4. Click on Save.

........................................................................................................................................................E N D O F S T E P S

Removing a board

1. Perform the “Setting a board out-of-service” (p. 2-15) or “Forcing a board out-of-service” (p. 2-16)

2. In the client area appears a panel, find the Remove hyperlink at the bottom of the panel.

3. Click on Remove.

........................................................................................................................................................E N D O F S T E P S

Modifying the type of the optical interface type of a board:1. Select a board (<Mnemonic>-x-x-xx: <Board>) or a XFP/SFP module (<Mnemonic>-

x-x-xx-xx: <Module>).


3. Select the optical module in the Tree structure

4. In the client area appears a panel, find the Provisioned Type field and, by means the combo-box, select the desired module. The available modules are summarized in Table 3-5, (pg. 3-6) and Table 3-6, (pg. 3-10).

5. Click on Save

The equipment configuration complies with the boards/modules inserted into the equipment being tested.

........................................................................................................................................................E N D O F S T E P S

CAUTION

Traffic affecting operation.

CAUTION

If the board is carrying traffic, the procedure can’t be executed. Before is necessary to perform “Forcing a board out-of-service” (p. 2-16).

Remote inventoryInitial Turn-Up and Setting


2-17

............................................................................................................................................................................................................................................................

Remote inventory

Purpose

This procedure allows to check the board part number and serial number in order to verify compliance with what specified in the "Plant documentation" and that have to be recorded in Table 5-2, (pg. 5-3) for 1850 TSS-320 or Table 5-3, (pg. 5-4) for 1850 TSS-160 of the “Equipment acceptance sheet” (p. 5-2)".

Procedure for the whole remote inventory1. Select the SHELF-x-x: UNVRSL320 or SHELF-x-x: UNVRSL160 in the Tree structure of

the Main window

2. In the Client area some panels appear (e.g. UP| Rack x > Shelf x)

3. Click on Remote inventory hyperlink and a new window opens, showing the relevant data for all the boards involved in the shelf.

........................................................................................................................................................E N D O F S T E P S

Procedure for a single board remote inventory1. Select a board (<Mnemonic>-x-x-xx: <Board>) in the Tree structure of the Main

window

2. In the Client area some panels appear (e.g. UP| Rack x > Shelf x > Board x)

3. Click on Remote inventory hyperlink and a new window opens, showing the relevant data.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

Remote inventoryInitial Turn-Up and Setting


............................................................................................................................................................................................................................................................


............................................................................................................................................................................................................................................................


Overview

Purpose

The paragraphs that follow list the instructions that must be executed as well as additional information.

Contents


“Instruments, Accessories and related documents” (p. 3-3)

“Connection points position” (p. 3-5)

“Local Measures list and operating sequence” (p. 3-13)

“Free running frequency check” (p. 3-14)

“Optical STM-1 and STM-4 ports test” (p. 3-17)


“Optical GE and 10GE ports test” (p. 3-23)

“GbE Transport on VC4-xV” (p. 3-26)

“10GbE Transport on VC4-xV” (p. 3-29)

“Q-Bridge VLAN switching test, tagged frames” (p. 3-32)

“Provider Bridge VLAN switching test” (p. 3-39)

“Local test in Line Terminal configuration in CWDM systems” (p. 3-52)

“Local test in OADM configuration in CWDM systems” (p. 3-55)

“Link test in CWDM systems” (p. 3-57)

“DWDM ports tests” (p. 3-59)

“Local test in Line Terminal configuration in DWDM systems” (p. 3-63)

............................................................................................................................................................................................................................................................

OverviewTest and Measurements


............................................................................................................................................................................................................................................................

“Local test in OADM configuration in DWDM systems” (p. 3-66)

“Link test in DWDM systems” (p. 3-68)

“SNCP protection check (line ports)” (p. 3-70)

“Protection test Matrix EPS” (p. 3-72)

“Synchronism priority and Holdover (if present)” (p. 3-74)

“Alarms check (if connected)” (p. 3-78)

“Rack lamps check” (p. 3-82)

“Housekeeping controls & alarms check” (p. 3-83)

“Fan 19” alarm test” (p. 3-85)

“Final checks” (p. 3-86)

“Point-to-point measures list and operating sequence” (p. 3-87)

“Rx Optical “line port” power check” (p. 3-88)

“Optical “line port” link margin” (p. 3-90)

“Point-to-point error monitoring check” (p. 3-92)

“Ring error monitoring check” (p. 3-94)

Instruments, Accessories and related documentsTest and Measurements


3-3

............................................................................................................................................................................................................................................................

Instruments, Accessories and related documents

Table 3-1 Instruments

Table 3-2 Accessories

REF. INSTRUMENTS Q.ty CHARACTERISTICS

A Pattern Generator /Error Detector

1 Signals available:

• G.957 compliant STM-1/16 optical• Ethernet 10/100 Mbps• Gb Ethernet, 10 Gb Ethernet

B Optical power meter 1 2nd window; 3rd window

C Single-mode variable optical Attenuator (VOA)

1 Variable attenuator within the 0-50 dB, 2nd and 3rd window

D Digital multi meter 1

E Craft terminal (Personal Computer)

1 Refer to the User Provisioning Guide (see “Related documentation” (p. 1-xv)).

It can be supplied by Alcatel-Lucent.

F Frequency meter 1 10 MHz ± 1 Hz

G Data Tester Tx rate up to 64 kbit/s contra-directional CCITT interface V.11

REF. ACCESSORIES Q.ty CHARACTERISTICS

H Coaxial Cables 2 Terminations:

• instrument side depending on (A)• equipment side depending on type of DDF

I Shielded pair 2 Termination:

• instrument (F)/(A)• SUB. D 37-pin male connector for 2 Mbit/s• SUB. D 50-pin male connector for service

channels RJ45 for Ethernet ports

J Optical loop 4 Terminations dependent on board/ODF connectors

• loss = 12 dB

............................................................................................................................................................................................................................................................

Instruments, Accessories and related documentsTest and Measurements


............................................................................................................................................................................................................................................................

Table 3-3 EC debugger cable pinout

K CT (LAN) cable 1 Termination:

• RJ45 connector (LAN port) on PC• RJ45 connector on MT320/MT320LO or

MT160/MT160LO (CT port) -(10)

L EC320 debugger cable

(see next Table 3)

1 Termination:

• SUB-D 9-pin connector on PC (COM1 port)• USB connector on EC320 (Debugger port) -

(12)

M Ethernet cable 1 Termination:

• RJ45 connector (LAN port) on PC• RJ45 connector on EC320 (Debugger port) -

(13)

N Coaxial cable for synchronism

1 Termination:

• instrument (F)• Synchronism termination (75 ohm)

O Single-mode single-fiber cord

4 Terminations dependent on board/ODF connectors, power meter and attenuator

P Multi-mode single-fiber cord

4 Terminations dependent on board/ODF connectors, power meter and attenuator

Q Fixed attenuators kit (suggested)

1 Suggested values: 1, 2 ,3 ,4 ,5 ,6 dB - MU type

R Fixed attenuators kit (suggested)

1 Suggested values: 1, 2 ,3 ,4 ,5 ,6 dB - SC type

S Cleaning kit for optical fibers

1

μUSB male (pin) Signal SUB-D 9 pin female (pin)

3 TX 3

2 RX 2

5 GND 5

1 DRT 4

REF. ACCESSORIES Q.ty CHARACTERISTICS

Connection points positionTest and Measurements


3-5

............................................................................................................................................................................................................................................................

Connection points position

Purpose

In the following some reference pictures and table that must be used for the procedures.

Table 3-4 Numbering and functions of common boards Connection Points

Note: Refer to Figure 3-1, (pg. 3-6) for 1850 TSS-320 and toFigure 3-2, (pg. 3-9) for 1850 TSS-160.

Access Point Slot FUNCTION1

Distribution panel

9-pin male Sub-D connector for Rack lamps (RL)

2 25-pin female Sub-D connector for Housekeeping (HK)

3 15-pin female Sub-D connector for Remote Alarms (RA)

4

1850 TSS-320, 15-pin female Sub-D connector for Shelf identifier (ShID)

1850 TSS-160, rotary switches for Shelf identifier (ShID)

5 NOT USED

6 NOT USED

7 RJ45 connector for Step-up alarm and remote inventory "A"

8 RJ45 connector for Step-up alarm and remote inventory "B"

9 25-pin female Sub-D connector for Auxiliary channels (AUX)

10 10, 11RJ45 connector: 10/100 Mbps LAN interface for Craft Terminal connection

11 10, 11RJ45 connector; 10/100 Mbps redundant LAN management interfaces (Q-interfaces) to connect the 135x NMS (DCN)

12 1, 20 RJ45 connector: 10/100 Mbps ETH debug interface

13 1, 20 RS232 on USB debug connector

14 37 5-pin male connector for Power Supply (Input Battery B)

15 37

9-pin Sub-D female connector for SYNCH B. It must be equipped with suitable adapter. Refer to the Product Information and Planning Guide (see “Related documentation” (p. 1-xv)).

16 39 5-pin male connector for Power Supply (Input Battery A)

17 39

9-pin Sub-D female connector for SYNCH A. It must be equipped with suitable adapter. Refer to the Product Information and Planning Guide (see “Related documentation” (p. 1-xv)).

18Distribution

panel1850 TSS-160 only, 15-pins male connector for heaters, fans control and thermocouples.

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-1 Common boards and connection points position for 1850 TSS-320

Table 3-5 1850 TSS-320 boards position

Board Slot FUNCTION

LOA10G21, 22, 24, 33,

35, 36

It adapts 10G of HO switching to 10G of LO switching (it provides access to 10G of LO switching in the Matrix). 4 working LOA (40G) may be deployed. Two hot standby spares may also be deployed to provide 2 groups 1+2 protected. Slot 24 protects slots 21, 22, slot 33 protects slots 35, 36.

R

AT AB

C M

m W

DBG

6 9

1 5

8 1

15 9

25 14

13 1

8 1

15 925 14

13 1

1 3+ -

1 3+ -

PSFA PSFB

AUX CHANNELSSTUPA STUPB

HOUSEKEEPING

SHELF ID

RL

RA

393635343332313029282726252423222120

3719181716151413121110987654321

R

DBG

1

2

1

2

LNKACTMFDXCOL

LNKACT

MFDXCOL

LNKACT

DSFDXCOL

LNKACT

DSFDXCOL

R

DBG

1

2

1

2

LNKACTMFDXCOL

LNKACT

MFDXCOL

LNKACT

DSFDXCOL

LNKACT

DSFDXCOL

R

AT AB

C M

m W

DBG

R

AT AB

C M

m W

DBG

1 2

3

4 5 687

9

14

15

16

17

10

11

10

11

Slotnumber

Slotnumber

12

13

12

13

SOURCESSTATUS

SOURCESSTATUS

(OUT) (IN)(OUT) (IN)



3-7

............................................................................................................................................................................................................................................................

1P10GSO

02 to 09

12 to 19

21 to 28

29 to 36

10 Gbps (STM-64) optical card with optical connections on XFP module

4P2G5SO2.5 Gbps (STM-16) optical card with optical connections on SFP modules.

8PSO155 / 622 Mbps (STM-1 - STM4) optical card with optical connections on SFP modules. It also supports electrical connections on the access module.

1POTU2

OTU-2 termination module. It is a bidirectional DWDM Optical Line Card with the ability to encapsulate/de-encapsulate an STM-64/OC-192 signal into/from a G.709 OTU-2 frame with FEC processing.

10XANY

It manages FE, GE, SDH (STM-1/4/16) traffic coming from 10 SFP modules placed on the front panel and to multiplex them together towards the Matrix, into VC4-nv. The card manages any combination of these signals, but the total processing is anyway limited to 10 Gbps by backplane links (half slot card). It manages FE, GE, Fibre Channel (1/2/4G FC), SDH (STM-1/4/16) traffic.

BOOST10GSingle-Channel Booster, it provides optical amplification for one channel (ch. 34) for ULH applications.

PRE10G

Single-Channel Pre-Amp, it provides optical amplification for one channel (ch. 34) for ULH and VLH applications. It is usually used in conjunction with the BOOST10G board.

DWLA10X

10Gbps transponder, with XFP optics on client and Line sides. Client side, both SDH and Data B&W IF are supported. Line side 10.709 Gbps and 11.096 Gbps bit rates are supported. Line side, the XFP-E adapter is required.

PP10GE

02 to 09

12 to 19

Layer 2 data Packet Processor able to collect & switch packets coming from one 10 GE optical interface (provided by one XFP-E or XFP module).

PP1GEIt supports the same features of 10 GE Packet Module (PP10G), but it is dedicated to GE traffic.

PP10MS

Layer 2 Packet Processor (PP10G), able to map 10G Ethernet streams over TDM, via VCAT, LCAS, GFP-F (EoS), acting as an "edge" between TDM and packet domains.

Board Slot FUNCTION

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

LOFA1111

06 to 09

12 to 15

EDFA optical amplifier with 17 dBm output power in C-Band and 22 dB gain (with 9 dB inter stage insertion loss). For FOADM only.

OMDX8100

8:1 channel multiplexer & demultiplexer, 100 GHz grid compliant, supporting 8 channels in the Long Band L1/L2. It includes one extra port to provide capacity upgrade in the Long Band L2/L1.

CWLA3

06 to 09

12 to 15

Multi-rate board (discrete rates in 0.125->2.7 Gbps range) carrying two independent CWDM channels or one protected CWDM channel (CWLA3OP). It is a double transponder in one slot. The 4 optical interfaces are B&W and/or CWDM SFPs.

CWLA3OP

CMDX8 Used in Line Terminal and Back-to-back terminal (Hub) configurations, it is able to mux/demux 1/2/8 CWDM wavelengths to/from a fiber in unidirectional applications, with or without the 1310nm signal insertion/extraction. When used as Hub, two cards are required

CMDX8S

CMDX1S

CMDX2S

CADM1Used in OADM configurations, it is able to add/drop 1/2/4 CWDM wavelengths per direction to/from the aggregate/line signal in unidirectional applications, with/without the 1310nm signal insertion/extraction. As two directions are integrated in the board, only one card is required.

CADM1S

CADM2

CADM2S

CADM4

CADM4S

SS-11, SL-11, SL-12, SS-41, SL-41, SL-42, SS-161, SI-161, SL-161, SL-162, SS-161AR, 1000B

On the relevant board

STM-1, STM-4, STM-16, multi-rate, GE, B&W SFP modules providing optical connections to the boards on which they are plugged

SS-162C,

SL-162C

Multi-rate (0.125->2.7 Gbps) CWDM SFP modules, providing optical connections to the boards on which they are plugged

XI-641, XS-642, XP1L12D2, 10GB

10 Gbps B&W XFPs, providing optical connections to the boards on which they are plugged

XL-642C10 Gbps DWDM XFP, providing optical connections to the boards on which they are plugged

Board Slot FUNCTION



3-9

............................................................................................................................................................................................................................................................

Figure 3-2 Common cards and connection points position for 1850 TSS-160

STUPA STUPB

12 13

R DBG

1 2 1 2

LN

KA

CT

M FD

XC

OL

LN

KA

CT

M FD

XC

OL

LN

KA

CT

DS

FD

XC

OL

LN

KA

CT

DS

FD

XC

OL

R DBG

1 2 1 2

LN

KA

CT

M FD

XC

OL

LN

KA

CT

M FD

XC

OL

LN

KA

CT

DS

FD

XC

OL

LN

KA

CT

DS

FD

XC

OL

Acc

esso

ry to

ols

Top view

Front view

13

8

12 13

218

10 11

10 11

14 15 16 17

R

AT AB

C M

m W

DB

G

R

AT AB

C M

m W

DB

G

4

10

11

37 42/43 38

12131415161718191

293031323334353620

Slot number

40

41

HOUSEKEEPING

RL

RA

S OURCE S S T AT US S OURCE S S T AT US

(OUT ) (IN) (OUT ) (IN)

7

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 3-6 1850 TSS-160 boards position

Board Slot FUNCTION

LOA10G 33, 35, 36

It adapts 10G of HO switching to 10G of LO switching (it provides access to 10G of LO switching in the Matrix). 2 working LOA (20G) may be deployed. One hot standby spares may also be deployed to provide one 1+2 protection group. Slot 33 protects slots 35, 36.

1P10GSO

12 to 19

29 to 36

10 Gbps (STM-64) optical card with optical connections on XFP module

4P2G5SO2.5 Gbps (STM-16) optical card with optical connections on SFP modules.

8PSO155 / 622 Mbps (STM-1 - STM4) optical card with optical connections on SFP modules. It also supports electrical connections on the access module.

1POTU2

OTU-2 termination module. It is a bidirectional DWDM Optical Line Card with the ability to encapsulate/de-encapsulate an STM-64 signal into/from a G.709 OTU-2 frame with FEC processing.

10XANY10XANY manages FE, GE, Fibre Channel (1/2/4G FC), SDH (STM-1/4/16) traffic.

BOOST10GSingle-Channel Booster, it provides optical amplification for one channel (ch. 34) for ULH applications

PRE10G

Single-Channel Pre-Amp, it provides optical amplification for one channel (ch. 34) for ULH and VLH applications. It is usually used in conjunction with the BOOST10G board.

DWLA10X

10Gbps transponder, with XFP optics on client and Line sides. Client side, both SDH and Data B&W IF are supported. Line side 10.709 Gbps and 11.096 Gbps bit rates are supported. Line side, the XFP-E adapter is required.



3-11

............................................................................................................................................................................................................................................................

PP10GE

12 to 19

Layer 2 data Packet Processor able to collect & switch packets coming from one 10 GE optical interface (provided by one XFP-E or XFP module). It supports Ethernet service emulation over a T-MPLS transport network (PWE3 based, L1 is provided by SDH or Ethernet) and enhanced QoS (8 CoS mapped onto 8 queues).

PP1GEIt supports the same features of 10 GE Packet Module (PP10GE), but it is dedicated to GE traffic.

PP10MS

Layer 2 Packet Processor (PP10G), able to map 10G Ethernet streams over TDM, via VCAT, LCAS, GFP-F (EoS), acting as an "edge" between TDM and packet domains..

LOFA1111

12 to 15

EDFA optical amplifier with 17 dBm output power in C-Band and 22 dB gain (with 9 dB inter stage insertion loss). For FOADM only.

OMDX8100

8:1 channel multiplexer & demultiplexer, 100 GHz grid compliant, supporting 8 channels in the Long Band L1/L2. It includes one extra port to provide capacity upgrade in the Long Band L2/L1.

CWLA3

12 to 15

Multi-rate board (discrete rates in 0.125->2.7 Gbps range) carrying two independent CWDM channels or one protected CWDM channel (CWLA3OP). It is a double transponder in one slot. The 4 optical interfaces are B&W and/or CWDM SFPs.

CWLA3OP

CMDX8 Used in Line Terminal and Back-to-back terminal (Hub) configurations, it is able to mux/demux 1/2/8 CWDM wavelengths to/from a fiber in unidirectional applications, with or without the 1310nm signal insertion/extraction. When used as Hub, two cards are required

CMDX8S

CMDX1S

CMDX2S

CADM1Used in OADM configurations, it is able to add/drop 1/2/4 CWDM wavelengths per direction to/from the aggregate/line signal in unidirectional applications, with/without the 1310nm signal insertion/extraction. As two directions are integrated in the board, only one card is required.

CADM1S

CADM2

CADM2S

CADM4

CADM4S

Board Slot FUNCTION

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

SS-11, SL-11, SL-12, SS-41, SL-41, SL-42, SS-161, SI-161, SL-161, SL-162, SS-161AR, 1000B

On the relevant board

STM-1, STM-4, STM-16, multi-rate, GE, B&W SFP modules providing optical connections to the boards on which they are plugged

SS-162C,

SL-162C

Multi-rate (0.125->2.7 Gbps) CWDM SFP modules, providing optical connections to the boards on which they are plugged

XI-641, XS-642, XP1L12D2, 10GB

10 Gbps B&W XFPs, providing optical connections to the boards on which they are plugged

XL-642C10 Gbps DWDM XFP, providing optical connections to the boards on which they are plugged

Board Slot FUNCTION

Local Measures list and operating sequenceTest and Measurements


3-13

............................................................................................................................................................................................................................................................

Local Measures list and operating sequence

The purpose of local measures is to check the correct operating mode of the equipment boards.

They are detailed in the following paragraphs here contained.

“Free running frequency check” (p. 3-14)


............................................................................................................................................................................................................................................................

Free running frequency checkTest and Measurements


............................................................................................................................................................................................................................................................

Free running frequency check

Purpose

The test allows to verify the correct frequency value of the oscillator on the MATRIX. The equipment must be provided with TIMING ADAPTER (8DG 08739 AA__).

Test instruments

Refer to Table 3-1, “Instruments” (p. 3-3).

• Craft Terminal (E)

• Frequency Meter (F)

Accessories

Refer to Table 3-2, “Accessories” (p. 3-3)

• Cable for synchronism (N)

• CT (LAN) cable (K)

Test BenchNote: In the test bench picture, the boards position for 1850 TSS-320 and 1850 TSS-160 are referred only in order to make thedrawing easier.

Set up the bench shown in Figure 3-3, “Free-running frequency check” (p. 3-15) with the equipment switched off.



3-15

............................................................................................................................................................................................................................................................

Figure 3-3 Free-running frequency check

Procedure

Refer to Figure 3-1, “Common boards and connection points position for 1850 TSS-320” (p. 3-6), Figure 3-2, “Common cards and connection points position for 1850 TSS-160” (p. 3-9) and Figure 3-3, “Free-running frequency check” (p. 3-15).

1. Connect the outgoing synchronism ( symbol) to the frequency meter .

2. Switch on the equipment.

Important! If no synchronism reference clock had been previouslyset, at the equipment switching on, the local oscillator supplies thereference clock.

3. In the menu bar follow the Synchronization Bits Modify BITS-OUT menu path.

4. In the panel click on Continue hyperlink and the Modify BITS-OUT panel appears.

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

BLOCK DIAGRAM

1850 TSS-320/160

E

K

F

FREQUENCYCOUNTER

PSF320

FREQUENCYCOUNTER

MT320 / MT160Slot 10

PSF320Slot 37 or 39

SOURCESSTATUS

(OUT) (IN)

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

5. In the Modify BITS-OUT panel, set the parameters as follows:

• Signal Format: field as 2 MHz value

• Enable Output: field as Y to enable the output source on external connector.

6. Check that the frequency meter reads a value of 2,048 kHz ±4.6 ppm and record it in the Table 5-4, “On-Site 1850 TSS-320/160 Final Test: SDH Local Measurements” (p. 5-5).

........................................................................................................................................................E N D O F S T E P S

Optical STM-1 and STM-4 ports testTest and Measurements


3-17

............................................................................................................................................................................................................................................................

Optical STM-1 and STM-4 ports test

Purpose

The purpose of this procedure is to verify the optical output power and the ALS correct operation.

Test instruments



• Pattern Generator/Error Detector (A)

• Power meter (B)

• x dB fixed attenuator

Accessories


• Single-mode or multi-mode single-fiber cords (O) or (P), according to the interface type

• Craft Terminal (LAN) cable (K)


• Set up the bench shown in Figure 3-4, “STM-1/STM-4 Ports test” (p. 3-18).

WARNING

Insert x dB fixed attenuator, according to the optical characteristics of instruments and boards

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-4 STM-1/STM-4 Ports test

Procedure

Refer to Figure 3-1, (pg. 3-6), Figure 3-2, (pg. 3-9) for boards location and Figure 3-4, (pg. 3-18) for test bench set-up.

1. By means of CT applications, enable the Automatic Laser Shutdown, as described in “How to enable ALS” (p. 4-17), on the looped optical port under test.

PTx power test

2. Preset the instrument to transmit a signal (depending on the type of port used) with the following requirements:

BLOCK DIAGRAM1850 TSS-320/160

Optical port"n"

MatrixPattern Generator

Error Detector

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K


1850 TSS-320slot 02 to 09, 12 to 19, 21 to 28, 29 to 36

1850 TSS-160slot 12 to 19, 29 to 36

1P10

GSO

4P2G

5SO

8PSO

10XA

NY

Detail

Error Detector

Power Meter

Pattern GeneratorT

RQ or

A

B

T

Power Meter

LoopLINEport

STM-1 interface STM-4 interfaceBit rate 155,520 kbit/s 622,080 kbit/s

Code/interface (SFP) S-1.1, L-1.1, L-1.2 S-4.1, L-4.1, L-4.2(see para.“SFP and XFP modules” (p. 4-21) for details)

Type STM-1 optical STM-4 optical



3-19

............................................................................................................................................................................................................................................................

3. Insert the signal and test error-free data transit

4. Connect the power meter to the optical port output being tested

5. Check that the optical power is within the range stated on the table in para. “SFP and XFP modules” (p. 4-21).

6. Disconnect the pattern generator from the STM-1 or STM-4 input port. Check no power on Power Meter

7. Repeat the test on each optical board.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Optical STM-16 and STM-64 ports test

Purpose

The purpose of this procedure is to verify the optical output power and the ALS correct operation.

Test instruments




• Power meter (B)


Accessories





• Connect to STM-16 / STM-64 ports a lower bit rate ports, as shown in the following table.

• Performs the test using two different line ports (STM-16 / STM-64) per each tributary (STM-1) port.

• Set up the bench shown in Figure 3-5, “STM-16/STM-64 Ports test” (p. 3-21).

Type of protected cross-connections

STM-1 STM-16/STM-64 See para. “Unprotected Bidirectional XC between a Remote data port (VC4-nV) and an STM-n port” (p. 4-6).

WARNING




3-21

............................................................................................................................................................................................................................................................

Figure 3-5 STM-16/STM-64 Ports test

Procedure

Refer to Figure 3-1, (pg. 3-6), Figure 3-2, (pg. 3-9) for boards location and Figure 3-5, (pg. 3-21) for test bench set-up.

1. By means of CT applications, enable the Automatic Laser Shutdown, as described in “How to enable ALS” (p. 4-17), on the looped optical port under test.



R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K

MT320 / MT160Slot 10 1850 TSS-320 slot 02 to 09, 12 to 19, 21 to 28, 29 to 36

1850 TSS-160 slot 12 to 19, 29 to 36

4P2G

5SO

8PSO

10XA

NY

Detail

Error Detector

Pattern GeneratorRQ orA

BLOCK DIAGRAM 1850 TSS-320/160Loop

STM-1port


Error Detector

LINEport"A"

LINEport"B"

Loop

4P2G

5SO J

Power Meter

Power Meter B

STM-1 interfaceBit rate 155,520 kbit/s

Code/interface (SFP) S-1.1, L-1.1, L-1.2(see para.“SFP and XFP modules” (p. 4-21) for details)

Type STM-1 optical

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

4. By means of CT, enable the ALS on the optical port under test, as described in “How to enable ALS” (p. 4-17).

5. Remove the optical loop from the port under test.

6. Connect the Power meter to the output connector and check that the power is null.

7. When the LASER restart, check for power presence for approx. 5 seconds.

8. If these conditions do not occur, replace the optical board under test.

9. With the Power meter connected to the output connector, disable the ALS on the optical port under test, as described in “How to set a loopback” (p. 4-19).

10. Check that the optical power is within the range stated on the table reported in para. “SFP and XFP modules” (p. 4-21).

11. Restore the optical loop at the port under test.


........................................................................................................................................................E N D O F S T E P S

DANGERWhen ALS is enabled the LASER immediately switch off. It restart after 120 seconds for 5 seconds.

Optical GE and 10GE ports testTest and Measurements


3-23

............................................................................................................................................................................................................................................................

Optical GE and 10GE ports test

Purpose

The purpose of this procedure is to verify the optical output power.

Test instruments




• Power meter (B)


Accessories




Test Bench Note: In the test bench picture, the boards position for 1850 TSS-320 and 1850 TSS-160 are referred only in order to make thedrawing easier.

WARNING


............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-6 Optical GE and 10GE Ports test

Procedure1. In the Tree structure, select the board (e.g. PP1GE-x-x-xx: 1GB), and expand it up to

the port (e.g. SFP-x-x-xx-x: ANY-DATAS)

2. In the Client area, click on the PHYSICAL tab, in the State panel select the Administrative state field as up,

R

Detail


Loop

GbEport


Error Detector

SDHport

Multi-service

collector

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K


1850 TSS-320 - slot 02 to 09, 12 to 191850 TSS-160 - slot 12 to 19

Error Detector


4P2G

5SO

PP1G

E

1850 TSS-320- slot 02 to 09, 12 to 19, 21 to 28, 29 to 361850 TSS-160-slot 12 to 19, 29 to 36

R

PP10

MS

J

Power Meter

Power Meter B



3-25

............................................................................................................................................................................................................................................................

PTx power test


For further details, see Table 4-5, “B&W multi-rate multi-format SFP: optical interfaces characteristics” (p. 4-23), APD and PIN CWDM SFP are also available to manage colored wavelengths. For further details, see Table 4-6, “B&W GE SFPs: optical interfaces characteristics” (p. 4-24).

For further details, see Table 4-7, “CWDM multi-rate (2100 to 2700 Mbps) SFPs optical interfaces characteristics” (p. 4-25), Table 4-8, “B&W 10G XFPs: optical interfaces characteristics” (p. 4-26), and Table 4-9, “B&W 10G long-haul XFPs: optical interfaces characteristics” (p. 4-27).



6. Connect the Power meter to the output connector.

7. Check that the optical power is within the range stated on the table reported in para. “SFP and XFP modules” (p. 4-21).

8. Restore the optical loop at the port under test.


........................................................................................................................................................E N D O F S T E P S

Gigabit Ethernet interface on optical SFP (IEEE 802.3)Interface type 1000 Base-S 1000 Base-L 1000 Base-ZBit rate 1.250 Gbps 1.250 Gbps 1.250 GbpsWavelength 820 -> 860 nm 270 -> 1355 nm 540 -> 1570 nm

10 Gigabit Ethernet interface on optical XFP (IEEE 802.3)Interface type 10G Base-S 10G Base-L 10G Base-E P1L1-2D2 APD DWDMBit rate 9.95328 Gbps; 10.3125 Gbps

Wavelength 840->860 1290->1330 1530->1565 1530->1565C-Band,

100GHz grid

DANGERThe ALS for PP1GE and PP10G boards is not operative in current release.

............................................................................................................................................................................................................................................................

GbE Transport on VC4-xVTest and Measurements


............................................................................................................................................................................................................................................................

GbE Transport on VC4-xV

Purpose

The purpose of this procedure is to check

• the GbE packets transport by means of VC4-xV (virtual concatenation),

• if the Virtual concatenated ETS cross-connection works properly at maximum capacity of the Virtual concatenation group VC4-xV.

• alarms detection

Test instruments





Accessories


• Optical loop (J)




• Refer to Table 3-5, (pg. 3-6) and Table 3-6, (pg. 3-10) for the SFP list and para.“SFP and XFP modules” (p. 4-21) for the technical specifications.

WARNING




3-27

............................................................................................................................................................................................................................................................

Figure 3-7 GbE Transport on VC4-xV test

Procedure1. Set up the test bench.

2. Cross-connect the GE port to the SDH port and the Matrix (MT320/MT320LO or MT160/MT160LO) as follows:

a. carry out the “Unprotected Bidirectional XC between a Remote data port (VC4-nV) and an STM-n port” (p. 4-6)

a. carry out the “P2P XC between a local and a remote data port” (p. 4-8)

3. In the Client window, check that the LOS alarm is present in the Alarms area (and the LED relevant to the SFP under test is OFF)

R

Detail

BLOCK DIAGRAM 1850 TSS-320/160

LoopGbEport


Error Detector

SDHport

Multi-service

collector

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K



Error Detector


4P2G

5SO

PP1G

E


J

R

PP10

MS

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

4. By the Pattern Generator/Error Detector start in transmitting at 100% of the available bandwidth.

– Check that the LOS alarm disappears and that the on-board led relevant to the 1GE port under test is green.


– In the Client window, check the presence of the TSF alarm on the remote port (on PP1GE board).

6. Reconnect the SDH optical loop.

– Check that the TSF alarm disappears.

– Check that all the frames received are the same of those transmitted and no alarms are detected by the instrument for 5 minutes.

........................................................................................................................................................E N D O F S T E P S

Pattern Generator / Error detector setupPort type 1 GEPAutonegotiation ONFrame length 1518 bytesBandwidth 100%

Optical interfaces (XFP) types (refer to para. “SFP and XFP modules” (p. 4-21) for details)

GE interface types (SFP)

Optical B&W = 1000 Base SX / 1000 Base LX / 1000 Base ZX;

Electrical B&W = 1000 Base-TCWDM =

• APD (C8L1-1D2) for long haul,

• PIN (C8S1-1D2) for short haul

DANGERThe ALS for PP1GE boards is not operative in current release.

10GbE Transport on VC4-xVTest and Measurements


3-29

............................................................................................................................................................................................................................................................

10GbE Transport on VC4-xV

Purpose

The purpose of this procedure is to check the 10GbE packets transport by means of VC4-xV (virtual concatenation) and that if the Virtual concatenated ETS cross-connection works properly at maximum capacity of the Virtual concatenation group VC4-xV.

Test instruments





Accessories






• Refer to Table 3-5, (pg. 3-6) and Table 3-6, (pg. 3-10) for the SFP list and para.“SFP and XFP modules” (p. 4-21) for the technical specifications.

WARNING


............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-8 10GbE Transport on VC4-xV test


2. Cross-connect the 10GE port to the SDH port and the Matrix (MT320/MT320LO or MT160/MT160LO) as follows:

a. carry out the “Unprotected Bidirectional XC between a Remote data port (VC4-nV) and an STM-n port” (p. 4-6)

a. carry out the “P2P XC between a local and a remote data port” (p. 4-8)

3. In the Client window, check that the LOS alarm is present in the Alarms area (and the LED relevant to the SFP under test is OFF)

4. By the Pattern Generator/Error Detector start in transmitting at 100% of the available bandwidth.

BLOCK DIAGRAM 1850 TSS-320/160

Loop10GEport


Error Detector

SDHport

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K



Error Detector

Pattern Generator

RQ or

A

R

PP10

GE


1P10

GSO

J

Pattern Generator / Error detector setupPort type 10 GEPAutonegotiation ONFrame length 1574 bytesBandwidth 10%



3-31

............................................................................................................................................................................................................................................................

– Check that the LOS alarm disappears and that the on-board led relevant to the 10GE port under test is green.


– In the Client window, check the presence of the TSF alarm on the remote port (on PP10GE board).

6. Reconnect the SDH optical loop.

– Check that the TSF alarm disappears.

– Check that all the frames received are the same of those transmitted and no alarms are detected by the instrument for 5 minutes.

........................................................................................................................................................E N D O F S T E P S

Optical interfaces (XFP) types (refer to para. “SFP and XFP modules” (p. 4-21) for details)

10GE interface types (XFP)B&W = 10G Base-S / 10G B Base- / 10G Base-EAPD WDM for long haul (ITU-T G.698.2 - DW100U-2AXC

DANGERThe ALS for PP10G boards is not operative in current release.

............................................................................................................................................................................................................................................................

Q-Bridge VLAN switching test, tagged framesTest and Measurements


............................................................................................................................................................................................................................................................

Q-Bridge VLAN switching test, tagged frames

Purpose

The purpose of this procedure is to check that Q-Bridge is able to transport tagged traffic frames among the ports member set.

Test instruments





Accessories


• Single-mode or multi-mode single-fiber pig-tails (O) or (P), according to the interface type


Test Bench• Refer to Table 3-5, (pg. 3-6) and Table 3-6, (pg. 3-10) for the SFP list and para. “SFP

and XFP modules” (p. 4-21) for the technical specifications.

WARNING




3-33

............................................................................................................................................................................................................................................................

Figure 3-9 Q-Bridge VLAN switching test, untagged frames test

Procedure1. Follow Data Bridge Configuration menu path.

2. In Bridge Configuration panel find the Bridge Type: field and by means of the combo-box select Bridge802.1Q (Virtual Bridge Type) than click on Save & Continue hyperlink.

Figure 3-10 Bridge configuration

3. In order to set the port as a Bridge; in the Tree area select the packet processor board (e.g. ).

BLOCK DIAGRAM1850 TSS-320

GbEport

Pattern Generator

Error Detector

GbEport

Matrix

R

DetailR

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K


1850 TSS-320- slot 02 to 09, 12 to 191850 TSS-160 - slot 12 to 19

Error Detector

Pattern GeneratorRQ or A

PP1G

E

Detail

RQ or

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

4. The following steps are to set the Ethernet local port as ETB (i.e. Network to Network Interface type).

a. In the Tree structure, select the board (e.g. PP1GE-x-x-xx), expand it up to the modules (e.g. MDL-x-x-xx-x). The yellow LED highlights an equipped but not provisioned module, if the module is not equipped the LED is gray.

b. Select one out of the module and in the Client area select Provisioned Type: = ANY-DATAS by means the combo box and then click on Save hyperlink.

Figure 3-11 Module provisioned type selection

In the Tree area, under the module, the port is created (e.g. with grey port icon)

c. Select the previously created port in the Tree area, while in the Ethernet port panel of the Client area select the Client Type: = etb and then click on Save hyperlink.



3-35

............................................................................................................................................................................................................................................................

Figure 3-12 Port behaviour selection

d. Click on Enable auto-negotiation hyperlink, in MAU panel,

Figure 3-13 Auto-negotiation enabling

e. In the State panel of the Client area, select the Administrative state field as up (e.g. with colored port icon),

WARNINGIf the Auto-negotiation is enabled for the Ethernet port, it must be set for the instrument too.

WARNINGPort icon color depends on the port type:

• orange color for NNI - ETB (it will be registered in Tagged Member Set)

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-14 Administrative state setting

5. Repeat from Step a to Step e in order to set a second ETB port.

Check that in expanding the Tree area up to the port , and selecting the BRIDGE functional tab, the Rack_ > Shelf_ > Board __ > Module __ > Port __ tab change it in 802.1Q tab

6. Follow Data Virtual LAN Management Virtual LAN menu path and in the Client area the list of the available VLAN is shown.

Figure 3-15 VLAN creation

7. Create a Service VLAN (S-VLAN) entering a integer number (in the 2 to 4094 range, e.g. 8), in the New VLAN field of the VLAN Registration panel, then click on Create hyperlink.

Important! Relevant to S-VLAN numbering, 1 is the default oneand 4095 is reserved)

8. The Client area presents the Service VLAN Registration Management tab. According to the port type (refer to the previously mentioned WARNING), select the port set (e.g. in our example Port Tagged Set as r1sr1sl5/ETHRemPort#1) and add it by means of the right-arrow button.



3-37

............................................................................................................................................................................................................................................................

Figure 3-16 VLAN assignment

9. Click on Save & exit hyperlink and in the Client area, the VLAN list will be updated as shown hereunder.

Figure 3-17 VLAN list

10. Select the VLAN to which these ports have to be connected (e.g. 8) and click on the tagged hyperlink. a new window appears, showing the result of this procedure, i.e. the VLAN creation, where is possible changing from tagged to untagged the traffic type (if any).

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-18 Tagged/untagged selection

11. Click on Save and exit to confirm it.

12. Perform the XC (cross-connection) between the local and remote port, as described in “P2P XC between a local and a remote data port” (p. 4-8).

13. Connect the Pattern Generator/Error detector with the following settings.

Important! It is required to properly configure the instrument(source and destination address), so that Port A transmit to Port B.

Important! The “Frame VLAN Type” of the instrument must beset at 8100.

14. Check that no errors are read.

........................................................................................................................................................E N D O F S T E P S

WARNINGFor Tagged traffic incoming into port A and outgoing onto port B, both the ports must be registered on the same SVLAN x in tagged member set (as for default Untagged traffic only transit between them).

Pattern Generator / Error detector setupPort type 1GEPAutonegotiation ONFrame length 1518 bytesBandwidth 100%S-VLAN x (e.g. 8)

Optical interfaces (SFP) types (refer to para. “SFP and XFP modules” (p. 4-21) for details)


Provider Bridge VLAN switching testTest and Measurements


3-39

............................................................................................................................................................................................................................................................

Provider Bridge VLAN switching test

Purpose

The purpose of this procedure is to check that Provider Bridge is able to transport untagged traffic frames among the ports member set.

Test instruments





Accessories


• Single-mode or multi-mode single-fiber pig-tails (O) or (P), according to the interface type


Test Bench• Refer to Table 3-5, (pg. 3-6) and Table 3-6, (pg. 3-10) for the SFP list and para. “SFP

and XFP modules” (p. 4-21) for the technical specifications.

WARNING


............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-19 Provider Bridge VLAN switching test

Procedure1. Follow Data Bridge Configuration menu path.

2. In Bridge Configuration panel find the Bridge Type: field and by means of the combo-box select Bridge802.1ad (Provider Bridge Type) than click on Save & Continue hyperlink.

Figure 3-20 Provider Bridge configuration

3. In order to set the port as a Bridge in the Tree area select the packet processor board (e.g. ).


GbEport

Pattern Generator

Error Detector

GbEport

Matrix

R

DetailR

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K


1850 TSS-320- slot 02 to 09, 12 to 191850 TSS-160 - slot 12 to 19

Error Detector


PP1G

E

Detail

RQ or



3-41

............................................................................................................................................................................................................................................................

4. The following steps are to set the Ethernet local port as ETB (i.e. Network to Network Interface type).

a. In the Tree structure, select the board (e.g. PP1GE-x-x-xx), expand it up to the modules (e.g. MDL-x-x-xx-x). The yellow LED highlights an equipped but not provisioned module, if the module is not equipped the LED is gray.

b. Select one out of the module and in the Client area select Provisioned Type: = ANY-DATAS by means the combo box and then click on Save hyperlink.

Figure 3-21 Module provisioned type selection

In the Tree area, under the module, the port is created (e.g. with grey port icon)

c. Select the previously created port in the Tree area, while in the Ethernet port panel of the Client area select the Client Type: = etb and then click on Save hyperlink.

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-22 Port behaviour selection

d. Click on Enable auto-negotiation hyperlink, in MAU panel,

Figure 3-23 Auto-negotiation enabling

e. In the State panel of the Client area, select the Administrative state field as up.

WARNINGIf the Auto-negotiation is enabled for the Ethernet port, it must be set for the instrument too.

WARNINGPort icon color depends on the port type:

• orange color for NNI - ETB (it will be registered in Tagged Member Set, P-VID excluded)

• blue color for UNI - ETS (it will be registered in Untagged Member Set)



3-43

............................................................................................................................................................................................................................................................

Figure 3-24 Administrative state setting

5. Repeat from Step a to Step e in order to set the ETS second port, with different Step c where in the Ethernet port panel of the Client area it is necessary select the Client Type: = ets

Check that in expanding the Tree area up to the port , and selecting the BRIDGE functional tab, the Rack_ > Shelf_ > Board __ > Module __ > Port __ tab change it in 802.1ad tab

6. Follow Data Virtual LAN Management Virtual LAN menu path and in the Client area the list of the available VLAN is shown.

Figure 3-25 VLAN creation

7. Create a Service VLAN (S-VLAN) entering a integer number (in the 2 to 4094 range, e.g. 8), in the New VLAN field of the VLAN Registration panel, then click on Create hyperlink.

Important! Relevant to VLAN numbering, 1 is the default P-VIDvalue and 4095 is reserved)

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

8. The Client area presents the Service VLAN Registration Management tab. According to the port type (refer to the previously mentioned WARNING), select the ports set (e.g. in our example Port Tagged Set as r1sr1sl5/ETHRemPort#1 as ETB and Port Untagged Set as r1sr1sl5/ETHRemPort#2 as ETS) and add them by means of the right-arrow buttons.

Figure 3-26 VLAN assignment

9. Click on Save & exit hyperlink and in the Client area, the VLAN list will be updated as shown hereunder.

Figure 3-27 VLAN list



3-45

............................................................................................................................................................................................................................................................

10. Select the VLAN to which these ports have to be connected (e.g. 8) and click on the tagged or untagged hyperlink. A new window appears, showing the result of this procedure, i.e. the VLAN creation, where is possible changing from tagged to untagged and viceversa the traffic type (if any).

Figure 3-28 Tagged/untagged selection

11. Click on Save and exit to confirm it.

12. Perform the XC (cross-connection) between the S-VLAN and ETS port, as described in “XC in Provider scenario” (p. 4-11).

13. Connect the Pattern Generator/Error detector with the following settings.

Important! It is required to properly configure the instrument(source and destination address), so that Port A transmit to Port B.

Important! The “Frame VLAN Type” of the instrument must beset at 88A8.

14. Check that no errors are read.

........................................................................................................................................................E N D O F S T E P S

WARNINGFor Tagged traffic incoming into port A and outgoing onto port B, both the ports must be registered on the same SVLAN x (as for default Untagged traffic only transit between them).

Pattern Generator / Error detector setupPort type 1GEPAutonegotiation ONFrame length 1518 bytesBandwidth 100%S-VLAN x (e.g. 8)

Optical interfaces (SFP) types (refer to para. “SFP and XFP modules” (p. 4-21) for details)


............................................................................................................................................................................................................................................................

CWDM ports testsTest and Measurements


............................................................................................................................................................................................................................................................

CWDM ports tests

Basics

Before starting the CWDM commissioning, be sure that the optical fibres are properly cleaned.

All the single spans attenuation connecting the various link nodes, including the acceptable margin, are given in the Design Project document (released by a Project Manager) and in the Link Description Table (LDT).

The procedure is divided in two parts:

- local test

- link test

The node local test must be firstly performed. The link tests can be carried out after local tests on all nodes.

Figure 3-29 Commissioning example

For the local test optimization the two operators have to move along the link nodes route, as in the following example:

a. they must be able to perform the local tests on all nodes;

b. they must be able to perform the single span attenuation respecting the design project document;

c. they must be able to perform the link tests.

Looking at the example link shown in Figure 3-29, (pg. 3-46), the commissioning steps examples are described in the following:

STEP 1: The operator A performs the local tests on the Terminal-A.

The operator B performs the local tests on OADM-A.

The operators jointly perform the span I attenuation test.

STEP 2: The operators perform the same operations carried out in STEP 1, on Terminal-B, OADM-B and SPAN II.

1

2

TerminalA

B

A B

I OADMA/B

TerminalB

A

II



3-47

............................................................................................................................................................................................................................................................

At the end of link tests it is necessary to come back on all nodes for all the link test presettings removal, if performed, and restore all the node settings according to initial configuration.

Rel 3.0 CWDM boards

For further details, please refer to Table 3-5, (pg. 3-6).

In current release, the following CWDM tributary boards are available:

• CWLA3, CWLA3OP, supporting two CWDM channels/interfaces at 2.5 Gbps (STM-16)

• 4P2G5SO, supporting up to four CWDM interfaces at 2.5 Gbps (STM-16)

• PP10G; It is a Layer 2 data Packet Processor able to collect & switch packets coming from one 10 GE optical interface (provided by one XFP-E or XFP module).

• PP1GE; It supports the same features of 10 GE Packet Module (PP10G), but it is dedicated to GE traffic.

• PP10MS; It is a Layer 2 Packet Processor (PP10G), and maps 10G Ethernet streams over TDM, via VCAT, LCAS, GFP-F (EoS).

In current release, the following CWDM Mux/Demux boards are available:

• CMDX8(S), 8-channel CWDM mux/demux w/ and w/o supervision

• CMDX2S, 2-channel CWDM mux/demux w/ supervision

• CMDX1S, 1-channel CWDM mux/demux w/ supervision

In current release, the following CWDM OADM boards are available:

• CADM4(S), 4-channel CWDM OADM w/ and w/o supervision



For the supported CWDM and B&W SFPs, refer to Table 3-5, (pg. 3-6).

Alarms and consequent actions on CWLA3 and CWLA3OP

The default configuration is with both channels in add/drop, as shown in Figure 3-30, (pg. 3-48).

Table 3-7, (pg. 3-48) shows the alarms and the relevant consequent actions.

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-30 Add&drop configuration *default configuration

Table 3-7 Alarms usage for both Channels in Add/Drop Configuration on CWLA3(OP)

Alarm Action

CWDM_RX1_LOS Shutdown user TX1

USER_RX1_LOS Shutdown CWDM TX1

CWDM_RX2_LOS Shutdown user TX2

USER_RX2_LOS Shutdown CWDM TX2

8x8 MATRIX

User RX 1

CDR1User TX 1

Input

OutputPort #1

User RX 2

CDR2User TX 2

Input

OutputPort #3

CWDM TX 1CDR3

CWDM RX 1

Port #2

CWDM TX 2CDR4

CWDM RX 2

Port #4

Channel #1

Channel #2



3-49

............................................................................................................................................................................................................................................................

CWDM commissioning Overview

The kinds of nodes that can be present in a link are the following:

• LINE TERMINAL

• OADM

• Back-to-back (HUB)

LINE TERMINAL

The LINE TERMINAL is built on

– one CWDM mux/demux (CMDX) board

– CWDM channels, provided by CWLA3, CWLA3OP, STM-16 and GbE boards, provided with CWDM interfaces/ports.

The LINE TERMINAL is able to mux/demux up to 8 channels (1, 2 or 8 channels, according to the board type) to/from an optical fiber CWDM line.

Figure 3-31 Line Terminal configuration in CWDM systems

Matrix

B/W signals

B&W SFPs

B/W signal

B/W signal

CWDMSFPs

B&WSFPs

CWDMSFPs

N channels (up to 8) tothe other node

CM

DX

(MU

X/D

EMU

X)

GBECWDM port

STM-16CWDM port

STM-16 CWDM ports(CWLA3)

STM-16 B&W ports

N x STM-N /GbE B&W

ports

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

OADM

The OADM is built on

– one or two OADM (CADM) board(s) (1, 2 or 4 channels add/drop capacity), according to the board type

– CWDM channels, provided by CWLA3, CWLA3OP, STM-16 and GbE boards, provided with CWDM interfaces/ports.

The OADM adds and drops a part of the traffic (1, 2 or 4 channels, according to the board type) in both directions, as shown in Figure 3-32, (pg. 3-50).

Figure 3-32 OADM configuration in CWDM systems

Matrix

N channels (up to 8) tthe other node

CM

DX

(MU

X/D

EMU

X)

STM-16/GbECWDM ports

CWDMSFPs

B&WSFPs


STM-16 B&W ports


CM

DX

(MU

X/D

EM

UX)


CWDMSFPs

B&WSFPs


STM-16 B&W ports

N x STM-N / GbEB&W ports

B&W SFPs

N - X pass-through channels

X added/dropped channels (X = 1, 2 or 4)



3-51

............................................................................................................................................................................................................................................................

Back-to-back (HUB)

The Back-to-back terminal configuration is made up of two Line terminal, hence including two mux/demux (CMDX) boards (1, 2 or 8 channels add/drop capacity) and CWDM channels. The Back-to-back terminal adds and drops all the traffic in both directions. There are no pass-through channels.

Figure 3-33 Back-to-back (HUB) configuration in CWDM systems

Important! The following procedures must be carried out by atleast two operators, each one equipped with the instruments listed.

Matrix

N channels (up to 8) tthe other node

CM

DX

(MU

X/D

EM

UX)


CWDMSFPs

B&WSFPs


STM-16 B&W ports


CM

DX

(MU

X/DEM

UX)


CWDMSFPs

B&WSFPs


STM-16 B&W ports

N x STM-N / GbEB&W ports

B&W SFPs

N added/dropped channels

............................................................................................................................................................................................................................................................

Local test in Line Terminal configuration in CWDM systemsTest and Measurements


............................................................................................................................................................................................................................................................

Local test in Line Terminal configuration in CWDM systems

Purpose

The purpose of this procedure is to check that the Line terminal correct operation.

Note: B&W ports are provided by PP1GE, 4P2G5SO, 8PSO,1P10GSO, CWLA3(OP) boards.

Note: CWDM ports are provided by PP1GE, 4P2G5SO andCWLA3(OP) boards as referred in para. “Rel 3.0 CWDM boards”(p. 3-47).

Test instruments



• Optical power meter (B)

• Variable optical attenuator (C)


Accessories



• Craft Terminal cable (K)

• Single-mode or multi-mode single-fibers cords (O) or (P), according to the interface type

• Fixed attenuators kit (R) or (Q)

• Cleaning kit for optical fibers (S)

Test bench• Refer to Table 3-5, (pg. 3-6) for the SFP list and para.“SFP and XFP modules”

(p. 4-21) for the technical specifications.

WARNING




3-53

............................................................................................................................................................................................................................................................

Figure 3-34 Local test in Line Terminal configuration in CWDM systems

Procedure1. Perform a bidirectional unprotected cross-connection between B&W/client and

CWDM port(s), according to the boards equipped (only for SDH and DATA boards, not required for CWLA3 and CWLA3OP); for Ethernet/Data cross-connection, refer to para. “Q-Bridge VLAN switching test, tagged frames” (p. 3-32).

2. Before connecting the VOA, plug-out the Rx input fiber of the CWDM board(s) - (CWLA3, CWLA3OP, PIM1GE, 4P2G5SO)

3. Connect the VOA between the CMDX MUX output and CMDX DEMUX input; the VOA value must be equal to the span power budget

6 9

1 5

8 1

15 9

25 14

13 1

8 1

15 925 14

13 1

1 3+ -

1 3+ -

PSFA PSFB


HOUSEKEEPING

SHELF ID

RL

RA

393635343332313029282726252423222120

3719181716151413121110987654321

R

AT AB

C M

m W

DBG

R

AT AB

C M

m W

DBG

SO

UR

CE

SS

TA

TU

SS

OU

RC

ES

ST

AT

US

R

DBG

1

2

1

2

LNKACTMFDXCOL

LNKACTMFDXCOL

LNKACT

DSFDXCOL

LNKACT

DSFDXCOL

R

DBG

1

2

1

2

LNKACTMFDXCOL

LNKACTMFDXCOL

LNKACT

DSFDXCOL

LNKACT

DSFDXCOL

EK

Error Detector

Pattern GeneratorR Qor

A C

BLOCK DIAGRAM 1850 TSS-320

GbEB&Wport

Matrix

GBECWDMport(s)

STM-NB&Wport

STM-16CWDMport(s)

CM

DXPattern

Generator&

ErrorDetector

CWLA3CWLA3OP

STM

-16

B&

W p

orts

CW

DM

por

ts

VOA

R

S

4749

5153

5557

5961

PWR

CH2

CH1

OOS

W2

W2

W1

W1

U2

U2

U1

U1

VOA

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

4. Check the output power of each CWDM port (SFP), by means of the Power meter (refer to para. “SFP and XFP modules” (p. 4-21) for power values). Then connect each fiber to the related SFP Transmitter and disconnect the other end of the same fiber from each MUX input

5. Check that the insertion loss of each fiber is < 0.1 dB, then reconnect the fibers

6. Disconnect the MUX output fiber and check the output power by means of the Power meter

7. Verify the insertion loss of each channel by connecting one-by-one the MUX CWDM tributary input channels and checking each time the MUX output power with the Power meter. Refer to para. “CWDM mux/demux” (p. 4-29) for the insertion loss value of each channel of CMDX (or OADM) boards (MUX side)

8. Through the ODF, connect the MUX output (multiplexed signal) to the VOA input and the VOA output to the DEMUX input (optical loop)

9. Verify the insertion loss of each DEMUX channel, connecting one-by-one the Power meter to each DEMUX output and checking each time the optical power. Refer to para. “CWDM mux/demux” (p. 4-29) for the insertion loss value of each channel of CMDX and OADM boards (DEMUX side)

10. Connect each fiber to the related DEMUX output, then disconnect the other end from each CWDM SFP, Rx side, and check that:

– the insertion loss of each fiber is < 0.1 dB

– for each port, the received power is in the supported optical range, as referred to para. “SFP and XFP modules” (p. 4-21).

11. Connect each fiber to the related port/SFP, Rx side

12. Test the BER at a given bit rate, checking no errors for 5 minutes.

........................................................................................................................................................E N D O F S T E P S

Local test in OADM configuration in CWDM systemsTest and Measurements


3-55

............................................................................................................................................................................................................................................................

Local test in OADM configuration in CWDM systems

Purpose

The purpose of this procedure is to check that the Add-Drop correct operation.

Note: B&W ports are provided by PP1GE, 4P2G5SO, 8PSO,1P10GSO, CWLA3(OP) boards.

Note: CWDM ports are provided by PP1GE, 4P2G5SO andCWLA3(OP) boards as referred in para. “Rel 3.0 CWDM boards”(p. 3-47).

Test instruments






Accessories







Test bench• Refer to Table 3-5, (pg. 3-6) for the SFP list and para.“SFP and XFP modules”

(p. 4-21) for the technical specifications.

Note: CWLA3 wiring to the test instrument isn’t shown forsimplicity reasons (too many lines). As an example, a CWLA3 isequipped in Figure 3-34, “Local test in Line Terminal configurationin CWDM systems” (p. 3-53)

WARNING


............................................................................................................................................................................................................................................................

Local test in OADM configuration in CWDM systemsTest and Measurements


............................................................................................................................................................................................................................................................

Figure 3-35 Local test in OADM configuration in CWDM systems

Procedure

Perform the procedure previously described in para.“Local test in Line Terminal configuration in CWDM systems” (p. 3-52) for both EAST and WEST sides of the OADM configuration. Only the added and dropped channels have to be checked.

If present, the pass-through channels will be tested in link test (End-to-end), described in para. “Link test in CWDM systems” (p. 3-57).

6 9

1 5

8 1

15 9

25 14

13 1

8 1

15 925 14

13 1

1 3+ -

1 3+ -

PSFA PSFB


HOUSEKEEPING

SHELF ID

RL

RA

393635343332313029282726252423222120

3719181716151413121110987654321

R

AT AB

C M

m W

DBG

R

AT AB

C M

m W

DBG

SO

UR

CE

SS

TA

TU

SS

OU

RC

ES

ST

AT

US

R

DBG

1

2

1

2

LNKACT

MFDXCOL

LNKACT

MFDXCOL

LNKACT

DSFDXCOL

LNKACTDSFDXCOL

R

DBG

1

2

1

2

LNKACT

MFDXCOL

LNKACT

MFDXCOL

LNKACT

DSFDXCOL

LNKACTDSFDXCOL

EK

Error Detector

Pattern Generator

R Qor

A C

BLOCK DIAGRAM

1850 TSS-320

CA

DM

PASS-THROUGH CHANNELS

VOA

R PWR

CH2

CH1

OOS

W2

W2

W1

W1

U2

U2

U1

U1

S -E

47-E

49-E

51-E

53-E

E

S-W

E

47-W49-W

51-W53-W

W

W

VOA

VOA

CWDM port

B&W port

CW

LA3(

OP

)

GbECWDM

port

STM-16CWDM

port

CWDM port

B&W port

GbECWDM

port

STM-16CWDM

port

CA

DM

GbEB&Wport

STM-NB&Wport

STM-NB&Wport

GbEB&Wport

Matrix

Pattern Generator / Error Detector

VOA

CW

LA3(

OP

)

Link test in CWDM systemsTest and Measurements


3-57

............................................................................................................................................................................................................................................................

Link test in CWDM systems

Purpose

The purpose of this procedure is to check that the link operates in correct way.

Figure 3-36 Link Test in CWDM systems

1. Rx input power level check per each channel

Before connecting the Line fiber between CMDX-A and OADM-A, disconnect the Rx fiber per each channel (between CMDX-A and each CWDM SFP, plugged on each tributary board). Check the Rx input power and, if necessary, insert a fixed optical attenuator, whose value depends on the interface type; refer to para. “SFP and XFP modules” (p. 4-21) for interfaces/SFP optical characteristics

2. Span 1 check

If the span loss is other than the one declared by the customer, please refer to the Project Manager.

Station B PRX check: disconnect the fiber from the OADM-A Line signal input, connect it to the Power meter and verify the compliance with the LDT. Reconnect the fiber

Station A PRX check: disconnect the fiber from the CMDX-A Line signal input, connect it to the Power meter and verify the compliance with the LDT. Reconnect the fiber

3. Span 2 check

Station B PRX check: disconnect the fiber from the OADM-B Line signal input, connect it to the Power meter and verify the compliance with the LDT. Reconnect the fiber

Station C PRX check: disconnect the fiber from the CMDX-B Line signal input, connect it to the Power meter and verify the compliance with the LDT. Reconnect the fiber

STATION A

CH 1 STM-16

CM

DX-

A

CH 2

CH 3

STM-16

GbE

PatternGenerator

ErrorDetector

STATION B

SPAN 1 SPAN 2

STM-16 STM-16

OA

DM

-A OA

DM

-B

STATION C

CH 1 STM-16

CM

DX-B

CH 2

CH 3

STM-16

GbE

CH 2 - CH 3

CH 1 CH 1

............................................................................................................................................................................................................................................................

Link test in CWDM systemsTest and Measurements


............................................................................................................................................................................................................................................................

4. End-to-end stability test.

Perform a physical loop (Station C, user side) on all the channels with the same bit rate.

Referring to the example of Figure 3-37, (pg. 3-58), and assuming CH1 and CH2 are STM-16 and CH3 is GbE, on ODF perform a physical loop on CH1 and CH2 client side in Station C.

In Station B (OADM) connect CH1 in physical pass-through.

Connect the Pattern Generator/Error Detector output to the CH1 client Input in Station A and check that the CH1 client Output power (Station A) is OK (refer to para. “CWDM mux/demux” (p. 4-29)).

Perform a Daisy chain in Station A, connecting CH1 Client Output to CH2 Client Input.

Check that the CH2 client Output Power (Rx value on the instrument) is OK.

Connect the CH2 client Output to the Pattern Generator/Error Detector Input and start the stability test: at a given bit rate, check no errors.

Figure 3-37 End-to-end stability test example in CWDM systems

5. After having checked all the channels, by CT check that all the ports under stability test don't have any alarm.

........................................................................................................................................................E N D O F S T E P S

STATION A

CH 1 STM-16

CM

DX-

A

CH 2

CH 3

STM-16

GbE

PatternGenerator

ErrorDetector

STATION B

SPAN 1 SPAN 2

STM-16 STM-16

OA

DM

-A OA

DM

-B

STATION C

CH 1 STM-16

CM

DX-B

CH 2

CH 3

STM-16

GbE

CH 2 - CH 3

CH 1 CH 1

DWDM ports testsTest and Measurements


3-59

............................................................................................................................................................................................................................................................

DWDM ports tests

Basics

The purpose is to give some information about configurations and relevant tests.

The basics are referred in “Q-Bridge VLAN switching test, tagged frames” (p. 3-32).

Rel 3.0 DWDM boards

For further details, please refer to Table 3-5, (pg. 3-6) .

The following DWDM tributary boards are available in current rel.:

• 1P10GSO, supporting one DWDM interface at 10 Gbps (STM-64)

• PP10G; It is a Layer 2 data Packet Processor able to collect & switch packets coming from one 10 GE optical interface (provided by one XFP-E or XFP module).

The following DWDM Mux/Demux board is available in current rel.:

• OMDX8100, 8-channel DWDM mux/demux

For the supported DWDM and B&W XFPs, refer to Table 3-5, (pg. 3-6).

DWDM commissioning Overview

The kinds of nodes that can be present in a link are the following:

• LINE TERMINAL

• OADM

• Back-to-back (HUB)

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

LINE TERMINAL

The LINE TERMINAL is built on

– one DWDM mux/demux (OMDX) board

– DWDM channels, provided by STM-64 and10 GbE boards, provided with DWDM interfaces/ports.

The LINE TERMINAL is able to mux/demux up to 8 channels to/from an optical fiber DWDM line.

Figure 3-38 Line Terminal configuration in DWDM systems

Matrix

B&W XFPs

B/W signal

DWDMXFPs

DWDMXFPs

8 channels tothe other node

OM

DX8

100

(MU

X/D

EMU

X)

10GbEDWDM port

STM-64DWDM port

8 x STM-N /10GbE

B&W ports



3-61

............................................................................................................................................................................................................................................................

OADM

The OADM is built on

– two OADM (OMDX8100) boards (8 channels add/drop capacity)

– DWDM channels, provided by STM-64 and 10GbE boards, provided with DWDM interfaces/ports.

The OADM adds and drops a part of the traffic (8 channels) in both directions, as shown in Figure 3-39, (pg. 3-61).

Figure 3-39 OADM configuration in DWDM systems

Matrix

N channelsfrom/to

the other node

OM

DX8

100

DWDMXFPs

N channelsfrom/to

the other node OM

DX8100

STM-64DWDM ports

DWDMXFPs

8 x STM-N / 10GbEB&W ports

B&W XFPs

N - 8 pass-through channels

8 added/dropped channels

10GbEDWDM ports

10GbEDWDM ports

STM-64DWDM ports

1

8

1

8

B&W signals

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Back-to-back (HUB)

The Back-to-back terminal configuration is made up of two Line terminal, hence including two DWDM mux/demux (OMDX8100) boards (8 channels add/drop capacity) and DWDM channels. The Back-to-back terminal adds and drops all the traffic in both directions. There are no pass-through channels.

Figure 3-40 Back-to-back (HUB) configuration in DWDM systems

The following procedures must be carried out by at least two operators, each one equipped with the instruments listed.

Matrix

8 channelsfrom/to

the other node

OM

DX8

100

DWDMXFPs

8 channelsfrom/to

the other node OM

DX8100

STM-64DWDM ports

DWDMXFPs

8 x STM-N / 10GbEB&W ports

B&W XFPs

8 added/dropped channels

10GbEDWDM ports

10GbEDWDM ports

STM-64DWDM ports

1

8

1

8

B&W signals

Local test in Line Terminal configuration in DWDM systemsTest and Measurements


3-63

............................................................................................................................................................................................................................................................

Local test in Line Terminal configuration in DWDM systems

Purpose


Note: B&W ports are provided by PP10G, 4P2G5SO, 8PSO,1P10GSO boards.

Note: DWDM ports are provided by PP10GE and 1P10GSOboards (also refer to para. “Rel 3.0 DWDM boards” (p. 3-59)).

Note: Insert an X dB optical attenuator, according to theclient/B&W interface used.

Test instruments






Accessories







............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 3-41 Local test in Line Terminal configuration in DWDM systems

Procedure1. Perform a bidirectional unprotected cross-connection between B&W/client and

DWDM port(s), according to the boards equipped; for Ethernet/Data cross-connection, refer to para. “Q-Bridge VLAN switching test, tagged frames” (p. 3-32).

2. Before connecting the VOA, plug-out the Rx input fiber of the DWDM board(s) - (PP10GE, 1P10GSO)

3. Connect the VOA between the OMDX MUX output and OMDX DEMUX input; the VOA value must be equal to the span power budget

4. Check the output power of each DWDM port (XFP), by means of the Power meter (refer to para. “SFP and XFP modules” (p. 4-21) for power values). Then connect each fiber to the related XFP Transmitter and disconnect the other end of the same fiber from each MUX input

5. Check that the insertion loss of each fiber is < 0.1 dB, then reconnect the fibers

6 9

1 5

8 1

15 9

25 14

13 1

8 1

15 925 14

13 1

1 3+ -

1 3+ -

PSFA PSFB


HOUSEKEEPING

SHELF ID

RL

RA

393635343332313029282726252423222120

3719181716151413121110987654321

R

AT AB

C M

m W

DBG

R

AT AB

C M

m W

DBG

SO

UR

CE

SS

TA

TU

SS

OU

RC

ES

ST

AT

US

R

DBG

1

2

1

2

LNKACTMFDXCOL

LNKACTMFDXCOL

LNKACT

DSFDXCOL

LNKACT

DSFDXCOL

R

DBG

1

2

1

2

LNKACTMFDXCOL

LNKACTMFDXCOL

LNKACT

DSFDXCOL

LNKACT

DSFDXCOL

EK

Error Detector

Pattern Generator

R Qor

AC


10 GbEB&Wport

Matrix

10 GBEDWDM

port

STM-NB&Wport

STM-64DWDM

port

OM

DX8

100

PatternGenerator

&Error

Detector

VOA

VOA

N channels(up to 8)

193.80061

MSFDSF

193.700193.600

193.500193.400

193.300193.200

193.100193.000

R R



3-65

............................................................................................................................................................................................................................................................

6. Disconnect the MUX output fiber and check the output power by means of the Power meter

7. Verify the insertion loss of each channel by connecting one-by-one the MUX DWDM tributary input channels and checking each time the MUX output power with the Power meter. Refer to para. “DWDM mux/demux” (p. 4-36) for the insertion loss value of each channel of the OMDX8100 (MUX side)

8. Connect the MUX output (multiplexed signal) to the VOA input and the VOA output to the DEMUX input (optical loop)

9. Verify the insertion loss of each DEMUX channel, connecting one-by-one the Power meter to each DEMUX output and checking each time the optical power. Refer to para. “DWDM mux/demux” (p. 4-36) for the insertion loss value of each channel of the OMDX8100 (DEMUX side)

10. Connect each fiber to the related DEMUX output, then disconnect the other end from each DWDM XFP, Rx side, and check that:

– the insertion loss of each fiber is < 0.1 dB

– for each port, the received power is in the supported optical range, as referred to para. “SFP and XFP modules” (p. 4-21).

11. Connect each fiber to the related port/XFP, Rx side

12. Test the BER at a given bit rate, checking no errors for 5 minutes.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

Local test in OADM configuration in DWDM systemsTest and Measurements


............................................................................................................................................................................................................................................................

Local test in OADM configuration in DWDM systems

Purpose


Note: B&W ports are provided by PP10G, 4P2G5SO, 8PSO,1P10GSO boards.

Note: DWDM ports are provided by PP10G and 1P10GSOboards (also refer to para. “Rel 3.0 DWDM boards” (p. 3-59)).

Note: Insert an X dB optical attenuator, according to theclient/B&W interface used.

Test instruments






Accessories







Local test in OADM configuration in DWDM systemsTest and Measurements


3-67

............................................................................................................................................................................................................................................................

Figure 3-42 Local test in OADM configuration in DWDM systems

Perform the procedure previously described in para. “Local test in Line Terminal configuration in DWDM systems” (p. 3-63) for both EAST and WEST sides of the OADM configuration. Only the added and dropped channels have to be checked.

If present, the pass-through channels will be tested in link test (End-to-end), described in next para. “Link test in DWDM systems” (p. 3-68).

BLOCK DIAGRAM

1850 TSS-320

OM

DX8

100PASS-THROUGH CHANNELS

VOA

10 GbEDWDM

port

STM-64DWDM

port

10 GbEDWDM

port

STM-64DWDM

port

OM

DX8100

10 GbEB&Wport

STM-NB&Wport

STM-NB&Wport

10 GbEB&Wport

Matrix

Pattern Generator / Error Detector

VOA

6 9

1 5

8 1

15 9

25 14

13 1

8 1

15 925 14

13 1

1 3+ -

1 3+ -

PSFA PSFB


HOUSEKEEPING

SHELF ID

RL

RA

393635343332313029282726252423222120

3719181716151413121110987654321

R

AT AB

C M

m W

DBG

R

AT AB

C M

m W

DBG

SO

UR

CE

SS

TA

TU

SS

OU

RC

ES

ST

AT

US

R

DBG

1

2

1

2

LNKACT

MFDXCOL

LNKACT

MFDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

R

DBG

1

2

1

2

LNKACT

MFDXCOL

LNKACT

MFDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

EK

Error Detector

Pattern Generator

R Qor

AC

VOA

193.80061

MSFDSF

193.700193.600

193.500193.400

193.300193.200

193.100193.000

R R R R

193.80061

MSFDSF

193.700193.600

193.500193.400

193.300193.200193.100

193.000

CVOA

to/fromPattern Generator

&Error Detector

............................................................................................................................................................................................................................................................

Link test in DWDM systemsTest and Measurements


............................................................................................................................................................................................................................................................

Link test in DWDM systems

Purpose

The purpose of this procedure is to check that the link operates in correct way.

Figure 3-43 Link Test in DWDM systems

1. Rx input power level check per each channel

Before connecting the Line fiber between OMDX-A and OADX-B, disconnect the Rx fiber per each channel (between OMDX-A and each DWDM XFP, plugged on each tributary board). Check the Rx input power and, if necessary, insert a fixed optical attenuator, whose value depends on the interface type; refer to para. “SFP and XFP modules” (p. 4-21) for interfaces/XFP optical characteristics

2. Span 1 check

If the span loss is other than the one declared by the customer, please refer to the Project Manager.

Station B PRX check: disconnect the fiber from the OADX-B Line signal input, connect it to the Power meter and verify the compliance with the LDT. Reconnect the fiber

Station A PRX check: disconnect the fiber from the OMDX-A Line signal input, connect it to the Power meter and verify the compliance with the LDT. Reconnect the fiber

3. Span 2 check

Station B PRX check: disconnect the fiber from the OADX-C Line signal input, connect it to the Power meter and verify the compliance with the LDT. Reconnect the fiber

Station C PRX check: disconnect the fiber from the OMDX-D Line signal input, connect it to the Power meter and verify the compliance with the LDT. Reconnect the fiber

4. End-to-end stability test.

STATION A

CH 1 STM-64

OM

DX-

A

CH 2

CH 3

STM-64

10 GbE

PatternGenerator

ErrorDetector

STATION B

SPAN 1 SPAN 2

STM-64 STM-64

OA

DX-B O

AD

X-C

STATION C

CH 1 STM-64

OM

DX-D

CH 2

CH 3

STM-64

10 GbE

CH 2 - CH 3

CH 1 CH 1

Link test in DWDM systemsTest and Measurements


3-69

............................................................................................................................................................................................................................................................

a. Perform a physical loop (Station C, user side) on all the channels with the same bit rate.

Referring to the example of Figure 3-44, (pg. 3-69), and assuming CH1 and CH2 are STM-64 and CH3 is 10 GbE, on ODF perform a physical loop on CH1 and CH2 client side in Station C.

b. In Station B (OADM) connect CH1 in physical pass-through.

c. Connect the Pattern Generator/Error Detector output to the CH1 client Input in Station A and check that the CH1 client Output power (Station A) is OK (refer to para. “DWDM mux/demux” (p. 4-36)).

d. Perform a Daisy chain in Station A, connecting CH1 Client Output to CH2 Client Input.

e. Check that the CH2 client Output Power (Rx value on the instrument) is OK.

f. Connect the CH2 client Output to the Pattern Generator/Error Detector Input and start the stability test: at a given bit rate, check no errors.

Figure 3-44 End-to-end stability test example in CWDM systems

g. After having checked all the channels, by CT check that all the ports under stability test don't have any alarm.

........................................................................................................................................................E N D O F S T E P S

STATION A

CH 1 STM-64

OM

DX-

A

CH 2

CH 3

STM-64

10 GbE

PatternGenerator

ErrorDetector

STATION B

SPAN 1 SPAN 2

STM-64 STM-64

OM

DX-B

OM

DX-

C

STATION C

CH 1 STM-64

OM

DX-D

CH 2

CH 3

STM-64

10 GbE

CH 2 - CH 3

CH 1 CH 1

............................................................................................................................................................................................................................................................

SNCP protection check (line ports)Test and Measurements


............................................................................................................................................................................................................................................................

SNCP protection check (line ports)

Purpose

Verify the SNCP protection efficiency

Test instruments




Accessories





Test Bench:

Figure 3-45 SNCP protection check

For the 1850 TSS-320 shelf configuration, refer to Figure 3-1, (pg. 3-6).


Only one type of cross-connection is reported in the figure. The figure can change depending on the type of tributary port and on the line port selected.

1850 TSS-320/160 Loop

STM-1port

Pattern Generator

Error Detector

STM-16/64Line port

"A"

LoopSTM-16/64Line port

"B"

Matrix

SNCP protection check (line ports)Test and Measurements


3-71

............................................................................................................................................................................................................................................................

Procedure1. Cross-connect the tributary port and the line port as reported on the table.

2. Performs the test using two different line (STM-16 / STM-64) ports per each tributary (STM-1) port.

3. Check that no errors are read on the error detector.

4. Open one out of the Optical loop.

5. Check after a transient condition that no errors are read by the error detector.

........................................................................................................................................................E N D O F S T E P S

Type of protected cross-connections See paragraphSTM-1 STM-16 / STM-64 .“Optical STM-16 and STM-64 ports test”

(p. 3-20)

Bit rate 155,520 kbit/s

Code/interface (SFP) S-1.1, L-1.1, L-1.2(see para. “SFP and XFP modules” (p. 4-21) for details)

Type STM-1 optical

............................................................................................................................................................................................................................................................

Protection test Matrix EPSTest and Measurements


............................................................................................................................................................................................................................................................

Protection test Matrix EPS

Purpose• Check that EPS is working properly

• Check that following switching no data has been lost apart from an initial transient state.

Test instruments




Accessories





Test Bench

Figure 3-46 Matrix/CRU EPS protection check

The figure can change depending on the type of tributary port and on the line port selected.



1850 TSS-320/160Loop

STM-1port

Pattern Generator

Error Detector

STM-16/64Line port

"A"

LoopSTM-16/64Line port

"B"

Matrix "A"Matrix "B"

Protection test Matrix EPSTest and Measurements


3-73

............................................................................................................................................................................................................................................................

Procedure1. Perform the same cross connection used for the previous SNCP protection test.

2. Preset the instrument to transmit a signal with the following requirements:

3. Check that no errors are read on the Error Detector.

4. Remove the MASTER matrix (in slot 10) and insert it again; after a brief transient, check that no errors are read.

........................................................................................................................................................E N D O F S T E P S

Bit rate 155,520 kbit/s

Code/interface (SFP) S-1.1, L-1.1, L-1.2(see para. “SFP and XFP modules” (p. 4-21)for details)

Type STM-1 optical

............................................................................................................................................................................................................................................................

Synchronism priority and Holdover (if present)Test and Measurements


............................................................................................................................................................................................................................................................

Synchronism priority and Holdover (if present)

Purpose

Verify the efficiency of the synchronism (i.e., for the synchronisms that might be preset in the configuration) priority list and the Holdover

Test instruments




• 2-MHz station distribution signal (if present)

Accessories








3-75

............................................................................................................................................................................................................................................................

Figure 3-47 Synchronism priority and holdover

Prerequisites

The synchronization system must be set as follows:

Extracted reference clock (ITU-T definition T1) settings:

1. In the menu bar follow the Synchronization Synchronization Search menu path.

2. In the Synchronization panel, select ALL as Access Identifier: and click on Search hyperlink, selecting one out of the provisionable LINEREFSYS-x-x-xx in the list and click on Modify hyperlink.

3. In the Modify Synchronization panel set the following items:

– Assigned port Access Identifier: one out of the available STM-n ports and that can be selected by means the Select procedure.


STM-N port

SSU(2048 kHz

GENERATOR)

Timing &Synchronism

SSU(2048 kHz

GENERATOR)

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K


PSF320 Slot 37

SOURCESSTATUS

(OUT) (IN)

4P2G

5SO


Holdover

Pattern Generator

(T4/T5)

(T1)

(T0)Error Detector

Detail

Error Detector


J

(T3/T6)

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

– Provisioned Quality Level: It is the provisioned quality level of a timing reference. Two different methods are supported; i.e. the quality level is either derived from the incoming SSM value or a fixed quality value is set. The value AUTO is only allowed for ports supporting SSM. Possible values: AUTO (quality level value is derived from incoming SSM) or PRC (ETSI quality level value is fixed to Primary Reference Clock, specified in ITU-T Rec. G.811) or SSUL (ETSI quality level value is fixed to Synchronization Supply Unit - Local node, specified in ITU-T Rec. G.812) or SSUT (ETSI quality level value is fixed to Synchronization Supply Unit -Transfer node, specified in ITU-T Rec. G.812) or SEC (ETSI quality level value is fixed to SDH Equipment Clock, specified in G.813 option 1). Select one out of the available items .

– Timing Reference Priority: It is the priority of a timing reference for the system timing selection process. It is possible to provision the same priority to different timing references in order to support a non-revertive selection process. When Sync Messaging is disabled, the selection process will be controlled by signal status and priority. The priority "0" means that the timing reference is disabled from the selection process. A greater parameter value means a lower the priority for the selection besides the value "0". Possible values: 0 (disabled for the system timing selection process) and from 1 to 8 (enabled for the system timing selection process). For the test it is suggested to set it as 1.

4. Click on Save hyperlink in order to confirm the settings and the client area shows the updated list.

External reference clock (ITU-T definition T3/T6) settings

1. In the menu bar follow the Synchronization Bits Modify BITS-0 menu path.

2. In the Select Shelf panel, click on Continue hyperlink.

3. In the Modify BITS panel, set the Signal Format: field as the signal type for the timing output port (i.e. out-going direction) as referred in the plat document. This parameter determines the capabilities of the timing output port in terms of SSM insertion and squelching. Possible values: 2MHZ (2 MHz signal without SSM support. ITU-T definiton T3) or 2MBIT-NOSSM (2 Mbit/s framed signal with no SSM support. ITU-T definiton T6) or 2MBIT-SSM (2 Mbit/s framed signal with SSM support. ITU-T definiton T6). For the test it is suggested to set it as 2MHZ.

4. Repeat the procedure for BITS-1.

5. Set the external reference clock from one of the provisionable incoming signals (i.e. on the PSF320 adapter), selecting one out of the possible EXTREF-x-x-x in the list and click on Modify hyperlink.

6. In the Modify Synchronization panel set the items by means the procedure previously mentioned.




3-77

............................................................................................................................................................................................................................................................

Outgoing reference clock (ITU-T definition T4/T5) enabling:

1. In the menu bar follow the Synchronization Bits Modify BITS-OUT menu path.

2. In the Select Shelf panel, click on Continue hyperlink.

3. In the Modify BITS-OUT panel set the following items:

– Signal Format: signal type for the timing output port (i.e. out-going direction). The parameter determines the capabilities of the timing output port in terms of SSM insertion and squelching. Possible values: 2MHZ (2 MHz signal without SSM support. ITU-T definiton T4) or 2MBIT-NOSSM (2 Mbit/s framed signal with no SSM support. ITU-T definiton T5) or 2MBIT-SSM (2 Mbit/s framed signal with SSM support. ITU-T definiton T5).

– Enable Output: specify the output mode to Y (output is enabled, i.e. switched on). Other possible value N (output is disabled, i.e. switched off).



If the SSU (Synchronization Supply Unit) is not available, a 2048 kHz generator can be used.

2. Connect the synchronization signal to incoming synchronism ( symbol on the adapter).

1. In the menu bar follow the Synchronization Synchronization Search menu path, check the following current synchronization status:

• MT320-x-x-10 = NORMAL

2. If you remove at once the Pattern Generator from optical line input, the status changes in MT320-x-x-10 = FREE-RUNNING

3. If you remove 30 minutes after the settings the Pattern Generator from optical line input, the status changes in MT320-x-x-10 = HOLDOVER.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

Alarms check (if connected)Test and Measurements


............................................................................................................................................................................................................................................................

Alarms check (if connected)

Purpose

Verify the correct restitution of the caused alarms and housekeeping alarms.

Test instruments



Accessories



• Lamp block, that might be a LED connected to a -Vtest voltage generator whose ground is common with the equipment, and a series resistance Rs, whose value is given by: Rs=(Vtest)/10 mA.

Note: Vtest must not exceed 72V, and the output current from thepin must not exceed 50 mA. Further, the LED used should bear a10-mA current.




3-79

............................................................................................................................................................................................................................................................

Figure 3-48 Alarms check

Note: Check for alarms also on the EC320 board (see “EC320card front view” (p. 4-37)).

Procedure

Primary power supply alarm check

1. Switch-OFF one Primary power supply (Breaker A).

– Verify that the Green LED on the STEP UP “A”turns OFF.

– Verify that the NURG indication at the top of the rack (rack lamps) lights ON.

– Verify that the NURG (minor) alarm LED of the EC320 lights ON, point (15).

– Verify that the “Lamps block,” connected to the NURG pin of the Remote Alarms connector, turns ON.

69

15

LAMP BLOCK


PSF320 "A"

BREAKER"A"

VBATT 1

PSF320 "B"

RACK LAMPconnector

GENTRU

VBATT 1

VBATT 2

VSERV

STEPUP "A"

STEPUP "B"

RACK LAMPunit

LED RsV ext.

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

E

K


BREAKER"B"

VBATT 2

STEPUP"A"

STEPUP"B"

1RL

PSF320 Slot 37

PSF320 Slot 39

RMcable

SOURCESSTATUS

(OUT) (IN)

SOURCESSTATUS

(OUT) (IN)

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

2. On CT, select the PSF320 board in slot 37.

– Verify that the PWR alarm turns ON.

3. Switch-ON breaker A.

4. Switch-OFF the other primary power supply (Breaker B).

– Verify that the green LED on the STEP UP “B” lights OFF.


5. On CT, select the PSF320 in slot 39.


6. Switch-ON breaker B.

7. Switch-OFF the STEP UP “A”.

– Verify that the green LED on the STEP UP “A” turns OFF.




9. Switch-ON the STEP UP “A”.

10. Switch-OFF the STEP UP “B”.

– Verify that the green LED on the STEP UP “B” turns OFF.



– Verify that the BF alarm (Battery Failure) turns ON.

12. Switch-ON the STEP UP “B”.

........................................................................................................................................................E N D O F S T E P S

Remote alarms check (if present)Test and Measurements


3-81

............................................................................................................................................................................................................................................................

Remote alarms check (if present)

Table 3-8 Rack alarms (RA) connector pin-out

# Pin Signal Description1 RA_ANDBATT Fault or loss of both station batteries2 RA_ORBATT Fault or loss of one station battery3 RA_URG Urgent alarm45 RA_ANC Fault or loss of both equipment-internal service power supplies67 RA_NURG Not Urgent alarm89 RA_ORC Fault or loss of one equipment-internal service power supply1011 RA_INT Internal alarm1213 RA_IND Indeterminate alarm1415 RA_REF Voltage reference of remote alarms

GND Electrical ground - Case

............................................................................................................................................................................................................................................................

Rack lamps checkTest and Measurements


............................................................................................................................................................................................................................................................

Rack lamps check

Refer to Figure 3-49, (pg. 3-84) and Figure 3-50, (pg. 3-84) for Rack Lamps (RL) connector location and pinout

1. If present, remove all of the alarms.

2. Originate the alarms as instructed below and verify that the related rack lamps LED at the top of the rack (TRU) turns ON.

........................................................................................................................................................E N D O F S T E P S

URGExtract one board (in service). Moreover this procedure turns-ON the major (14.) LED on EC320. The major alarm is displayed on CT

NURGSwitch-OFF one step-up. Moreover this procedure turns-ON the minor (15.) LED on EC320. The minor alarm is displayed on CT

MEMWith an URG or NURG alarm raised, press the “alarm cut-off key” (11.) on EC320. Moreover this procedure turns-ON the Attended (17.) alarm LED on EC320

Housekeeping controls & alarms checkTest and Measurements


3-83

............................................................................................................................................................................................................................................................

Housekeeping controls & alarms check

Purpose

Verify the correct restitution of the housekeeping alarms (CPI) and Controls (CPO).

Table 3-9 Housekeeping connector pin-out

WARNING

This function is not managed in current release.

# Pin Signal Description1 Not used Empty2

CPO 1 (HK-OUT 1)# 1 Output; N wire

3 # 1 Output; P wire4 Not used Empty5

CPO 2 (HK-OUT 2)# 2 Output; N wire

6 # 2 Output; P wire7

8CPO 3 (HK-OUT 3)

# 3 Output; N wire9 # 3 Output; P wire10

11CPO 4 (HK-OUT 4)

# 4 Output; N wire12 # 4 Output; P wire13 Not used Empty14 Not used Empty15 Not used Empty15 CPI 1 (HK-IN 1) # 1 Input16 CPI 2 (HK-IN 2) # 2 Input17 CPI 3 (HK-IN 3) # 3 Input18 CPI 4 (HK-IN 4) # 4 Input19 CPI 5 (HK-IN 5) # 5 Input20 CPI 6 (HK-IN 6) # 6 Input21 CPI 7 (HK-IN 7) # 7 Input22 CPI 8 (HK-IN 8) # 4 Input24 CPI_REF Voltage reference of input housekeeping25 Not used Empty

GND Electrical ground - Case

............................................................................................................................................................................................................................................................

Housekeeping controls & alarms checkTest and Measurements


............................................................................................................................................................................................................................................................

Figure 3-49 1850 TSS-320 Back panel electrical connectors location

Figure 3-50 1850 TSS-160 Back panel electrical connectors location

6 9

1 5

8 1

15 9

25 14

13 1

8 1

15 925 14

13 1

1 3+ -

1 3+ -

PSFA PSFB


HOUSEKEEPING

SHELF ID

RL

RA

STUPA STUPB

Acc

esso

ry to

ols

HOUSEKEEPING

RL

RA

Fan 19” alarm testTest and Measurements


3-85

............................................................................................................................................................................................................................................................

Fan 19” alarm test

1. Extract one FAN unit (position 40 or 41).

2. On CT, select the involved FAN.

– Verify that the IMPROPRMVL alarm turns ON.

3. Insert the previously removed FAN unit

4. Repeat the procedure on the other FAN.

........................................................................................................................................................E N D O F S T E P S

WARNING

Do not extract both the FAN units contemporaneously .

............................................................................................................................................................................................................................................................

Final checksTest and Measurements


............................................................................................................................................................................................................................................................

Final checks

Purpose

Check that the equipment has been properly configured.

Test instruments



Accessories



Procedure

The following operations must be carried out at the end of the STAND-ALONE tests:

1. Disconnect all the cross-connections made on the equipment during the test operation phase.

If set down in the executive design, configure the following:

1. The LAPD protocol based on the line interfaces implemented

2. The IP address

3. The NE local address NSAP

4. The OS address

Point-to-point measures list and operating sequenceTest and Measurements


3-87

............................................................................................................................................................................................................................................................

Point-to-point measures list and operating sequence

The aim of point to point measures is to check the whole link including the line.

If alarms and/or errors are detected and if all the local checks have been made, then the failure is due to external causes. If local checks have not been executed proceed as instructed in para. “Local Measures list and operating sequence” (p. 3-13).

In this section, the following are detailed:

• “Rx Optical “line port” power check” (p. 3-88)

• “Optical “line port” link margin” (p. 3-90)

• “Point-to-point error monitoring check” (p. 3-92)

• “Ring error monitoring check” (p. 3-94)

............................................................................................................................................................................................................................................................

Rx Optical “line port” power checkTest and Measurements


............................................................................................................................................................................................................................................................

Rx Optical “line port” power check

Purpose

Verify the optical power of the signal received from the remote 1850 TSS-320/160 (Station B on the test bench).

Test instruments



• Power Meter (B)

Accessories



Test Bench

Figure 3-51 Rx Optical “line port” power check

Procedure1. Disconnect the Rx optical cable line and connect it to the Power meter.

2. By means of the CT, disable the ALS in Station A, as described in para. “How to disable ALS” (p. 4-17).

3. Wait for 180 seconds, and then check that the Rx optical power complies with the expected value.

STM-Nport ODF

Powermeter

STM-NportODF

1850 TSS-320/160 1850 TSS-320/160

RX line optical cable

Station - A Station - B

Craft Terminal

Rx Optical “line port” power checkTest and Measurements


3-89

............................................................................................................................................................................................................................................................

4. Rx power must be calculated on plant data. (PTx - Theoretical line attenuation based on customer data).

5. Repeat the check on the other ports with “Line port” function.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

Optical “line port” link marginTest and Measurements


............................................................................................................................................................................................................................................................

Optical “line port” link margin

Purpose

Verify the margin between the Rx optical power (in normal line condition) and the minimum received optical power (by introducing line attenuation) related to fixed bit error rate.

Test instruments




• Power Meter (B)


Accessories




Test Bench

Figure 3-52 Optical “line port” link margin

ODF

Variableattenuator

STM-NportODF

1850 TSS-320/160

RX line cable


Craft Terminal

STM-Nport ODFSTM-N

portSTM-N

portODF

Powermeter

Error Detector

Pattern Generator

1850 TSS-320/160

LOOP

Optical “line port” link marginTest and Measurements


3-91

............................................................................................................................................................................................................................................................

Procedure

STATION-A

1. Connect the pattern generator output to the STM-N port input and the pattern generator input to the STM-N port output. All connections could be made on the ODF.

2. Connect the Rx optical line cable to a variable optical attenuator with attenuation equal to zero; connect the other side of the variable optical attenuator to the port or to ODF.

3. Preset the instrument according to the port type under test, and send a fixed PRBS sequence.

STATION-B

4. Make a loop on the STM-N concerned with point-to-point connection (or on the ODF).

STATION-A

5. With the pattern generator, send a fixed PRBS sequence

6. Check that the error detector has read no errors.

7. Increase the optical attenuation till errors are read on the error detector.

8. Reduce attenuation until no errors are read.

9. Disconnect the optical cable from the STM-n input port and connect it to the power meter input.

10. Margin level must be minimum 4 dB better than the values reported in para “SFP and XFP modules” (p. 4-21).

11. By means of the CT, disable the ALS in Station A, as described in para. “How to disable ALS” (p. 4-17)).

12. Wait for 180 sec. and then read the Rx optical power.

The difference between the Rx optical power (see “Rx Optical “line port” power check” (p. 3-88)) and the Rx optical power when introducing attenuation (as above explain) is the “link margin.”

13. Repeat the check on the other port with “line port” function.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

Point-to-point error monitoring checkTest and Measurements


............................................................................................................................................................................................................................................................

Point-to-point error monitoring check

Purpose

Check the bit error rate on the link during a certain period of time (for example during night hours).

Test instruments




Accessories




Test Bench:

Figure 3-53 Point-to-point error monitoring check

ODF STM-NportODF

1850 TSS-320/160


port ODFSTM-NportportODF

Error Detector

Pattern Generator

1850 TSS-320/160

LOOP

Point-to-point error monitoring checkTest and Measurements


3-93

............................................................................................................................................................................................................................................................

Procedure

STATION-A

1. Connect the Pattern Generator output to the 1850 TSS-320/160 “port” input and the pattern generator input to the 1850 TSS-320/160 “port” output. All the connection could be made on the ODF.

STATION-B

2. Make a loop on the1850 TSS-320/160 “port” (or on the ODF) concerned with the point to point connection.

STATION-A

3. Set the pattern generator according to the 1850 TSS-320/160 “port” characteristics and send a fixed PRBS sequence.

4. After a certain period of time, check that no errors are read on the error detector.

5. Repeat the check on the other port with the 1850 TSS-320/160 “line port” function.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

Ring error monitoring checkTest and Measurements


............................................................................................................................................................................................................................................................

Ring error monitoring check

Purpose

Check the bit error rate on the link during a certain period of time (for example during night hours)

Test instruments




Accessories




Test Bench

Figure 3-54 Ring error monitoring check

ODF

STM-NportODF

1850 TSS-320/160


port ODFSTM-Nportport

ODF

Error Detector

Pattern Generator

1850 TSS-320/160

STM-NportODF

1850 TSS-320/160

Station - C

port ODFSTM-Nportport



3-95

............................................................................................................................................................................................................................................................

Procedure

STATION-A

1. Connect the pattern generator output to the 1850 TSS-320/160 “port” input and the Pattern Generator input to the 1850 TSS-320/160 “port” output. All the connection could be made on the ODF.

STATION-B

2. Make a loop on the 1850 TSS-320/160 “port” (or on the ODF) concerned with the point-to-point connection.

STATION-A

3. Set the pattern generator according to the 1850 TSS-320/160 “port” characteristics and send a fixed PRBS sequence.

4. After a certain period of time check that no errors are read on the error detector.

5. Repeat the check on the other port with the 1850 TSS-320/160 “line port” function.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................


............................................................................................................................................................................................................................................................


Overview

Purpose

This chapter contains details lists of procedures step typically created with craft terminal configurations.

Furthermore it contains optical characteristics.

These details are always referred from the previous chapters.

Contents


“Bidirectional XC between an STM-4 and STM-64 ports” (p. 4-2)

“Bidirectional protected XC between an STM-4 and STM-64 ports” (p. 4-4)

“Unprotected Bidirectional XC between a Remote data port (VC4-nV) and an STM-n port” (p. 4-6)

“P2P XC between a local and a remote data port” (p. 4-8)

“XC in Provider scenario” (p. 4-11)

“Procedure to enable and disable the ALS” (p. 4-17)

“Procedure to manage a loopback” (p. 4-18)

“SFP and XFP modules” (p. 4-21)

“CWDM mux/demux” (p. 4-29)

“DWDM mux/demux” (p. 4-36)

“EC320 card front view” (p. 4-37)

“MT320/MT320LO or MT160/MT160LO card front view” (p. 4-38)

............................................................................................................................................................................................................................................................

Bidirectional XC between an STM-4 and STM-64 portsConnections, Configurations and Characteristics


............................................................................................................................................................................................................................................................

Bidirectional XC between an STM-4 and STM-64 ports

Purpose

To set an XC (cross-connection) defining the source and destination boards.

Basics Drawing

Figure 4-1 Bidirectional XC between an STM-4 and STM-64 ports

Procedure 1. Follow the Connection TDM Create menu path.

The Create Cross Connection panel appears.

2. In the Create Cross Connection panel select the desired items in the following fields:

– Cross Connection Type: = Connection (it set a cross-connection entity and establishes a one-way [unidirectional], two-way [bidirectional] cross connection between the specified facilities).

– VC Type: = VC4 (it set the cross connection rate on which the command acts).

– Direction: = Starting From (it allows to establish the direction of the cross connection, actual the source point).

3. Click on Continue hyperlink and a window opens where it is possible to select the source point into the Specify a VC of type VC4 panel.

– If you know the identifications of the cross connection, select the source point (Starting From) by means of the combo-boxes whose represent, starting from the left to the right, the Rack, Shelf, Slot, Module, Interface. (e.g. STM1AU4-1-1-8-2-1). Click on ADD button and it will be reported in the Access Identifier: field of the panel.

– If you don’t know the identifications of the cross connection, click on Start Tree Selection button. In the lower part of the windows a tree with the available boards for cross connection and a table with the details appears. Expand the tree for the board involved in the cross connection (e.g. 8XSO-1-1-8: 8PSO SFP-1-1-8-2: SS-11 STM1-1-1-8-2) and in the right part the table with the available VC4 facilities will be shown ( (e.g. STM1AU4-1-1-8-2-1 ). Click on it will be reported in the Access Identifier: field of the panel.

1WAY2WAY

FROM

FROM

FROM TO

TO

TO

samefacility

samefacility

Bidirectional XC between an STM-4 and STM-64 portsConnections, Configurations and Characteristics


4-3

............................................................................................................................................................................................................................................................

4. Click on Set hyperlink and the Provision Cross Connection panel appears with the From: field filled with the previous setting.

5. Click on Select hyperlink of the To: field and repeat the procedure in the Step 3 with the following differences:

– If you know the identifications of the cross connection, select the destination point (Ending From) by means of the combo-boxes whose represent, starting from the left to the right, the Rack, Shelf, Slot, Module, Interface. (e.g. STM64AU4-1-1-4-1-1). Click on ADD button and it will be reported in the Access Identifier: field of the panel.

– If you don’t know the identifications of the cross connection, click on Start Tree Selection button. Expand the tree for the board involved in the cross connection (e.g. 10GSO-1-1-4: 1P10GSO SFP-1-1-4-1: SS-11 STM64-1-1-4-1) and in the right part the table with the available VC4 facilities will be shown ( (e.g. STM16AU4-1-1-4-1-1 ). Click on it will be reported in the Access Identifier: field of the panel.

6. Click on Set hyperlink and the Provision Connection panel appears with the To: field filled with the previous setting.

7. In the Create Cross Connection panel select the 2WAY item, by means of the combo-box associated to the Cross Connection Type: field.

Optionally you can assign a label for the cross connection validating the SET From To Circuit Identifier check-box.

8. Click on Create hyperlink in order to execute the command and set the relevant cross connection.

........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

Bidirectional protected XC between an STM-4 and STM-64ports

Connections, Configurations and Characteristics


............................................................................................................................................................................................................................................................

Bidirectional protected XC between an STM-4 and STM-64 ports

Purpose

To set an XC (cross-connection) defining the source and destination boards.

Basics Drawing

Figure 4-2 Bidirectional protected XC between an STM-4 and STM-64 ports




– Cross Connection Type: = Connection path protected (it set a path protected cross-connection entity and establishes a one-way [unidirectional], two-way [bidirectional] cross connection between the specified facilities)

– VC Type: = VC4 it set the cross connection rate on which the command acts.

– Direction: = Starting Fromped (protecting receive side from the network, protected source of cross-connection). Other possibilities are: Starting Fromping (protecting receive side from the network, protecting source of cross-connection) or Ending To (transmit side to the network, sink of cross-connection).


– If you know the identifications of the cross connection, select the source point (Starting From) by means of the combo-boxes whose represent, starting from the left to the right, the Rack, Shelf, Slot, Module, Interface. (e.g. STM1AU4-1-1-8-2-1). Click on ADD button and it will be reported in the Access Identifier: field of the panel.

1WAY2WAY

FROM

FROM

FROM TO

TO

TO

samefacility

samefacility

Bidirectional protected XC between an STM-4 and STM-64ports



4-5

............................................................................................................................................................................................................................................................

– If you don’t know the identifications of the cross connection, click on Start Tree Selection button. In the lower part of the windows a tree with the available boards for cross connection and a table with the details appears. Expand the tree for the board involved in the cross connection (e.g. 8XSO-1-1-8: 8PSO SFP-1-1-8-2:

4. Click on Set hyperlink and the Provision Connection Path Protected panel appears with the Fromped: field filled with the previous setting and some differences with the previous shown in Step 2.

5. Click on Select hyperlink of the Fromping: field and repeat the procedure in the Step 3 in order to set the protecting receive side from the network, protecting source of cross-connection.

6. After the selection, click on Set hyperlink and the Provision Connection Path Protected panel appears with the Fromping: field filled with the previous setting.

7. Click on Select hyperlink of the To: field and repeat the procedure in the Step 3 in order to set the transmit side to the network, sink of cross-connection.

8. After the selection, click on Set hyperlink and the Provision Connection Path Protected panel appears with the To: field filled with the previous setting.

9. In the Provision Connection Path Protected panel select the 2WAYSNCP item, by means of the combo-box associated to the Cross Connection Type: field or click on the Default hyperlink.

Optionally you can assign a label for the cross connection validating the SET Circuit Identifier check-box.

10. In the other fields of the Provision Connection Path Protected panel select the default values clicking on the Default hyperlink:

– Revertive Mode: = N (it indicates whether or not to make revert to protected once the protected comes into service and the traffic is on protecting). Possible values: Y (Yes revert to protected / FROMPED)

– Revert Delay Time [min]: = 5 (wait to restore time, if Revertive Mode =Y in minutes. If Revertive Mode=N it does not have any effect at the NE behavior.). Possible values: in the 0 to 15 range.

– Hold Off Time [millisec]: = 0 (time for automatic switching. The values are in milliseconds). Possible values: 0, 30, 50, 70, 100, 300, 500, 700, 1000, 3000, 5000, 10000 milliseconds.

– Protection Type: = SNCI (SubNetwork Connection Protection with Inherent monitoring). Other possibility is SNCN (SubNetwork Connection Protection with Non-intrusive monitoring).


........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

Unprotected Bidirectional XC between a Remote dataport (VC4-nV) and an STM-n port



............................................................................................................................................................................................................................................................

Unprotected Bidirectional XC between a Remote data port (VC4-nV) and an STM-n port

Purpose

The procedure is performed on a multiservice and SONET/SDH boards.




– Cross Connection Type: = Connection (it set a path protected cross-connection entity and establishes a one-way [unidirectional], two-way [bidirectional] cross connection between the specified facilities)

– VC Type: = e.g. VC416C it set the cross connection rate on which the command acts.

– Direction: = Starting From (it allows to establish the direction of the cross connection, actual the source point).


– If you know the identifications of the cross connection, select the source point (Starting From) by means of the combo-boxes whose represent, starting from the left to the right, the Rack, Shelf, Slot, Module, Interface. (e.g. VCGVC4-x-x-xx-x-x). Click on ADD button and it will be reported in the Access Identifier: field of the panel.

– If you don’t know the identifications of the cross connection, click on Start Tree Selection button. In the lower part of the windows a tree with the available boards for cross connection and a table with the details appears. Expand the tree for the board involved in the cross connection (e.g. PP10AD-x-x-xx: PP10MS) and in the right part the table with the available VCG facilities will be shown ( (e.g. VCGVC4-x-x-xx-x-xx). Click on it will be reported in the Access Identifier: field of the panel.

4. Click on Continue hyperlink and a window opens where it is possible to select the source point into the Specify a VC of type VC416C panel.

– If you know the identifications of the cross connection, select the destination point (Ending to) by means of the combo-boxes whose represent, starting from the left to the right, the Rack, Shelf, Slot, Module, Interface. (e.g. STM64AU4-x-x-xx-x-x). Click on ADD button and it will be reported in the Access Identifier: field of the panel.

Unprotected Bidirectional XC between a Remote dataport (VC4-nV) and an STM-n port



4-7

............................................................................................................................................................................................................................................................

– If you don’t know the identifications of the cross connection, click on Start Tree Selection button. In the lower part of the windows a tree with the available boards for cross connection and a table with the details appears. Expand the tree for the board involved in the cross connection (e.g. 10GSO-x-x-xx: 1P10GSOSO XFP-x-x-xx-x: XI-xxx STM64-x-x-xx-x) and in the right part the table with the available STM64 facilities will be shown ( (e.g. STM64AU4-x-x-xx-x-xx). Click on it will be reported in the Access Identifier: field of the panel.

5. Click on Set hyperlink and the Provision Cross Connection panel appears with the To: field filled with the previous setting.

6. In the Create Cross Connection panel select the 2WAY item, by means of the combo-box associated to the Cross Connection Type: field.

Optionally you can assign a label for the cross connection validating the SET From To Circuit Identifier check-box.


........................................................................................................................................................E N D O F S T E P S

............................................................................................................................................................................................................................................................

P2P XC between a local and a remote data portConnections, Configurations and Characteristics


............................................................................................................................................................................................................................................................

P2P XC between a local and a remote data port

Purpose

The procedure is performed on a data and multservice boards.

Basics Drawing

Figure 4-3 P2P XC between a local and a remote data port

Procedure

To perform this XC (cross-connection), it is required to configure a P2P connection between the local port (the access data board) and the remote port (the packet processor).

1. In order to made a cross-connection with a remote port involved, it is mandatory to create first a Virtual Concatenation Group (VCG) as follows:

a. Click on a MultiService board (e.g. PP10AD-x-x-xx:PP10MS).

b. Scroll down the Client area until the VCG Range panel is shown.

By means of the Minimum and Maximum VCG Index variable parameters, select the range of the VCG (from 1 to 124), and click on the Search hyperlink.

At the bottom of the Client area a table is added where are shown the main information about the previously selected range, as shown in the following picture.

c. Click on the provision hyperlink of the desired VCG-x-x-x-x, and the Create Virtual Concatenation Group panel appears.

PP10MS

local port

PP10GEPP1GE

remote port



4-9

............................................................................................................................................................................................................................................................

d. In the Create Virtual Concatenation Group panel select the useful parameters as follows:

– Max. Member Number: Indicates the number of VC members in the addressed VCG.

– VCG type: VC4

– Protocol Types: Indicates the protocol used for mapping data over SDH. GFP-F (GFP Framed). It allows a variable number of members belonging to VCG).

e. Click on Save.

f. The just created VCG group will appear at the bottom of the new window .

2. Click on the PHYSICAL tab and in the State panel of the Client area the Remote Port is shown (e.g. r_sr__sl__/ETHRemPort#_),

3. Set the Admin state to up in the State panel.

4. It is necessary then to create the local port: in the Tree area, click on a Data board (e.g. PP1GE-x-x-xx).

– Expand it till to the SFP or XFP module (e.g. SFP-x-x-xx-xx: ANY-DATAS) and the GE port (e.g. ),

– In the Client area, click on the PHYSICAL tab, in the State panel select the Administrative state field as up (e.g. ),

We have created the local port and the VCG in the remote port, now we have to create the P2P cross connection between the two ports.

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

5. Follow the Connection Ethernet P2P XC Create XC menu path.

The P2P data connection panel appears.

6. In this panel it is possible set a P2P cross-connection entity and establishes a bidirectional cross connection between the specified facilities.

a. Click on Select hyperlink of the From: field and a window opens showing the available resources in a tree format. Expand the tree, until the SFP module available port (e.g. PP1GE-x-x-xx SFP-x-x-xx-x: ANY-DATAS) where is available the r_sr__sl__/ETHLocPort#_#_ port. Click on it and the relevant local port is reported in the P2P data connection panel.

b. Click on Select hyperlink of the To: field and a window opens showing the available resources in a tree format. Expand the tree, until the SFP module available port (e.g. e.g. PP10AD-x-x-xx: PP10MS) where is available the r_sr__sl__/ETHRemPort#_ port. Click on it and the relevant remote port is reported in the P2P data connection panel.

7. Click on Save & Continue hyperlink

........................................................................................................................................................E N D O F S T E P S

XC in Provider scenarioConnections, Configurations and Characteristics


4-11

............................................................................................................................................................................................................................................................

XC in Provider scenario

Purpose

The procedure is performed on a data and multservice boards.

Basics Drawing

Figure 4-4 XC in Provider scenario

Procedure

To perform this kind of XC (cross-connection), it is required to configure an XC between the SVLAN (on the access data board) and the remote port (on the packet processor).

1. In order to made a cross-connection with a remote port involved, it is mandatory to create first a Virtual Concatenation Group (VCG) as follows:

a. Click on a MultiService board (e.g. PP10AD-x-x-xx:PP10MS).

b. Scroll down the Client area until the VCG Range panel is shown.

By means of the Minimum and Maximum VCG Index variable parameters, select the range of the VCG (from 1 to 124), and click on the Search hyperlink

At the bottom of the Client area a table is added where are shown the main information about the previously selected range, as shown in the following picture.

PP10MS

local port

PP10GEPP1GE

etb

remote port

ets

S-VLANUNI-NNINNI-UNIUNI-UNI

etb

etsXC

Local portetbetbetsets

Remote portetbetsetbets

connectionby means of:

S-VLANXCXCXC

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 4-5 VCG creation - 1

c. Click on the provision hyperlink of the desired VCG-x-x-x-x, and the Create Virtual Concatenation Group panel appears.

d. In the Create Virtual Concatenation Group panel select the useful parameters as follows:

– Max. Member Number: Indicates the number of VC members in the addressed VCG (e.g. 2)

– VCG type: VC4

– Protocol Types: Indicates the protocol used for mapping data over SDH. GFP-F (GFP Framed. It allows a variable number of members belonging to VCG).


e. Click on Save.

f. The just created VCG group will appear at the bottom of the new window, where it is necessary to set the parameters as follows:

– Activation State: = ACTIVE

– Number of Paths: = ALL

Click on Save hyperlink.



4-13

............................................................................................................................................................................................................................................................


g. Click on the PHYSICAL tab and in the State panel of the Client area the Remote Port is shown (e.g. r_sr__sl__/ETHRemPort#_). In the Ethernet Port panel, select the Client Type field as ets and set the Admin state to up in the State panel.

h. Now it is necessary creating the local port: in the Tree area, click on a Data board (e.g. PP1GE-x-x-xx).

– Expand it till to the SFP or XFP module (e.g. SFP-x-x-xx-xx: ANY-DATAS) and the GE port (e.g. ),

– In the Client area, click on the PHYSICAL tab, in the State panel select the Administrative state field as up (e.g. ),

2. Traffic Descriptor selection

a. Follow the Data Traffic Descriptor menu path. The relevant panel appears showing the list of all available Traffic descriptors (refer to the ZIC User Provisioning Guide for details.).

CAUTIONIf more then 1 VCG is required, it is necessary to set in the Modify Virtual Concatenation Group panel, the LCAS control field as Y, with VC members in Idle state.

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Figure 4-8 TD selection

b. Create a “guaranteed” TDs (e.g. GUARANTED and GUARANTEDNULL) with the parameter shown in Figure 4-8.

3. VLAN registration

a. Follow the Data Virtual LAN menu path. The relevant panel appears showing the list of all available VLAN., and register the ets ports in the Untagged Member Set.

4. XC creation (remote port)

Selecting the Provider Bridge Ethernet Services XC menu path the Client area will show the Figure 4-9 panel.

Figure 4-9 XC creation - 1

Click on Create hyperlink in order to perform the settings steps.

a. XC between ets remote port and SVLAN xx (UNI - NNI)

In the Client area shown in Figure 4-10, in the Create Provider Bridge service panel, select:

– UNI-NNI item in the Topology field.

– click on Select hyperlink of the Ingress field to open the selection window for UNI port (e.g. r_sr__sl__/ETHRemPort#_ as ets port). After the selection the port will be referred into the Ingress field.

– click on Select hyperlink of the S-VID field to open the selection window for Static VLAN identifier searching (e.g. S-VLAN 8). After the selection the identifier will be referred into the S-VID field.

In the Client area hown in Figure 4-10, in the ETS Flow to Provider Bridge section panel, select:

– GUARANTED item in the Traffic Descriptor field.



4-15

............................................................................................................................................................................................................................................................

– all the other fields are optional, leave the default value, i.e.: Topology Classifier = Default, Layer 2 control frames (0x): = FFFFFFFFFF, Policing Mode: = colorBlind, Color Profile: = the default value that appears and VLAN pop: field that allows to disable or enable the Customer TAG (CTAG) pop.


Then click on Save & continue hyperlink in order to set the egress port.

b. XC between SVLAN xx and ets remote port (NNI - UNI)

In the Client area shown in Figure 4-11, in the Create Provider Bridge service panel, select:

– NNI-UNI item in the Topology field.

– click on Select hyperlink of the Egress field to open the selection window for UNI port (e.g. r_sr__sl__/ETHRemPort#_). After the selection the port will be referred into the Egress field.

– click on Select hyperlink of the S-VID field to open the selection window for Static VLAN identifier (e.g. S-VLAN 8). After the selection the identifier will be referred into the S-VID field.

In the Client area shown in Figure 4-11, in the Provider Bridge to ETS Flow section panel, select:

– a “guaranteed” TD in the Traffic Descriptor field (e.g. GUARANTED NULL).

– the VLAN push: optional field allows to disable or enable the Customer TAG (CTAG).

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................


5. Click on Save & exit to confirm the settings.

6. Repeate the XC creation, but for local port (refer to Step 4).

Now the cross-connection is operative, and the test can be carried out (refer to “Provider Bridge VLAN switching test” (p. 3-39)).

........................................................................................................................................................E N D O F S T E P S

Procedure to enable and disable the ALSConnections, Configurations and Characteristics


4-17

............................................................................................................................................................................................................................................................

Procedure to enable and disable the ALS

Procedure

How to disable ALS

1. In the Tree Structure, select the board and expand it until the available SFP/XFP modules is displayed ( )

2. Select the involved module and click on it.

In the client area some functional tabs (according to the type of rate) appears.

3. Select the Physical folder (e.g. STMN/GBE for an SPF module)

4. In the first panel that appears in the client area, find the ALS Enabled field and, by means the combo-box, select the N (ALS disabled) option

........................................................................................................................................................E N D O F S T E P S

How to enable ALS

1. In the Tree Structure, select the board and expand it until the available SFP/XFP modules is displayed ( )


In the client area some functional tabs (according to the type of rate) appears.

3. Select the Physical folder (e.g. STMN/GBE for an SPF module)

4. In the first panel that appears in the client area, find the ALS Enabled field and, by means the combo-box, select the Y (ALS enabled) option

........................................................................................................................................................E N D O F S T E P S

DANGERWhen having to disconnect the Optical Fiber, follow the procedure stated below to avoid laser radiation. The triangle will indicate presence.

DANGERWhen ALS is disabled the LASER is always switched on.

DANGERWhen ALS is enabled the LASER immediately switch off. It restart after 120 seconds for 5 seconds.

............................................................................................................................................................................................................................................................

Procedure to manage a loopbackConnections, Configurations and Characteristics


............................................................................................................................................................................................................................................................

Procedure to manage a loopback

Basics

The loopbacks are settable onto the following boards:

• 10GSO: providing one STM64 optical port per module.

• 2G5SO: providing four STM16 optical ports per module.

• 8XSO: providing 8 STM1-4 optical ports per module.

• PP1GE: providing 10 SFP ports per module that can be 1GE optical.

• PP10GE: providing 1 XFP port per module that can be 10GE optical.

• 10xANY: providing 10 SFP ports per module that can be STM1, STM4, STM16, 1GE optical.

• OT2TDM: providing 1 MSA (300pin) port per module that can be 10G DWDM colored.

• CWLA: providing four STM16 optical ports per module (two line side and two client side).

• DWLA10X: providing 1 XFP port on client side that can be STM64 or OTU-2 or 10GE; providing 1 XFP port (colored) on line side that can be OTU-2.

• 11GxAR: providing 1 XFP port on client side that can be STM64 or OTU-2 or 10GE or 10GFC; providing 1 TUNABLE MSA port on line side.

The following I/O optical port are supported:

SFP/XFP Type Function

SS-11 SFP Module Short Haul STM1 (λ 1310) B&W

SL-11 SFP Module Long Haul STM1 (λ 1310) B&W


SS-41 SFP Module Short Haul STM4 (λ 1310) B&W



SI-161 SFP Module Intraoffice STM16 (λ 1310) B&W

SS-161 SFP Module Short Haul STM16 (λ 1310) B&W (SDH card)

SL-161 SFP Module Long Haul STM16 (λ 1310) B&W (SDH card)

SL-162 SFP Module Long Haul STM16 (λ 1550) B&W (SDH card)

SS-161AR SFP Module Short Haul STM16 (λ 1310) B&W Any Rate (SDH card)

SS-162C SFP Modules Short Haul STM16 (λ 1550) B&W CWDM PIN

1000BSX-MMF SFP Module Short Haul Gigabit Ethernet



4-19

............................................................................................................................................................................................................................................................

Refer to “SFP and XFP modules” (p. 4-21) for detailed information about the I/O optical/electrical port.

Procedure

How to set a loopback

1. In the Tree Structure, select the board and expand it until the available I/O optical port (SFP, XFP or MSA) modules is displayed ( )


In the client area some panels (according to the type of rate) appear.

3. Scroll down the client area until the Loopback panel is shown.

4. In the panel, by means the Loopback Type combo-box, it is possible to choice (according the resource type):

– FACILITY = loopback where the signal received at the port (port ingress direction) is connected to the transmit side of the port.

– TERMINAL = loopback where the signal that is about to be transmitted (port egress direction) is connected to the receive side of the port.

The default value is FACILITY.

5. After the choice, click on Operate Loopback hyperlink that allows to establish a near-end facility or terminal loopback on the specified resource facility.

........................................................................................................................................................E N D O F S T E P S

How to disable a loopback

1. In the Tree Structure, select the board and expand it until the available I/O optical port (SFP, XFP or MSA) modules is displayed ( )


In the client area some panels (according to the type of rate) appear.

1000BLX-SMF SFP Module Long Haul Ethernet

1000BZX-SMF SFP Module Extra Long Haul Gigabit Ethernet

XI-641 XFP Module Intraoffice STM64 (λ 1310) B&W

XS-642 XFP Module Short Haul STM64 (λ 1550) B&W

XL-642C XFP Module Long Haul STM64 (λ 1550) DWDM Coloured

XP1L12D2 XFP Module Long Haul P1L1-2D2 interface (λ 1550)

10GEBaseSR XFP 10Gigabit Ethernet

SFP/XFP Type Function

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

3. Scroll down the client area until the Loopback panel is shown.

4. The panel refers about the actual loopback

5. Click on Release Loopback hyperlink that allows to release a near-end facility or terminal loopback on the specified resource facility.

........................................................................................................................................................E N D O F S T E P S

SFP and XFP modulesConnections, Configurations and Characteristics


4-21

............................................................................................................................................................................................................................................................

SFP and XFP modules

B&W SFP modules optical characteristics

Table 4-1 B&W STM-1 SFPs: optical interfaces characteristics

Note 1: if SLM LASER

Note 2: if MLM LASER

STM-1 SFP module type S.1.1 L.1.1 L.1.2 UnitDigital signal STM-1 compliant with G.707 and G.958Addressed wavelength 1261 -> 1360 1270 -> 1360 1480 -> 1580 nmMin. launched power -15 -5 -5 dBmMax. launched power -8 0 0 dBmAllowed bit rates 155.520 MbpsMin. extinction ratio (dB) 8.2 10 10 dBSpectral width

Max. -20dB bandwidth (nm) NA 1 (Note 1) 1 nmMax. RMS width (nm) 7.7 3 (Note 2) NA nm

Minimum SMSR NA 30 if SLM laser 30Max. chromatic dispersion -100 -> +100 -250 -> +250 1900 ps/nmMin. sensitivity, @ BER=1-10 -28 -34 -34 dBmMin. overload -8 -10 -10 dBmMax. optical path penalty 1 1 1 dBMax. receiver reflectance -14 -14 -25 dBOptical connector (Tx/Rx) LC LC LCFiber type SMF SMF SMFAcronym SS-11 SL-11 SL-12

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 4-2 B&W STM-4 SFPs : optical interfaces characteristics

Table 4-3 B&W STM-16 SFPs : optical interfaces characteristics

STM-4 SFP module type S.4.1 L.4.1 L.4.2 UnitDigital signal STM-4 compliant with G.707 and G.958Addressed wavelength 1274 -> 1355 1280 -> 1335 1480 -> 1580 nmMin. launched power -15 -3 -3 dBmMax. launched power -8 +2 +2 dBmAllowed bit rates 622.080 MbpsMin. extinction ratio (dB) 8.2 10 10 dBSpectral width

Max. -20dB bandwidth (nm) NA 1 1 nmMax. RMS width (nm) 2.5 NA NA nm

Minimum SMSR NA 30 30Max. chromatic dispersion -100 -> +100 -250 -> +250 1900 ps/nmMin. sensitivity, @ BER=1-10 -28 -28 -28 dBmMin. overload -8 -8 -8 dBmMax. optical path penalty 1 1 1 dBMax. receiver reflectance -14 -14 27 dBOptical connector (Tx/Rx) LC LC LCFiber type SMF SMF SMFAcronym SS-41 SL-41 SL-42

STM-16 SFP module type I.16.1 S.16.1 UnitDigital signal STM-16 compliant with G.707 and G.958Addressed wavelength 1270 -> 1360 1270 -> 1360 nmMin. launched power -10 -5 dBmMax. launched power -3 0 dBmAllowed bit rates 2.48832 GbpsMin. extinction ratio (dB) 8.2 8.2 dBSpectral width

Max. -20dB bandwidth (nm) NA 1 nmMax. RMS width (nm) 4 NA nm

Minimum SMSR NA 30Max. chromatic dispersion -12 -> +12 -100 -> +100 ps/nmMin. sensitivity, @ BER=1-10 -18 -18 dBmMin. overload -3 0 dBmMax. optical path penalty 1 1 dBMax. receiver reflectance -27 -27 dBOptical connector (Tx/Rx) LCFiber type SMFAcronym SI-161 SS-161



4-23

............................................................................................................................................................................................................................................................

Table 4-4 B&W STM-16 SFPs: long-haul optical interfaces characteristics

Table 4-5 B&W multi-rate multi-format SFP: optical interfaces characteristics

STM-16 SFP module type L.16.1 L.16.2 UnitDigital signal STM-16 compliant with G.707 and G.958Addressed wavelength 1280 -> 1335 1500 -> 1580 nmMin. launched power -2 -2 dBmMax. launched power +2 +2 dBmAllowed bit rates 2.48832 GbpsMin. extinction ratio (dB) 8.2 8.2 dBSpectral width

Max. -20dB bandwidth (nm) 1 1 nmMax. RMS width (nm) NA NA nm

Minimum SMSR 30 30Max. chromatic dispersion -250 -> +250 +1600 ps/nmMin. sensitivity, @ BER=1-10 -27 -28 dBmMin. overload -8 -8 dBmMax. optical path penalty 1 2 dBMax. receiver reflectance -27 -27 dBOptical connector (Tx/Rx) LCFiber type SMFAcronym SL-161 SL-162

Multirate SFP parameters S-16 multirate multiformat UnitAddressed wavelength 1290 -> 1330 nmMin. launched power -5 dBmMax. launched power 0 dBmAllowed bit rates 100 -> 2700 Mbps

Min. extinction ratio (dB)for bit rates > 2.125 Gbps = 8.2

for bit rates < 2.125 Gbps = 9.0dB

Spectral width

Max. -20dB bandwidth (nm) 1 nmMax. RMS width (nm) NA nm

Minimum SMSR 30Max. chromatic dispersion -100 -> +100 ps/nmMin. sensitivity, @ BER=1-10 -18 dBmMin. overload 0 dBmMax. optical path penalty 1 dBMax. receiver reflectance -27 dBOptical connector (Tx/Rx) LCFiber type SMFAcronym SS-161AR

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 4-6 B&W GE SFPs: optical interfaces characteristics

GbE SFP module type 1000Base-SX1000Base -

LX/LH 1000Base-ZX UnitDigital signal Gigabit Ethernet compliant with IEEE 802.3Addressed wavelength 820 -> 860 1270 -> 1355 1540->1570 nmMin. launched power -9.5 -11 0 dBmMax. launched power -4 -3 +5 dBmAllowed bit rates 1.250 1.250 1.250 GbpsMin. extinction ratio (dB) 9 9 9 dBSpectral width

Max. -20dB bandwidth NA NA 1 nmMax. RMS width 0.85 4 NA nm

Minimum SMSR NA NA 30Max. chromatic dispersion - - +1200 ps/nmMin sensitivity @BER=1-10 -17 -19 -24 dBmMin. overload 0 -3 0 dBmMax. optical path penalty - - 2 dBMax. receiver reflectance -12 -12 -12 dBOptical connector (Tx/Rx) LC LC LC

Fiber type

50/125 μm MMF 550m

62.5/125 μm MMF - 275m

9/125 μm SMF 10km

50/125 μm MMF 550m

62.5/125 μm MMF - 550m

9/125 μm SMF

Acronym 1000B 1000B 1000B



4-25

............................................................................................................................................................................................................................................................

CWDM SFP modules optical characteristics

Table 4-7 CWDM multi-rate (2100 to 2700 Mbps) SFPs optical interfaces characteristics

CWDM SFP parametersAPD CWDM

for long haul (ITU-T G.695 C8L1-1D2)

PIN CWDM

for short haul (ITU-T G.695 C8S1-1D2)

Unit

Addressed wavelength1471, 1491, 1511, 1531, 1551, 1571, 1591, 161

compliant with ITU-T G.694.2nm

Min. launched power 0 0 dBmMax. launched power +5 +5 dBmAllowed bit rates 2 -> 2700 2 -> 2700 MbpsMin. extinction ratio 8.2 8.2 dBMax. -20dB bandwidth 1 1 nmMinimum SMSR 30 30 dB

Max. chromatic dispersion

1600 @ 1611 nm1600 @ 1591 nm1500 @ 1571 nm1400 @ 1551 nm1400 @ 1531 nm1300 @ 1511 nm1200 @ 1491 nm1100 @ 1471 nm

1000 @ 1611 nm900 @ 1591 nm900 @ 1571 nm900 @ 1551 nm800 @ 1531 nm800 @ 1511 nm700 @ 1491 nm700 @ 1471 nm

ps/nm

Min. sensitivity, @ BER=1-10 -28 -18 dBmMin. overload -9 0 dBmMax. optical path penalty 2 1 dBMax. receiver reflectance -27 -27 dBOptical connector (Tx/Rx) LC LCFiber type SMF SMFAcronym SL-162C SS-162C

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

B&W XFP modules optical characteristics

Table 4-8 B&W 10G XFPs: optical interfaces characteristics

10G XFP parameters 10GE Base-S I-64.1 / 10GE Base-L Unit

Digital signalSTM-64 compliant with G.707 and G.958

10 Gigabit Ethernet compliant with IEEE 802.3 (10GB only)Addressed wavelength 840 -> 860 1290 -> 1330 nmMin. launched power -7.3 -6.0 dBmMax. launched power -1.0 -1.0 dBm

Allowed bit rates 9.95328; 10.3125; 10.5199.95328; 10.3125; 10.709225;

10.519Gbps

Min. extinction ratio 3.0 6.0 dBSpectral width: Max. -20dB bandwidth

See IEEE 802.3ae Triple Tradeoff Curves (TTC)

1.0 nm

Minimum SMSR - 30Max. chromatic dispersion - 60 ps/nmMin. sensitivity, @ BER=1-12 -9.9 -11 dBmStressed sensitivity -7.5 - dBmMin. overload -1.0 0.5 dBmMax. optical path penalty - 1.0 dBMax. receiver reflectance -12 -14 dBOptical connector (Tx/Rx) LC LCFiber type MMF SMFAcronym 10GB XI641



4-27

............................................................................................................................................................................................................................................................

Table 4-9 B&W 10G long-haul XFPs: optical interfaces characteristics

10G XFP parameters S-64.2b/10GE Base-E P1L1-2D2 Unit

Digital signalSTM-64 compliant with G.707 and G.958

10 Gigabit Ethernet compliant with IEEE 802.3 (XS642 only)Addressed wavelength 1530 -> 1565 1530 -> 1565 nmMin. launched power -1.0 0 dBmMax. launched power +2.0 +4.0 dBmAllowed bit rates 9.95328; 10.3125; 10709 GbpsMin. extinction ratio 8.2 9.0 dBSpectral width: Max. -20dB bandwidth

0.25 0.25 nm

Minimum SMSR 30 30 dBMax. chromatic dispersion 800 1600 ps/nmMin. sensitivity, @ BER=1-12 -14 -24 dBmMin. overload -1.0 -7.0 dBmMax. optical path penalty 2 2 dBMax. receiver reflectance -27 -27 dBOptical connector (Tx/Rx) LC LCFiber type SMF SMFAcronym XS642 XP1L12D2

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

DWDM XFP modules optical characteristics

Table 4-10 DWDM 10G XFPs: optical interfaces characteristics

10G XFP parameters APD DWDM Unit

Addressed wavelength1529,55 (196.00 THz) -> 1561,42 (192.00 THz)

100 GHz grid, compliant with ITU-T G.694.1nm

Min. launched power -2.0 dBmMax. launched power +3.0 dBmMaximum wavelength deviation EOLMax launched power

+/- 100 nm

Allowed bit rates 9.95328; 10.3125; 10.709; 11.095728 GbpsMin. extinction ratio 9.0 dBSpectral width: Max. -20dB bandwidth

+/- 8 GHz

Minimum SMSR 30Max. chromatic dispersion 1600 ps/nm

Min. sensitivity, @ BER=1-4

without ASE noise

-25 @ 1300 ps/nm

-23 @ 1600 ps/nmdBm

OSNR @ BER=1-417 @ 1300 ps/nm

19 @ 1600 ps/nmdB

Min. sensitivity, @ BER=1-12 up to 10.3125 Gbps

-22 @ 1300 ps/nm dBm

Min. OSNR sensitivity, @ BER=1-12 up to 10.3125 Gbps

25 @ 1300 ps/nm-23 dBm

Min. overload -8.0 dBmMax. optical path penalty - dBMax. receiver reflectance -12 dBOptical connector (Tx/Rx) LCFiber type SMFAcronym XL-642C

CWDM mux/demuxConnections, Configurations and Characteristics


4-29

............................................................................................................................................................................................................................................................

CWDM mux/demux

Table 4-11 1-Channel OADM w/o and w/ supervision: CADM1 and CADM1S

General Characteristics

Number of channels that can be add/drop per board:

One channel among the following λ:

• 1471 nm, 1491 nm, 1511 nm, 1531 nm,

• 1551 nm, 1571 nm, 1591 nm, 1611 nm

Fiber type 9/125 m SMF

Connector type MU horizontal

Isolation (adjacent channels) Min. 40 dB

Isolation (non-adjacent channels) Min. 45 dB

PDL Max. 0.25 dB

OADM MUX general scheme OADM DEMUX general scheme

Mux (Add) side insertion losses CADM1 CADM1SCh N (N = 1 to 8) Added to the aggregate (CWDM Line OUT) signal 1.0 dB 1.3 dB

Pass-through (Express) channels Added to the aggregate (CWDM Line OUT) signal

0.8 dB 1.5 dB

OSC channel (1311nm) Added to the aggregate (CWDM Line OUT) signal 1.0 dB

Demux (Drop) side insertion losses CADM1 CADM1SCh N (N = 1 to 8) Dropped from the aggregate (CWDM Line IN) signal 1.5 dB 2.2 dB

Pass-through (Express) channels Dropped from the aggregate (CWDM Line OUT) signal

1.3 dB 2.0 dB

OSC channel (1311nm) Dropped from the aggregate (CWDM Line OUT) signal

1.5 dB

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................




Two channels among the following pairs of λ:

• 1471 nm and 1491 nm

• 1511 nm and 1531 nm

• 1551 nm and 1571 nm

• 1591 nm and 1611 nm





PDL Max. 0.25 dB

OADM MUX general scheme see Table 4-11, (pg. 4-29)

Mux (Add) side insertion losses CADM2 CADM2SCh 1 Added to the aggregate (CWDM Line OUT) signal 1.3 dB 2.0 dB

Ch 2 Added to the aggregate (CWDM Line OUT) signal 1.3 dB 2.0 dB


1.0 dB 1.7 dB


Demux (Drop) side insertion losses CADM1 CADM1SCh 1 Dropped from the aggregate (CWDM Line IN) signal 1.8 dB 2.5 dB

Ch 2 Dropped from the aggregate (CWDM Line IN) signal 1.8 dB 2.5 dB


1.5 dB 1.7 dB


1.5 dB



4-31

............................................................................................................................................................................................................................................................




Four channels:

• 1471 nm, 1491 nm, 1511 nm and 1531 nm

• 1551 nm, 1571 nm, 1591 nm and 1611 nm





PDL Max. 0.25 dB

OADM MUX general scheme see Table 4-11, (pg. 4-29)

Mux (Add) side insertion losses CADM2 CADM2SCh 1 Added to the aggregate (CWDM Line OUT) signal 0.9 dB 1.6 dB





1.7 dB 2.4 dB


Demux (Drop) side insertion losses CADM1 CADM1SCh 1 Dropped from the aggregate (CWDM Line IN) signal 2.3 dB 3.0 dB





2.2 dB 2.9 dB


1.5 dB

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 4-14 8-Channel MUX/DEMUX w/o and w/ supervision: CMDX8 and CMDX8S

General CharacteristicsChannels number 8

Channels wavelength (1 to 8)1471 nm, 1491 nm, 1511 nm, 1531 nm,

1551 nm, 1571 nm, 1591 nm, 1611 nm





PDL Max. 0.25 dB

MUX general scheme DEMUX general scheme

Mux (Add) side insertion losses CMDX8 CMDX8SCh 1 Added to the aggregate (CWDM Line OUT) signal 0.9 dB 1.6 dB








Channel passband at -0.5dB (include channel centre wavelength in -6 / +8 range)

14 dB 14 dB


Demux (Drop) side insertion losses CMDX8 CMDX8SCh 1 Dropped from the aggregate (CWDM Line IN) signal 1.4 dB 2.1 dB








4-33

............................................................................................................................................................................................................................................................



Channel passband at -0.5dB (include channel centre wavelength in -6 / +8 range)

14 dB 14 dB


1.5 dB

Mux (Add) side insertion losses CMDX8 CMDX8S

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 4-15 2-Channel MUX/DEMUX w/ supervision: CMDX2S


Channels wavelength per board

Two channels among the following pairs of λ :

• 1471 nm and 1491 nm

• 1511 nm and 1531 nm

• 1551 nm and 1571 nm

• 1591 nm and 1611 nm

Fiber type 9/125 μm SMF




PDL Max. 0.25 dB

CMDX MUX and DEMUX general scheme see Table 4-14, (pg. 4-32)

Mux (Add) side insertion lossesCh 1 Added to the aggregate (CWDM Line OUT) signal 2.0 dB

Ch 2 Added to the aggregate (CWDM Line OUT) signal 2.0 dB

Channel passband at -0.5dB (include channel centre wavelength in -6 / +8 range) 14 dB


Demux (Drop) side insertion lossesCh 1 Dropped from the aggregate (CWDM Line IN) signal 2.5 dB

Ch 2 Dropped from the aggregate (CWDM Line IN) signal 2.5 dB

Channel passband at -0.5dB (include channel centre wavelength in -6 / +8 range) 14 dB

OSC channel (1311nm) Dropped from the aggregate (CWDM Line OUT) signal 1.5 dB



4-35

............................................................................................................................................................................................................................................................

Table 4-16 1-Channel MUX/DEMUX w/ supervision: CMDX1S


Channels wavelength per board

One channels among the following pairs of λ :

• 1471 nm, 1491 nm, 1511 nm, 1531 nm, 1551 nm, 1571 nm, 1591 nm, 1611 nm



PDL Max. 0.25 dB

CMDX MUX and DEMUX general scheme see Table 4-14, (pg. 4-32)

Mux (Add) side insertion lossesCh 1 Added to the aggregate (CWDM Line OUT) signal 1.1 dB


Demux (Drop) side insertion lossesCh 1 Dropped from the aggregate (CWDM Line IN) signal 2.1 dB

OSC channel (1311nm) Dropped from the aggregate (CWDM Line OUT) signal 1.5 dB

............................................................................................................................................................................................................................................................

DWDM mux/demuxConnections, Configurations and Characteristics


............................................................................................................................................................................................................................................................

DWDM mux/demux

Table 4-17 OMDX8100: 8-channel mux/demux

Note: With respect to the band nominal centre frequency

General CharacteristicsChannels number 8



Tributary channels frequencies and wavelengths (1 to 8) - L1 Band

1553.33 nm (193,000 THz), 1552.52 nm (193,100 THz), 1551.72 nm (193,200 THz), 1550.92 nm (193,300 THz), 1549.32 (193,500 THz), 1548.51 (193,600 THz), 1547.72 nm (193,700 THz), 1546.92 nm (193,800 THz)

End-to-end single channel insertion loss

7.65 dB max

Polarization dependent loss 0.30 dB max, within the channel pass band

Polarization mode dispersion 0.30 ps max, within the channel pass band

Return Loss 40 dB min, including connectors, ports terminated

Mux side insertion lossesInput power -27 -> +15 dB, at one tributary input

Insertion Loss

• Single channel

• Extra Band

4.7 dB max

2.4 dB max, across all channel centres

Net bandwidth @ -0.5 dB 45 GHz (see Note: )


Channel pass band 44 GHz

Demux side insertion lossesInput power -25 -> +15 dB, at one tributary input

Insertion Loss

• Single channel

• Extra Band

4.15 dB max

2.4 dB max, across all channel centres



Adjacent channel isolation 23 dB (see Note: )

Non-Adjacent channel isolation 30 dB (see Note: )

Directivity 40 dB, including connectors


EC320 card front viewConnections, Configurations and Characteristics


4-37

............................................................................................................................................................................................................................................................

EC320 card front view

Figure 4-12 EC320 card (Equipment Controller) - front view

LEGEND:

1. BOARD STATUS MULTI COLOR LED:

LED OFF: card inserted and not runningAMBER BLINK: FPGA downloadGREEN BLINK: SW boot/self testGREEN: CARD provisioned and running RED: card failRED BLINK: card miss-configured or card mismatch

2. EPS MULTI COLOR LED:

GREEN: eps configured - card activeAMBER: eps configured - card stand- byAMBER LINK: eps configured but not availableOFF: eps not configured

3. RESET COMMAND KEY

4. 10/100 ETH DEBUG RJ45 CONNECTOR - factory use only

5. GREEN LED ON: full duplex

GREEN LED OFF: half duplex6. YELLOW LED ON: link/active (no activity)

YELLOW LED BLINK: link/active (with activity)YELLOW LED OFF: no link

7. RS232 on μUSB DEBUG CONNECTOR - factory use only

8. LOCAL CRAFT TERMINAL μUSB CONNECTOR (F interface)

9. LOCAL CRAFT TERMINAL CONNECTOR (RS232 F interface)

10. USB INTERFACE for external memory device

11. ALARM CUT-OFF KEY

12. LAMP TEST KEY

13. RED LED - critical alarm

14. RED LED - major alarm

15. ORANGE LED - minor alarm

16. ORANGE LED - warning alarm

17. RED LED - attended alarm

18. ORANGE LED - abnormal condition

R

AT AB

C M

mW

DBG

1

23

4

56

7

8

9

10

1112

1314

1516

1817

............................................................................................................................................................................................................................................................

MT320/MT320LO or MT160/MT160LO card front viewConnections, Configurations and Characteristics


............................................................................................................................................................................................................................................................

MT320/MT320LO or MT160/MT160LO card front view

Figure 4-13 MT320/MT320LO or MT160/MT160LO card - front view

LEGEND:

(1) EPS Multi color LED:

GREEN: EPS configured - Card ActiveAMBER: EPS configured - Card Stand-byAMBER BLINK: EPS configured but not availableSWITCHED OFF: EPS not configured

(2) BOARD STATUS Multi color LED:

LED OFF: card inserted and not runningAMBER BLINK: FPGA downloadGREEN BLINK: SW boot/self testGREEN: CARD provisioned and running RED: card failRED BLINK: card miss-configured or card mismatch

(3) Shelf Controller Restart Command Key

(4) μUSB DEBUG connector - Factory use only

(5) RJ45 DEBUG connector - Factory use only

(6), (9), (12) GREEN LED ON: link/active (no activity)

GREEN LED BLINK: link/active (with activity)GREEN LED OFF: no link

(7), (10), (13) YELLOW LED ON: full duplex

YELLOW LED OFF: half duplexYELLOW LED BLINKING: collision

(8) 10/100 Mbit/s Q3 interface

(11) 10/100 Mbit/s redundant Q3 interface

(14) (17) ETH/FETH/GETH interface for Drop Shelf connection

(15) (18) Multi color LED:

LED OFF: no linkGREEN LED BLINK: 10/100 Mb/s link active (with activity)ORANGE LED ON: 1000 Mb/s link active (no activity)ORANGE LED BLINK: 1000 Mb/s link active (with activity)GREEN LED ON: 10/100 Mb/s link active (no activity)

(16) (19) YELLOW LED ON: full duplex

YELLOW LED OFF: half duplexYELLOW LED BLINKING: collision

R

DBG

1

2

1

2

LNKACTM

FDXCOL

LNKACTM

FDXCOL

LNKACTDSFDXCOL

LNKACTDSFDXCOL

1

2

3

4

5

11

8

14

17

67

910

1213

1516

1819


............................................................................................................................................................................................................................................................


Overview

Purpose

This chapter provides detailed test report sheet modules for the Alcatel-Lucent 1850 TSS-320 and TSS-160.

Contents.

The chapter contains the following topics:.

“Equipment acceptance sheet” (p. 5-2)

............................................................................................................................................................................................................................................................

Equipment acceptance sheetAlcatel-Lucent 1850 TSS-320 and TSS-160 Test Report


............................................................................................................................................................................................................................................................

Equipment acceptance sheet

Acceptance sheet

Table 5-1 Equipment acceptance sheet

EQUIPMENT ACCEPTANCE SHEET

CONTRACT N.

SITE

RING

EQUIPMENT 1850 TSS-320 1850 TSS-160

LOCATION Row ________ / Rack ________ / Subrack _____

SW Version

Addresses

AFI IDI VER AUTH RES DOM AREA

Local

SYSTEM ID ETHERNET ADDRESS

IP ADDRESS

FINAL TESTING RESULT OK KO

Note __________________________________________________

__________________________________________________

__________________________________________________

__________________________________________________

__________________________________________________

__________________________________________________

Date __ / ______________ / ____

For Customer Signature

For Alcatel-Lucent Signature



5-3

............................................................................................................................................................................................................................................................

Table 5-2 On-Site 1850 TSS-320 Final Test

Note: Please refer to Figure 3-1, “Common boards and connection points position for 1850 TSS-320” (p. 3-6).

Boards Types Serial NumbersSHELF SERIAL NUMBERSLOT 1SLOT 2SLOT 3SLOT 4SLOT 5SLOT 6SLOT 7SLOT 8SLOT 9SLOT 10SLOT 11SLOT 12SLOT 13SLOT 14SLOT 15SLOT 16SLOT 17SLOT 18SLOT 19SLOT 20SLOT 21SLOT 22SLOT 23SLOT 24SLOT 25SLOT 26SLOT 27SLOT 28SLOT 29SLOT 30SLOT 31SLOT 32SLOT 33SLOT 34SLOT 35SLOT 36SLOT 37SLOT 38SLOT 39SLOT 40SLOT 41

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 5-3 On-Site 1850 TSS-160 Final Test

Note: Please refer to Figure 3-2, “Common cards and connection points position for 1850 TSS-160” (p. 3-9).

boards Types Serial NumbersSHELF SERIAL NUMBERSLOT 1SLOT 10SLOT 11SLOT 12SLOT 13SLOT 14SLOT 15SLOT 16SLOT 17SLOT 18SLOT 19SLOT 20SLOT 29SLOT 30SLOT 31SLOT 32SLOT 33SLOT 34SLOT 35SLOT 36SLOT 37SLOT 38SLOT 39SLOT 40SLOT 41



5-5

............................................................................................................................................................................................................................................................

Table 5-4 On-Site 1850 TSS-320/160 Final Test: SDH Local Measurements

Measure Expected Value and Tolerance

Measure Value Unit

Free-running frequency check 2048 + 4.6 ppm kHz

SDH/SONETOptical ports test

Port Nr

Port type/slot

Interfacetype

Expected Value and Tolerance

Measure Value

PTx power test

1

See “SFP and XFP modules” (p. 4-21)

dBm

ALS check CheckTest error-free data transit

0 errors Errors

PTx power test

2


dBm

A.L.S. check CheckTest error-free data transit

0 errors Errors

PTx power test

3


dBm


0 errors Errors

PTx power test

4


dBm


0 errors Errors

PTx power test

5


dBm


0 errors Errors

PTx power test

6


dBm


0 errors Errors

PTx power test

7


dBm


0 errors errors

PTx power test

8


dBm


0 errors errors

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 5-5 On-Site 1850 TSS-320/160 Final Test: Data Local Measurements

MeasureExpected Value and Tolerance

Measure Value Unit

DATAOptical ports test Port Nr

Port type/ slot

Interfacetype

Alarms check1

CheckTest error-free data transit 0 errors ErrorsAlarms check

2Check

Test error-free data transit 0 errors ErrorsAlarms check

3Check


4Check


5Check


6Check


7Check


8Check


9Check


10Check

Test error-free data transit 0 errors Errors

Alarms check1

CheckTest error-free data transit 0 errors ErrorsAlarms check

2Check


3Check


4Check


5Check


6Check


7Check


8Check


9Check


10Check

Test error-free data transit 0 errors Errors



5-7

............................................................................................................................................................................................................................................................

Table 5-6 On-Site 1850 TSS-320/160 Final Test: CWDM Local Measurements


Measured Value Units

CWDM Optical Ports TestPort NR

Port Type/Slot

Interface Type

PTx power test(on CWDM SFP output)

1 See “SFP and XFP modules” (p. 4-21)

dBm



dBm



dBm



dBm



dBm



dBm



dBm



dBm

CH 47 insertion loss on CMDX/CADM (MUX side)

1 See “CWDM mux/demux” (p. 4-29)

dB



dB



dB



dB



dB



dB



dB



dB

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 5-7 On-Site 1850 TSS-320/160 Final Test: CWDM Link Measurements



CWDM Optical Ports TestPort NR / λ

Port Type/Slot

Interface Type

Line signal output power - (ODF) See “CWDM mux/demux” (p. 4-29)

dBm

Span loss BOL (Customer power budget)

dB

Line signal input power - (ODF) See “CWDM mux/demux” (p. 4-29)

dBm

CH 47 insertion loss on CMDX/CADM (DEMUX side)


dB



dB



dB



dB



dB



dB



dB



dB

PRx power test(on CWDM SFP input)


dBm



dBm



dBm



dBm



dBm



dBm



dBm



5-9

............................................................................................................................................................................................................................................................



dBm

Stability Test 12 h

Stability Test 10 minutes per Gbit



CWDM Optical Ports TestPort NR / λ

Port Type/Slot

Interface Type

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 5-8 On-Site 1850 TSS-320/160 Final Test: DWDM Local Measurements



DWDM Optical Ports Test

Port NR

Port Type/Slot

Interface Type

PTx power test(on DWDM XFP output)


dBm



dBm



dBm



dBm



dBm



dBm



dBm



dBm

CH 30 insertion loss on OMDX8100 (MUX side)

1 See “DWDM mux/demux” (p. 4-36)

dB



dB



dB

CH 33 insertion loss on OMDX8100(MUX side)


dB



dB



dB



dB



dB



5-11

............................................................................................................................................................................................................................................................

Table 5-9 On-Site 1850 TSS-320/160 Final Test: DWDM Link Measurements


Measured Value Unit

DWDM Optical Ports TestPort Nr

Port Type/Slot

Interface Type

Line signal output power - (ODF)

See “CWDM mux/demux” (p. 4-29)

dBm

Span loss BOL (Customer power budget)

dB

CH 30 insertion loss on OMDX8100 (DEMUX side)


dB



dB



dB



dB



dB



dB



dB



dB

PRx power test(on DWDM XFP input)


dBm



dBm



dBm



dBm



dBm



dBm



dBm



dBm

Stability Test 12 hStability Test 10 minutes per Gbit

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Table 5-10 On-Site Multiservice Node Final Test: Local Measurements

Table 5-11 On-Site Node Final Test: House keeping (not available in Rel. 3.0)

MeasureExpected Value and Tolerance Check

Measured Value Unit

Matrix checkQuantity of matrix boards N

0 errors Errors

SNCP protection check (Line ports) Check

Matrix EPS protections check Check

Synchronism priority and Holdover Check

Alarm check (if connected)

Primary power supply alarms check Check

ON-SITE MULTISERVICE NODE FINAL TEST: LOCAL MEASUREMENTS


Measured Value Unit

Housekeeping alarms check:

CPI 1 (HK-IN 1) check








CPO 1 (HK-OUT 1) check






5-13

............................................................................................................................................................................................................................................................

Table 5-12 On-Site Multiservice Node Final Test: Point-to-Point Measures

SITE 1

SITE 2

EQUIPMENT TYPE

EQUIPMENT RELEASE

MeasureExpected value and tolerance

Measured value Unit

Rx optical “line port” power check

PORT N° TYPE Expected value = Remote PTx – Theoretical line attenuation based on customer data

dBm



dBm



dBm



dBm


PORT N° TYPE Margin level must be min. 4 dB better than the values reported in “SFP and XFP modules” (p. 4-21)

dBm



dBm



dBm



dBm

E O W checkPoint to point error monitoring check 0 Errors errors

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

A-1P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

A Technical support

Overview

Purpose

This chapter provides important technical assistance information for the Alcatel-Lucent 1850 Transport Service Switch 320 and 160 (Alcatel-Lucent 1850 TSS-320 and TSS-160).

Contents

This appendix contains the following sections

“Technical assistance” (p. A-2)

“Accessing and navigating the On-Line Customer Support (OLCS) web site” (p. A-7)

“Other technical support services” (p. A-12)

............................................................................................................................................................................................................................................................

Technical assistanceTechnical support

A-2 P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

Technical assistance

Overview

Alcatel-Lucent provides the following Technical Support Services:

• Remote Technical Support (RTS) - remote technical support to troubleshoot and resolve system problems.

• On-site Technical Support (OTS) - on-site assistance with operational issues and remedial maintenance.

• Repair and Replacement (R&R) - technical support services for device repair/return or parts replacement.

• Alcatel-Lucent On-Line Customer Support (OLCS) - online access to information and services that can help resolve technical support requests.

Note: Technical Support Services are available 24 hours a day, 7 days a week.

For additional information regarding Alcatel-Lucent Worldwide Services, refer to the Alcatel-Lucent web site at http://www.alcatel-lucent.com/solutions.

Select the appropriate category:

• Service Providers

• Enterprise

Note: Use the appropriate steps below for the above categories.

Service Providers:

1. Select Service Providers.

2. Select Services.

3. Select Network Support and Maintenance Services located in the Maintenance section.

Note: An overview of services provided is displayed. If more detailed information on a particular category is needed, then select the appropriate information from the top tabs displayed.

Enterprises:

1. Select Enterprises.

2. Under the Evaluate section at the bottom of the page, select Products and Services.

3. At the Products and Services page, select Services.

http://www.alcatel-lucent.com/solutions



A-3

............................................................................................................................................................................................................................................................

Important! An overview of the services provided is displayed. For more information, select one of the three categories shown at the bottom of the page: Consult & Design, Maintain & Operate, or Integrate & Deploy.

Technical support

Many of our customers have established their own support procedures. These procedures usually involve escalation within their own companies. However, some instances may require additional assistance from Alcatel-Lucent.

Alcatel-Lucent has been and continues to be committed to providing excellence in technical support for its products and services. Therefore, we provide a hierarchical support structure ready and available to solve any Alcatel-Lucent product technical issue.

When additional assistance is required, the Alcatel-Lucent Welcome Center is the first point of contact. An Alcatel-Lucent Welcome Center operator can direct the request to engineers that are highly trained and skilled in resolving issues, involving Alcatel-Lucent products. Technical assistance is available 24 hours a day, 7 days a week.

On-line customer support

Overview

On-Line Customer Support (OLCS) is the Customer Support web site for our customers’ technical support needs. This customer web access tool provides an easy method to access data about Alcatel-Lucent products using the World Wide Web. A customer must first request access to this web site to gain access to the following customer support features:

• Ask AL Knowledgebase

• Customer Assistance Request Entry System (CARES)

• Data Drop Box

• Documentation

• Downloads

• Alcatel-Lucent Alerts

• Product Change Notices

• RMA (Repair and Exchange)

Alcatel-Lucent Welcome Center

1 866 582 3688, prompt 1 (continental U.S.)+1 (630) 224 4672 (outside continental U.S.)(24 hours a day, 7 days a week)

By using the Alcatel-Lucent Welcome Center as the entry point for Alcatel-Lucent support, customers will be assured of a timely and effective technical support service.

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Ask AL Knowledgebase

The Ask AL Knowledgebase web interface feature connects you to the Knowledge Management solutions database. The Ask AL Knowledgebase feature lets you search for solutions by using natural language queries. Many products have an extensive set of Solutions available. Solutions are created by technicians to provide customers with a method to resolve issues without calling for assistance. Solutions are displayed, showing the percentage weight or percent match, based on search criteria. Searches can be performed on all products that are entitled, through the level of service contract a customer has for RTS services.

CARES

The CARES web interface feature makes it easy for you to submit an Assistance Request (AR), subscribe to AR Notifications (be notified when an AR is updated), and view all the customer ARs. The CARES feature lets you open an AR for low severity issues or questions. Any high severity issue should be called into CTAM. Users can stay informed about their ARs by using the flexible AR Notification subscriptions. Users can choose a method for receiving updates: email, text messaging messages, or none. Users can choose when updates are wanted (when the state of the AR changes, any update to the investigation field occurs, or any time any text field is modified). Users can log into the OLCS web site and view ARs 24 hours a day, 7 days a week.

Data Drop Box

The Data Drop Box feature allows Alcatel-Lucent support technicians to provide customers with a quick method to share files. The Data Drop Box allows a technician to provide or receive a file from a customer quickly. These files remain in place for 7 days.

Documentation

The Documentation feature on the OLCS web site contains three areas: Manuals and Guides, Technical Notes, and Release Information.

• Manuals and Guides

This section contains the documents that are available in paper or electronic copy and are distributed with a new product. These are the documents that are available within the Alcatel-Lucent Product Documentation web site. The OLCS web site contains links to the actual documents at the Customer Information Center (CIC) web site. The following is a list of possible documents that are available from this site:

– Administration Guide

– Applications Planning Guide (APG)/Applications Planning and Ordering Guide (APOG)

– Getting Started Guide

– Installation Manual (IM)/Installation Guide (IG)



A-5

............................................................................................................................................................................................................................................................

– Modification Implementation Procedure (MIP)

– User Guide

– Alarm Messaging and Trouble Clearing Guide (AMTCG)

– Framework User Guide

– Graphical User Interface (GUI) Guide

– Maintenance Guide, Provisioning Guide

– User Operations Guide (UOG)

• Technical Notes

This section contains documents that are specific to the product and are technical in nature. Most of these documents will provide information in product data sheets or white papers, which are technical documents that explain the operation of a particular part of the system. The following documents are available in this section:

– Change Notice (CN)

– Ethernet Management Guide

– Method of Procedure (MOP)

– Planning Guide

– Service Assurance Guide

– Engineering Change Procedure (ECP)

– Feature Contents

– Operations Interworking (OI) Guide

– Screen Help

– White Papers

These documents will vary from product to product.

• Release Information

This section contains documents that are specific to the release of a product. The following documents are available in this section:

– Acceptance Documents

– Software Release Descriptions (SRD)

– Specific SRD sections

– White Papers (release specific)

– Software Compatibility

– Upgrade Paths

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

Downloads

Note: This may not apply to all products.

The Downloads area allows Alcatel-Lucent support technicians to provide access to software downloads that are specific to a customers contract. This feature is only allowed through negotiation with the Account Team and the Product Manager of the product.

Alcatel-Lucent Alerts

The Alcatel-Lucent Alerts tool is a subscription-based tool that provides the same information that our Product Notifications (PNs) did previously provide. This new method of communication is a vehicle to share product and support issues that are of informational, maintenance, or preventive nature. Alcatel-Lucent Alerts contain detailed text descriptions and urgency of Alcatel-Lucent product issues that need to be quickly communicated to customers after the deployment of a release or product.

Product Change Notices

The Product Change Notices (PCN) area provides information on hardware changes for a product. There is a selection of choices to help you search for Change Notices (CNs) or Customer Change Notices (CCNs).

Return Material Authorization (RMA) (Repair and Exchange)


The RMA area provides a list of contact information on all Alcatel-Lucent products. There is a “request an RMA number” on-line for most Alcatel-Lucent products. An RMA number is required for all returned parts and this feature provides you with an easy method to obtain the RMA number. Please check the warranty status before submitting a request.

Accessing and navigating the On-Line Customer Support(OLCS) web site

Technical support


A-7

............................................................................................................................................................................................................................................................

Accessing and navigating the On-Line Customer Support (OLCS) web site

Description

This section provides the method to access the On-Line Customer Support (OLCS) web site, obtain a login (if necessary), and navigate to each feature listed in this document.

Accessing the OLCS web site

To access the Alcatel-Lucent OLCS web site, enter: www.alcatel-lucent.com/support. Once you are at this web page, select Lucent Global Support. This will bring you to the web site where you can log in to gain access to the entitled products.

Obtaining a login for OLCS

To request a login, a customer must register, then and an email confirmation is sent within 2 business days. The following steps tell you how to register for a login:

1. Select “Register Here” on the top right (just below the Login and Password boxes) of the Online Customer Support (https://support.lucent.com/portal/olcsHome.do) web site.

2. Follow this registration process:

• Select the role and accept the terms of use.

• Provide a business identification, and enter in all of the required information.

• Validate your email address.

• Confirm your business identity and set a password.

• Select content. (This will be verified against the current contract agreements.)

• Register for the selected content.

3. An email confirmation of the registration and the site access privileges is sent within 2 business days.

4. Customize the web view once you have gained access to the OLCS web site.

• After logging in, a personalized view of the Customer Support Home page displays. This view is based on the user's and company support entitlements.

http://www.alcatel-lucent.com/wps/portal/support

https://support.lucent.com/portal/olcsHome.do

https://support.lucent.com/portal/olcsHome.do

............................................................................................................................................................................................................................................................


Technical support


............................................................................................................................................................................................................................................................

Need Help while registering?

View an OLCS website

After you have logged into the OLCS web site, a personalized view of the Customer Support Home page is displayed. This view is based on the user's and company support entitlements.

To set Customer Support as the default, if it is the primary destination on the www.alcatel-lucent.com website, click “Select default home page” on the left column. The “My Products” section provides you with quick navigation to the entitled products and also quick access to the CARES tool. While navigating through the various tools, you can establish bookmarks to certain tools, documents, or web pages (within OLCS) by clicking “Add to Bookmarks.”

The Customer Support home page can be customized by selecting “Customize page layout” and adjusting the fields to be displayed (uncheck the boxes to de-select those elements). These fields can be adjusted at any time. The changes take effect immediately.

There are two methods to find product information. Click “My Products” to choose a product, or click “Documentation” or “Downloads” to display a complete product listing. When the full product list is displayed, use the alphabetic listing (default) or the category list, whichever you prefer. Once a product is selected, a “Product Summary Page” is displayed, which describes all of the tools and features available for this product.

Note: If content has been posted, but contract entitlements do not allow access, then the following padlock icon is displayed:

Ask AL Knowledgebase

The Ask AL web page can be accessed from the left column on the Customer Support homepage (unless you changed the view), from the “Technical Support” section in the center of the page, or from the “My Bookmarks” section (if it was added there). Once at

From the U.S. 1 (866) 582 3688, prompt 7

From outside the U.S. +1 (630) 218 7688

In Asia/Pacific Please contact the in-country technical support hotline.

Via email Use the email address: [email protected] or use the site's “Contact Us” form

Use the OLCS help desk number for OLCS access problems, registration questions, password resets, navigation questions, etc.

http://ww.alcatel-lucent.com

http://ww.alcatel-lucent.com


Technical support


A-9

............................................................................................................................................................................................................................................................

the Ask AL Knowledgebase web page, enter a question or phrase using natural language, and click the check boxes for only the products that should be searched; otherwise, all products checked will be searched.

The results that return show a percentage weight or percent match based on the search criteria. To refine a search, add more details to the question or phrase and answer the other questions displayed. Once you find a solution of interest, select that solution, and the complete solution will display.

Many of the solutions are based on generated ARs or Known Problems from the SRD. To provide quality information, solutions go through a review process before being posted. Content can grow daily as solutions move through the review cycle.

CARES

CARES ARs are accessed from the left column on the Customer Support homepage (unless this view was changed), under the “Technical Support” section in the center of the page, from the “My Bookmarks” section (if CARES was added there), or from the Quick Link section “CARES Assistance Requests,” at the bottom of the Customer Support homepage. Product Notifications and Solutions can also be selected in this section. These are both legacy tools. The new tools, Alcatel-Lucent Alerts and Ask AL Knowledgebase, are discussed in other sections of this document.

When you select CARES, a general web page displays. From that page, a particular function can be selected from the left column. To provide more information on the selected tool, select “More” from the center column.

ARs can be viewed (using “Find an AR” or “Advanced query”), created (using “Create an AR”), or used to report a warranty defect (using “Report a warranty defect”). The CARES web interface has features that keep you informed about the progress of ARs. With the flexible AR Notification subscriptions, CARES can email or send text messages on a variety of activities regarding an AR. A notification is sent when the AR state is changed to Created, Resolved, Closed, or Pending Customer Action. Other conditions that generate notifications are if the following fields are updated: Investigation, Short Description, Current Summary, Description, and Resolution. You can set up (subscribe), remove (unsubscribe), or change these conditions at any time.

Data Drop Box

You can access the Data Drop Box from the left column on the Customer Support homepage (unless your view was changed), from the “Technical Support” menu in the center of the page, or from the “My Bookmarks” section (if Data Drop Box has been added there). Click the “Upload a file” button in the Data Drop Box window to send a file to the Alcatel-Lucent support technician. An email address can also be entered so that the

............................................................................................................................................................................................................................................................


Technical support


............................................................................................................................................................................................................................................................

Alcatel-Lucent technician will be notified when the file has been sent. Click the “Download a file” button from the Data Drop Box if the Alcatel-Lucent technician has sent a file to be downloaded. These files will remain on the site for 7 days.

Documentation

You can access documentation by selecting a product from the “My Products” area. Alternatively, documentation can also be accessed from the left column on the Customer Support home page (unless this view has been changed), from the “Technical Support” section in the center of the page, or from the “My Bookmarks” section (if Documentation has been added there). If accessing Documentation by means other than the “My Products” area, choose the product whose documentation you wish to access by selecting the product from the alphabetical listing or the category list.

Once you are on the product web page, select “Manuals and Guides” from the list under the “Documentation and downloads” section. The “Manuals and Guides” link brings you to the Library of Manuals and Guides for the product you have chosen. The document links bring you to the document stored in the Alcatel-Lucent Customer Information Center (CIC) web site or to another OLCS webpage that contains the product documentation.

Within the “Documentation and Downloads” area, the “Technical Notes” link brings you to a web page which contains documents that are not release specific and are technical in nature.

Also, within the “Documentation and Downloads” area, the Release Information link brings you to a Library of Release Notes web page that contains documents which are release specific and are listed by release.

Click on these links to download or open a PDF file.

Downloads


You can access downloads by selecting a product from the “My Products” section. Downloads can also be accessed from the left column on the Customer Support homepage (unless this view has been changed), from the “Technical Support” section in the center of the page, or from the “My Bookmarks” section (if Downloads was added there). If accessing Downloads by means other than the “My Products” area, choose the product whose Downloads you wish to access by selecting the product from the alphabetical listing or the category list.

Once you are on the product web page, click the “Downloads: Electronic Delivery” link from the list under the “Documentation and Downloads” area. Select the appropriate release to be downloaded from the drop-down list, and click “Next.” Select the file to be downloaded and click “Next.” On the next web page, enter the path where the file should be downloaded and click “Download.”


Technical support


A-11

............................................................................................................................................................................................................................................................

Alcatel-Lucent Alerts

You can access Alcatel-Lucent Alerts from the left column on the Customer Support homepage (unless this view has been changed), from the “Technical Support” section in the center of the page, or from the “My Bookmarks” section (if Alcatel-Lucent Alerts is added there).

Once you are on the Alcatel-Lucent Alerts web page, a list of products are displayed. Click on a product to see a list of Alerts for that product. Alternatively, use the “Enter the number of the Alert” field to find a specific Alert, or use the text search to search for Alerts with certain words.

To subscribe to Alcatel-Lucent Alerts, click the “Alerts Subscription Page” link. Once at the “Alcatel-Lucent Alerts Subscription” page, fill out the form and choose the product whose alerts you would like to subscribe to.

You have the option to click “Modify Subscription” or “Cancel Subscription.” Modify Subscription allows you to modify the Urgency, Type, and/or Products selected. “Cancel Subscription” will stop future Alcatel-Lucent Alerts email messages.

Product Change Notices (PCNs)

You can access Product Change Notices (PCNs) from the left column on the Customer Support home page (unless this view has been changed), from the “Technical Support” section in the center of the page, or from the “My Bookmarks” section (if PCNs were added there).

Once on the PCN web page, a list of PCNs is displayed. You can search PCNs by clicking one of the following links:

• PCN cross-reference

• Search for specific text in Class A PCNs

• PCNs added or updated within the past 30 day

• Change Notice summary report

Return Material Authorization (RMA) (Repair and Exchange)


Return Material Authorization (RMA) can be accessed from the left column on the Customer Support home page (unless this view has been changed), from the “Technical Support” section in the center of the page, or from the “My Bookmarks” section (if it was added there).

Once on the RMA web page, a table with contact information is displayed. Use the contact information provided or choose to fill in the online RMA request form at the bottom of that web page.

............................................................................................................................................................................................................................................................

Other technical support servicesTechnical support


............................................................................................................................................................................................................................................................

Other technical support services

The technical support services expert workshop series

Audience: Technicians, installers, maintenance engineers, technical support personnel, product evaluators, and anyone who has a working knowledge of the products involved and is interested in a hands-on workshop covering advanced troubleshooting issues.

Description: The same engineers that resolve the Assistance Requests (ARs) have developed a series of advanced, hands-on workshops that can be customized to the unique network applications. Individual product modules will provide the knowledge and skills to perform troubleshooting and fault-finding activities at the equipment site or from a remote operations center. There are lab exercises using Alcatel-Lucent network management systems to simulate real-world provisioning and troubleshooting scenarios. In addition, general technology modules will round out the understanding of the network element (NE) troubleshooting performed.

Objectives: Each module has specific objectives. Some overall series objectives are listed below:

• Understand advanced network element security features

• Setup and understand interworking between Alcatel-Lucent network elements

• Perform provisioning operations and remote trouble-shooting using CIT, EMS and TL1 interfaces.

• Analyze Performance Monitoring Data

• Understand alarm handling / alarm management

• Provision and understand system synchronization techniques

• Provision and understand protection schemes (BLSR, UPSR, 1+1 APS)

• Understand network communication issues (OSI and TCP/IP interfacing)

Length: Product Modules are scheduled for 3 days. Technology Modules are scheduled for 1 day.

Expected Foundation Knowledge: Suggested prerequisites are listed on each module's workshop description. Generally, customers should have a basic understanding of digital fundamentals and lightwave transmission systems. In addition, customers should have taken a previous Alcatel-Lucent Operating & Maintenance course or have equivalent experience with operations and maintenance issues related to the product

Activities Prior to Workshop Delivery: The effectiveness of this workshop series relies on the fact that it allows a customer to address the issues experienced in their network today. To achieve this, prior to the workshop, a conference call will be set up with the engineers that will facilitate the workshop. During this call, the logistics of simulating the customer's network environment will be discussed.



A-13

............................................................................................................................................................................................................................................................

Workshop Location: This workshop will be delivered in the Customer Advocate System Test Labs in Westford, MA. The format is 75% hands-on lab exercises, reinforced with 25% classroom instruction.

How to Sign Up:

To enroll in the training course:

• Within the United States,

– Visit https://training.lucent.com

– Call 1 (888) 582 3688: Prompt 2.

• Outside the continental United States,

– Visit https://training.lucent.com

– Contact your in-country training representative

– Call: +1 (407) 767 2798

– Fax: +1 (407)767 2677

• Enter “Advanced Workshops” in the search menu and click “Go.”

• Choose which Advanced Maintenance Workshop you’d like to register for by clicking on the link.

• Read the workshop description(s) and follow the links to register.

https://training.lucent.com/Saba/Web/Main

https://training.lucent.com/Saba/Web/Main

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

GL-1P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

Glossary

........................................................................................................................................................................Acronyms and Abbreviations

............................................................................................................................................................................................................................................................

A

ABNAbnormal

AISAlarmIndication Signal

ALSAutomatic Laser Shutdown

APDAvalanche Photo Detector (photodiode technology)

APSAutomatic Protection Switching

ANSIAmerican National Standards International

ASICApplication Specific Integrated Circuit

ATTDATTenDed (alarm storing)

AU/AU4Administrative Unit / level 4

AUGAdministrative Unit Group

AUOHAU Pointer

AUXAUXiliary

............................................................................................................................................................................................................................................................

Acronyms and AbbreviationsGlossary

GL-2 P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

............................................................................................................................................................................................................................................................

B

BATTBATTery

BERBit Error Rate

BIPBit Interleaved Parity

BNCBayonet Not Coupling

............................................................................................................................................................................................................................................................

C

CEEuropean Conformity

COCentral Office

CPECustomer Premises Equipment

CTCraft Terminal

CMICode Mark Inversion

COAXCOAXial

CPOOutgoing Parallel Contacts

CPUCentral Processing Unit (referred to Controller equipment unit or Microprocessor)

CWDMCoarse Wavelength Division Multiplexing

............................................................................................................................................................................................................................................................

D

DCDirect Current



GL-3

............................................................................................................................................................................................................................................................

DCCData Communication Channel

DCEData Circuit Terminating Equipment

DPLLDigital Phase Locked Loop

DWDMDense Wavelength Division Multiplexing

............................................................................................................................................................................................................................................................

E

ECEquipment Controller

ECCEmbedded Control Channel

ECTEquipment Craft Terminal

EMCElectromagnetic Compatibility

EMIElectromagnetic Interference

EOWEngineering Order Wire

ESDElectroStatic Discharges

ETSIEuropean Telecommunication Standards Institute

E2PROMElectrically Erasable Programmable Read Only Memory

............................................................................................................................................................................................................................................................

F

FF Interface (for Craft Terminal) or Fuse

FEBEFar End Block Error

FEPROMFlash Electrically Erasable Programmable Read Only Memory

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

FERFFar End Receive Failure

FLCFirst Level Controller

FPGAField Programmable Gate Array

............................................................................................................................................................................................................................................................

G

GAGate Array

GbEGigaBit Ethernet

GNDGround

............................................................................................................................................................................................................................................................

H

HDB3High Density Bipolar Code

HOAHigh Order Adaptation

HOIHigh Order Interface

HPCHigh Order Path Connection

HPTHigher Order Path Termination

HPOMHigh order Path Overhead Monitoring

HSUTHigh order Supervision Unequipped Termination

HWHardware

............................................................................................................................................................................................................................................................

I

ICSItem Change Status



GL-5

............................................................................................................................................................................................................................................................

IDIdentification Signals

IECInternational Electrotechnical Committee

IEEEInstitute of Electrical and Electronic Engineering

INInput

INDIndicative alarm

IPInternet Protocol

ISOInternational Organism for standardization

ITU-T (*)International Telecommunication Union-Telecommunication Sector

............................................................................................................................................................................................................................................................

L

LANLocal Area Network

LDSSHUTCommand for ALS

LDTLink Description Table

LEDLight Emitting Diode

LOFLoss Of Frame(alignment)

LOILow Order Interface

LOMLoss Of Multiframe

LOPLoss Of Pointer

LOPLoss Of Signal

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

LPALower Order Path Adaption

LPCLower Order Path Connection

LPOMLower Order Path Monitoring

LPTLower Order Path Termination or Loopback Equipment side (local)

LSUTLower Order Supervisory Unequipped termination

............................................................................................................................................................................................................................................................

M

MCFMessage Communication Function

MSAMultiplex Section Adaptation or Multi-Source Agreement (transceiver)

MSOHMultiplex Section Overhead

MSPMultiplex Section Protection

MSTMultiplex Section Termination

............................................................................................................................................................................................................................................................

N

NRZNo Return to Zero

NURGNot Urgent alarm

............................................................................................................................................................................................................................................................

O

OMSNOptinex MultiService Node

OOFOut Of Frame

ORLogic sum/Loss of only one station battery



GL-7

............................................................................................................................................................................................................................................................

OSOperating System

OUTOutput

............................................................................................................................................................................................................................................................

P

P/SParallel/Serial converter

PCPersonal Computer

PDHPlesiochronous Digital Hierarchy

PIPhysical Interface

PPIPlesiochronous Physical Interface

POHPath Overhead

PMMFPhysical Machine Management Function

PRBSPseudo Random Binary Signal

PWALMPower Supply Alarm

PWANDORANDOR/3 failure

............................................................................................................................................................................................................................................................

Q

Q2/QB2TMN Interface with B2 protocol. Interface towards plesiochronous equipment

Q3/QB3TMN Interface with B3 protocol. Interface towards TMN

............................................................................................................................................................................................................................................................

R

RReset command/General alarm

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

RAIRemote Alarm Indication

RECCRecommendation

RDIRemote Defect Indication

REIRemote Error Indication

REFReference

RELRelease

RIBUSRemote Inventory BUS

RNURGNot Urgent Alarm command. Lights up the relative rack red LED

RSOHRegenerator Section Overhead

RSTRegenerator Section Termination

RURGUrgent Alarm command. Lights up the relative rack red LED

RXReception

............................................................................................................................................................................................................................................................

S

SCShelf Controller

SDHSynchronous Digital Hierarchy

SETGSynchronous Equipment Timing Generation function

SLMSingle Longitudinal Mode

SMSingle Mode/Synchronous Mux

SNCP/I (**)Subnetwork Connection Protection Inherent



GL-9

............................................................................................................................................................................................................................................................

SOHSection Overhead

S/PSerial/Parallel Converter

SPISynchronous Physical Interface

SSFServer Signal Fail

SSUSynchronization Supply Unit

STM-0/STM-1..Synchronous Transport Module, levels 0 etc.

SWSoftware

............................................................................................................................................................................................................................................................

T

TANCRemote alarm due to failure of all power supply boards

TDLayout drawing

TIMTrace Identifier Mismatch

TMNTelecommunication Management Network

TORRemote alarm indicating loss of one of the station batteries

TORCRemote alarm due to a faulty/missing power supply board

TSDTrail Signal Degrade

TSFTrail Signal Fail

TSSTransport Service Switch

TTFTransport Terminal Function

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

TUG2/3Tributary unit group, level 2, 3

TUOHTributary Unit Overhead

TUP/UPEquipment Controller remote alarm

TU12/TU3Tributary unit level 12, 3

TXTransmission

TSOTechnical Support Organization

............................................................................................................................................................................................................................................................

U

URGUrgent

UIDUser Identifier

USBUniversal Serial Bus

............................................................................................................................................................................................................................................................

V

VCGVirtual Concatenation Group

VLANVirtual Local Area Network

VLSIVery Large Scale Integration

VCXO/VCOVoltage Controlled Oscillator

VC12/VC3/VC4/VC16/VC64Virtual Container, levels 12, 3, 4, 16, 64

VMMFVirtual Machine Management Function



GL-11

............................................................................................................................................................................................................................................................

VPNVirtual Private Network

VTVirtual Tributary

............................................................................................................................................................................................................................................................

W

WANWide Area Network

WDMWavelength Division Multiplexing

............................................................................................................................................................................................................................................................

X

XCCross-Connection

............................................................................................................................................................................................................................................................

Z

ZICZero Installation Craft terminal

............................................................................................................................................................................................................................................................



............................................................................................................................................................................................................................................................

I N - 1P/N 8DG 09019 JAAAIssue 01 June 2009

............................................................................................................................................................................................................................................................

Index

.............................................................................

.............................................................................

.............................................................................

.............................................................................

.............................................................................

.............................................................................

.............................................................................

C conventions used, xv

D documentconventions used, xv

how to use, xiii

intended audience, xiii

E Electrostatic Discharge (ESD), xv

I intended audience, xiii

P product disposal, xvii

product take-back, xvii

R recycle, xvii

S SFP, 4-21

I N - 2 P/N 8DG 09019 JAAAIssue 01 June 2009

Index

............................................................................................................................................................................................................................................................

............................................................................................................................................................................................................................................................