Turn-up and Commissioning Guide - 8DG25697KAAA_V1_Alcatel-Lucent 1850 Transport Service Switch...

Alcatel-Lucent - ProprietaryThis document contains proprietary information of Alcatel-Lucent and is not to be disclosed or usedexcept in accordance with applicable agreements

Alcatel-Lucent 1850Transport Service Switch (TSS-100) | Release 3.0 Turn-Up and Commissioning Guide

8DG 25697 KAAAISSUE 2

JANUARY 2009

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

The information presented is subject to change without notice. Alcatel-Lucent assumes no responsibility for inaccuracies contained herein.

Copyright © 2008 Alcatel-Lucent. All Rights Reserved.

Conformance statements

Interference Information: Part 15 of FCC Rules

This equipment has been tested and found to comply with the limits for Class A digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interferences 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 telecommunications networks through the use of remote access feature. 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 allowances or give any credit for charges that result from unauthorized access.

Limited warranty

Alcatel-Lucent provides a limited warranty to this product. 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

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Contents

About this document

Purpose ........................................................................................................................................................ ix

Reason for revision ...................................................................................................................................... ix

EDITION ..................................................................................................................................................... ix

DATE .......................................................................................................................................................... ix

DESCRIPTIONS ......................................................................................................................................... ix

Intended audience ........................................................................................................................................ ix

Supported systems .........................................................................................................................................x

How to use this document .............................................................................................................................x

Safety information ....................................................................................................................................... xi

Related information .................................................................................................................................... xii

Document support ..................................................................................................................................... xiv

Technical support ...................................................................................................................................... xiv

How to order .............................................................................................................................................. xiv

How to comment ....................................................................................................................................... xiv

Packaging collection and recovery requirements ...................................................................................... xiv

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

1 Introduction

Safety, labels and Norms ........................................................................................................................... 1-1

2 Initial Turn-up and Setting

Purpose ...................................................................................................................................................... 2-1

Contents ..................................................................................................................................................... 2-1

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

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

Start up procedure ..................................................................................................................................... 2-3

N.E. Software settings ............................................................................................................................. 2-12

3 Tests and measurements

Purpose ...................................................................................................................................................... 3-1

Contents ..................................................................................................................................................... 3-1

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Contents

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Instruments, Accessories and related documents ...................................................................................... 3-2

Connection points position ....................................................................................................................... 3-4

Local Measures list and operating sequence ............................................................................................. 3-8

Point-to-point measures list and operating sequence .............................................................................. 3-41

Restore factory default ............................................................................................................................ 3-48

4 Connections, configurations and characteristics

Contents .................................................................................................................................................... 4-1

Unidir HO STM-n cross-connection - Matrix looped STM-n .................................................................. 4-2

HO Bidir protected unstructured cross-connection between an STM-1/STM-4 port and STM-n ports ... 4-4

HO unprotected bidir cross-connection between a local and a remote data port ...................................... 4-5

HO Unprotected Bidir. XC between a Remote data port (VCG, VC4-nV) and an STM-N port ............. 4-7

Lower order (TU12) bidir protected XC between an STM-1/STM-4 port and STM-n ports ................... 4-8

Lower order (TU3) bidir protected XC between an STM-1/STM-4 port and STM-n ports ................... 4-11

Procedure to enable and disable the ALS ............................................................................................... 4-15

SFP and XFP modules optical characteristics ......................................................................................... 4-16

EC100 card front view ............................................................................................................................ 4-23

MT100 card front view ........................................................................................................................... 4-24

................................................................................................................................................................. 4-24

5 Alcatel-Lucent 1850 Transport Service Switch (1850 TSS-100) test report Sheet modules

6 Abbreviations

Table of abbreviations ............................................................................................................................... 6-1

IN Index

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List of figures

2-1 Craft Terminal (ZIC) Main window .......................................................................................... 2-10

3-1 Common cards connection points position .................................................................................. 3-4

3-2 Free-running frequency check ...................................................................................................... 3-9

3-3 PDH Ports test ............................................................................................................................ 3-12

3-4 STM-n Ports test ........................................................................................................................ 3-14

3-5 GE and 10GE ports test .............................................................................................................. 3-16

3-6 Test of GE transport on VC4-xV ............................................................................................... 3-19

3-7 Test of 10GE transport on VC4-xV ........................................................................................... 3-22

3-8 Bridge VLAN switching test, untagged frames ......................................................................... 3-25

3-9 SNCP protection check (line ports) ............................................................................................ 3-27

3-10 MATRIX/CRU EPS protection check ....................................................................................... 3-31

3-11 Synchronism priority and Holdover ........................................................................................... 3-33

3-12 Alarms check .............................................................................................................................. 3-34

3-13 Extension interface electrical connectors location and pinout ................................................... 3-39

3-14 Rx Optical "line port" power check ........................................................................................... 3-42

3-15 Optical "line port" link margin ................................................................................................... 3-43

3-16 Point-to-point error monitoring check ....................................................................................... 3-45

3-17 Ring error monitoring check ...................................................................................................... 3-46

4-1 EC100 card (Equipment Controller) - front view ...................................................................... 4-23

4-2 MT100 card (Universal Matrix) - front view ............................................................................. 4-24

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List of figures

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List of tables

1 Product release document applicability ...........................................................................................x

3-1 Instruments ................................................................................................................................... 3-2

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

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

3-4 Numbering and functions referred to the common cards Connection Points .............................. 3-5

3-5 TSS-100 traffic cards connection points ...................................................................................... 3-6

3-6 Rack alarms connector pin-out ................................................................................................... 3-36

3-7 Housekeeping connector pin-out ................................................................................................ 3-38

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List of tables

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About this document

Purpose

This manual provides instructions for turn-up and testing of the Alcatel-Lucent 1850 Transport Service Switch (TSS-100). This manual is not a service manual. Refer to 8DG25697BAAA - Alcatel-Lucent 1850 Transport Service Switch (TSS-100) User Provisioning Guide for any activities involving circuit turn-up, or ·8DG25697FAAA - Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Maintenance and Trouble Clearing Guide for trouble analysis and regular maintenance.

Measurements are carried out in normal environmental and power supply operating conditions. During the test period, the equipment must always be ON.

When using this handbook it is assumed that the Operators know:

• the structure (hardware composition, refer to ·8DG25697AAAA - Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Product Information and Planning Guide) and all the possible operating modes of the equipment (product-release) this handbook refers to.

• how to use a PC and the Windows ambient applications

Reason for revision

The following table shows the revision history of this document.

Intended audience

This manual is intended for individuals who are responsible for the turn-up and commissioning of the Alcatel-Lucent 1850 Transport Service Switch (TSS-100).

EDITION DATE DESCRIPTIONS

01 November 2008 It is the first validated and officially released issue of this document

02 January 2009 It has been issued to add the 1000Base-BX SFP and for template updating

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About this document

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Supported systems

This Product Information guide applies to the following product releases:

Table 1 Product release document applicability

How to use this document

This handbook has been edited according to the Alcatel-Lucent standard. It is divided into the following main topics as described in the table of contents:

PRODUCT Part Number

1850TSS-100 8DG 02602 AAAA

PRODUCT RELEASE VERSION Part Number

1850TSS-100 3.0 8DG 25658 AAAA

Topic Description

ABOUT THIS DOCUMENT It contains general information as preliminary information, safety recommendation, handbook purpose, history, related documents, handbook structure..

INTRODUCTION The procedures are introduced with general information and rules

INITIAL TURN-ON AND SETTING

List the instructions that must be sequentially executed to turn-on the equipment

TEST AND MEASUREMENTS Describes the measures to perform in order to check the correct operating mode of the equipment units

CONNECTIONS, CONFIGURATIONS AND CHARACTERISTICS

Contains the detailed list of procedures to define connection and configuration; furthermore characteristics and parameter values used during commissioning. They are referred in the Test and Measurements chapter as detailed procedures/data available when necessary

TEST REPORT MODULES Modules available to be filled during On Site Commissioning final test

ABBREVIATIONS Contains the list of abbreviation used in this document

INDEX Contains a list of index references

CUSTOMER DOCUMENTATION FEEDBACK

It contains info regarding customer opinions collection about this documentation

About this document

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Safety information

This document contains safety 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

Recommended safety rules are indicated in this manual.

Local safety regulations must be used if mandatory. Safety instruction in this document should be used in addition to the local safety regulations. In case of conflict between safety instructions stated in this manual and those indicated in local regulations, mandatory local norms will prevail. If local regulations are not mandatory, than safety rules stated in this manual will prevail.

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

Invisible laser radiation is present when the optic connector is open. AVOID DIRECT EXPOSURE TO BEAM.

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 and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference in which case users will be required to correct the interference at their own expense.

Adhere to the following safety precautions:

• Electrostatic discharge (ESD)

You must be properly grounded when making contact with the Alcatel-Lucent 1850 Transport Service Switch (TSS-100) 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 Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 Safety Guide - 8DG 25697 GAAA.

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About this document

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Service Personnel

Installation and service must be carried out by authorized persons having appropriate technical training and experience necessary to be aware of hazardous operations during installation and service, so as to prevent any personal injury or danger to other person as well as prevent damaging the equipment.

Access to the Equipment

Access to the Equipment in use must be restricted to Service Personnel only.

Service Personnel skill

Service Personnel must have an adequate technical background on telecommunications and in particular on the equipment subject of this handbook. An adequate background is required to properly install, operate and maintain equipment. Merely reading this handbook and the associated handbooks indicated in “Related information” (p. xii) is considered as not enough.

Admonishments

To avoid hazardous conditions, observe the following admonishments:

Related information

The following list depicts all the documents related to this product:

1. 8DG 25697 AAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 Product Information and Planning Guide.

2. 8DG 25697 BAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 User Provisioning Guide.

3. 8DG 25697 CAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 TL1 User Provisioning Guide

4. 8DG 25697 DAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 TL1 Commands Guide

DANGER

Possibility of personal injury.

CAUTION

Possibility of service interruption.

WARNING

Possibility of equipment damage.

About this document


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5. 8DG 25697 EAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 CLI User Provisioning Guide.

6. 8DG 25697 FAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 Maintenance and Trouble Clearing Guide.

7. 8DG 25697 GAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 Safety Guide.

8. 8DG 25697 HAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 Engineering Rules.

9. 8DG 25697 JAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 Installation Guide.

10. 8DG 25701 AAAA — Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 Documentation CD-ROM. It contains the electronic format of all the above listed documents.

In particular, refer to the Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Safety Guide and Product Information and Planning Guide to obtain the following information:

• GENERAL CHARACTERISTICHS AND NORMS

• SAFETY RULES

– General rules

– Harmful optical signals

– Risk of explosion

– Moving mechanical parts

– Heat-radiating Mechanical Parts

• ELECTROMAGNETIC COMPATIBILITY (EMC)

• ELECTROSTATIC DISCHARGERS (ESD)

• LABELS AFFIXED TO THE EQUIPMENT

• GENERAL ON ALCATEL CUSTOMER DOCUMENTATION

• DISMANTLING & RECYCLING

Alcatel-Lucent 1850 Transport Service Switch (TSS-100) Release 3.0 User Provisioning Guide as a guide of the Craft Terminal (ZIC) procedures and menu.

Other useful documents are:

• Station layout

• Plant documentation.

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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 all the Technical Support needs (engeneering, installation, maintenance etc.) and product training, please contact your Local Alcatel-Lucent Technical Assistance Center (TAC).

How to order

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

How to comment

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

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.

https://support.lucent.com

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

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

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

mailto:[email protected]

mailto:[email protected]

https://support.lucent.com

http://alcatel-lucent.com/support/

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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.

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].

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1 Introduction

The current procedure defines the commissioning modality for the Alcatel-Lucent 1850 Transport Service Switch (TSS-100) 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.

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, labels and Norms

WHEN CARRYING OUT THE GIVEN OPERATIONS OBSERVE THE NORMS STATED IN THE SAFETY GUIDE (see “Related information” (p. 1-xii))

ATTENTION EMC NORMS

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Safety, labels and NormsIntroduction

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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.

General Rules

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

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

• To 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

• All measures must be done at the ODF/DDF points (ODF= Optical Distribution Frame, DDF= Digital Distribution Frame).

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

2.8 kg x cm (0.28 Newton x m) ± 10%

Exceeding this value may result in screw breaking.

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

WARNINGFIXING THE UNITS (AND MODULES) INTO THE SUBRACK(caution to avoid equipment damage)


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2 Initial Turn-up and Setting

Purpose

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

Contents

This chapter contains the following topics:

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

“HW setup” (p. 2-2)

“Start up procedure” (p. 2-3)

“N.E. Software settings” (p. 2-12)

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


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Visual inspection for shelf installation and cabling

Check the following before starting any procedure.

• Rack allocation: according to station layout

• Shelf allocation in the rack: according to station layout

• Shelf configuration (units 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 setup

Unit 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 (refer to “Related information” (p. 1-xii)).

Start up procedureInitial Turn-up and Setting


2-3

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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. 2-3)

“Voltage polarity test” (p. 2-3)

“TRU Output Voltage for main shelf” (p. 2-4)

“Equipment Power-on” (p. 2-4)

“General system check” (p. 2-5)

“PC Start-up” (p. 2-6)

“Software download at the first installation” (p. 2-6)

“C.T. (ZIC) Start-up” (p. 2-8)

“NE Start-up” (p. 2-8)

“Software Download procedure” (p. 2-11)

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

• All Circuit Breakers or TRU (Top Rack Unit) Extension Bypass units have to be in power-off position

• Check branch -A and -B against "+" - Line with the multimeter:

Input Power Range: -38 VDC to -72 VDC

• Check the voltage of "+" - Line against the rack frame.

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TRU Output Voltage for main shelf

• Disconnect power cable from the two PSFs

• Turn on the Extension Bypass units and check voltage at the power cable plugs.

– Branch Input < -65 V --> Output Power NGTRU = -65 V

– Branch Input > -65 V --> Output Power NGTRU = Branch Voltage

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

• After the voltages have been measured, power off the Extension Bypass units and reconnect the power cables

• Fix the power cable screws.

Equipment Power-on

• Switch on all Step-up Converters, NGTRU BYPASS and Circuit Breakers located at the top of each rack

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

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

After FLC (EC100) boot-up with empty persistency, the hardware in the system has to be configured via Equipment Provisioning Dialog and CT-GUI (refer to the User Provisioning Guide, listed in “Related information” (p. 1-xii)).

Before starting the next test or any measurement, allow a warm-up period of the Alcatel-Lucent 1850 TSS-100 for at least 30 min.

DANGERNever disconnect and connect power cable under load

RTN

-48VDC

RT

-48VDC



2-5

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General system check

After equipment configuration is done, the Alcatel-Lucent 1850 TSS-100 should be in the following state:

• FLCs (EC100) are running in redundant state

• All SLCs (in MT100) are loaded and have state active/passive in these shelves

• No alarms "Critical" and "Major" are present in the system

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

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

WARNINGEnsure that the reference clocks are connected and selected by the equipment clock system before performing further tests. - check for status and corresponding alarms on the CT

WARNINGRecord installed software versions and part number in the Test Protocol

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PC Start-up

Computer hardware configuration

Refer to the User Provisioning Guide, listed in “Related information” (p. 1-xii).

Computer software configuration and installation

Refer to the User Provisioning Guide, listed in “Related information” (p. 1-xii).

Software download at the first installation

To perform the SW download procedure, it is requested to have installed a FTP server application. In this example "1850" is both username and password of this application.

1. Connect the PC 9-pin COM1 port to the EC100 mUSB debugger port (19, see Figure 3-1, “Common cards connection points position” (p. 3-4)) by means of the debugger cable 8DG 25468 AA, (k. in Table 3-2, “Accessories” (p. 3-2)).

2. On PC, select Start -> Programs -> Accessories -> Communication -> Hyperterminal and perform the following settings (it is suggested to save these settings to have a faster access in the following connections)

Select COM1

and click on Apply.

Click on File -> Properties and select "VT100" in Emulation field.

3. Connect the PC Ethernet port to the EC100 ETH (LAN) port (18, see Figure 3-1, “Common cards connection points position” (p. 3-4)), by means of the Ethernet cable, (l. in Table 3-2, “Accessories” (p. 3-2))

WARNING

FTP Server program installed and running is mandatory for software download.

In case of a firewall is running on PC, it is required to disable it.Disable the pop-up blocker, if enabled.If a secure http is used (https://…), it is required to have a temporary certification. The customer can get it, following the browser indications.

• Bit per seconds 38,400• Data bits 8 8• Parity None• Stop Bits 1• Flow control None



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In the following, the commands to be entered by the operator are in bold. After typing the command, press ENTER.

4. Power on the equipment

5. when the program indicates PRESS CRTL\-C to stop the boot sequence, enter CTRL\C

6. # login root7. # ifconfig eth1 151.98.15.36 netmask 255.255.255.0 up (to enable the ETH1 port of

1850TSS); 151.98.15.36 is the IP address

8. start the FTP server application

9. # cd /tmp10. # ftp 151.98.15.35 (ftp server address)

11. # cd /dir (dir = directory name)

12. # get keyfsimage (binary mode)

13. EXIT ftp application

14. # ramdisk-init15. # disk-init FORMAT FLASHDISK RAID (to format the flash disk)

16. # disk-init MOUNT17. # StartApp DWL 1850TSS320M 1850TSS100M Vx.x.x 151.98.15.35 21 /dir 1850

1850 falsewhere

18. at the end the program give the result of the procedure (i.e. success)

19. # disk-init UMOUNT20. unplug the LAN cable

21. # reboot22. It is now possible to start the CT (ZIC) application.

• 1850TSS100M NE SW package (twice); M stands for Multiservice• Vx.x.x SW Version• 151.98.15.35 IP address• 21 Port• dir directory name• 1850 the first one is the FTP username, the second one is the FTP

password

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C.T. (ZIC) Start-up

Procedure

1. Enable the DHCP function on the PC LAN port, using the following procedure: select Start -> Control Panel -> Network connections -> Local area connection -> Properties -> Internet Protocol (TCP/IP) -> Properties -> Obtain an IP address automatically -> OK

2. Connect the LAN port of the C.T. (ZIC) to the LAN connector (16, see Figure 3-1, “Common cards connection points position” (p. 3-4)), located on the MT100 unit (SLC, plugged in slots 9 and 10)

3. Check the IP address: select Start -> Run than enter cmd in the "Run" window. In the new window enter ipconfig and check that the ip address is 10.0.0.x

NE Start-up

1. Open a browser and enter the IP address of the TSS-100 Craft Terminal (ZIC) port (e.g. http://10.0.0.1/ -> ENTER). The equipment will be displayed on the screen

2. To access the NE, the operator has to be logged to the NE. In the Authentication dialog box, Enter User (e.g., ALCATEL-LUCENT) and Password (e.g. Ansi_4GX), then click on "Login" button

3. The next window requires to choose the operative region: ANSI or ETSI. After choosing, click on "Save", so accessing the five steps of the turn-up procedure

4. Turn-up Procedure STEP 1/5 - System Identification. It allows to provide the system/NE name)

System IdentificationIn the "SID" field, enter the desired name, e.g., GENOVA132.

The other fields are fixed and cannot be modified.

Click on "Save".



2-9

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

5. Turn-up Procedure STEP 2/5 - Network Setting. It allows to provide the system/NE name)

This procedure allows to set the following fields, displayed on the screen:

Click on "Save".

6. Turn-up Procedure STEP 3/5 - Time SettingsThis procedure allows setting the following field, displayed on the screen:

Click on "Save".

OSI ADDRESS (NSAP) for all the NE of the network

• L3IDP

These fields, located below the OSI ADDRESS (NSAP), can be modified by the operator according to the customer needs

• L3DFI

• L3ORG

• L3RES

• L3ROW

• L3SYS

IP ADDRESS (HOST ID) for all the NE of the network

• IP ADDRESS digit a valid IP address

• SUBNET MASK fixed value at 255.255.255.255, it cannot be modified

LAN ADDRESS (Q) This field is for gateway NE only. This NE has to be connected to the NMS (DCN) via LAN cable. This cable is connected to the M connector of the MT100 (17, see Figure 3-1 on page 3-4)

• ENABLE LAN YES (V in the square)

• ENABLE IP YES (V in the square)

• PROXY ARP Allows the NMS to know the IP address (HOST ID) of the NEs inside the network, via the gateway NE. It can be enabled or disabled, according to the customer requirements

• OSPF AREA currently it can be only Disabled

• IP ADDRESS Provided by the customer (e.g. 151.98.27.132)

• SUBNET MASK Provided by the customer (e.g. 255. 255. 255.0)

• INTEGRATING IS-IS Routing protocol, it can be enabled or disabled according to the customer requirements

NE TIME

• ENABLE NTP PROTOCOL

If selected (V in the square) allows using the network time protocol, via an FTP server. Click on "Create" and enter the IP address of the NTP server. It is also possible to set the "Offset time"

If not selected (empty square) we can set by hand the current date and time

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



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

7. Turn-up Procedure STEP 4/5 - Root PasswordThis procedure allows setting the following field, displayed on the screen:

Click on "Save".

8. Turn-up Procedure STEP 5/5 - Reboot SystemAll the settings will be effective only after rebooting the system.

Click on "Reboot" for rebooting the system.

Figure 2-1 Craft Terminal (ZIC) Main window

CHANGE ROOT PASSWORD

Allows to modify the standard debug root password (provided by Alcatel-Lucent) with a new one chosen by the customer

Tree Structure

Alarms view

Client window



2-11

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

Software Download procedure

This procedure allows loading and installing a new SW version.

This procedure could be traffic affecting.

Procedure

1. Access the main menu of the Alcatel-Lucent 1850 TSS-100 CT (ZIC), as described in previous para. “NE Start-up” (p. 2-8), and proceed as in the following

2. Click on "System"

3. Click on "Software Release"

4. In the new window, click on "New Software Version", than enter

• the "Host" address (e.g. 151.98.27.84, it is provided by the customer)

• the server path (the directory where the SW is stored)

• user and password

5. Click on "Download", than "OK" to download the new software version

6. Click on the new software version

7. Select "Activate auto" or "Activate Manual" according to the customer requirements

8. Wait till the "Successful installation of the new SW Package"

9. Press "OK".

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

N.E. Software settingsInitial Turn-up and Setting


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

N.E. Software settings

Preset the equipment configuration

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

It is first required to access the main menu of the Alcatel-Lucent 1850 TSS-100 CT (ZIC), as described in previous para. “NE Start-up” (p. 2-8).

Then it is required to click on the SLOT to be configured, in the Tree structure of the Main window (located on the left of the screen, refer to Figure 2-1, “Craft Terminal (ZIC) Main window” (p. 2-10)).

Now it is possible to perform the operations described in the following.

To set a card out-of-service

• Select "OOS" in the "Primary state" field and click on save.

To add a card

• Select an empty slot

• Select the Unit type in the "Equipment expected" field

• The "AINS mode" field allows to choose "No wait" or "AINS" (Automatically in service)

• Click on "Declare".

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

• Select the Network Element in the Tree structure, e.g. NE: 151.98.27.112

• Select the "board level" option

• In "Autoprovisioning Mode", select "AUTOEQ-AUTOFC" option

• Click on "Save".

To remove a card

• Select the unit in the Tree structure of the Main window of the Alcatel-Lucent 1850 TSS-100 CT (ZIC)

• Select "OOS" in the "Primary state" field

• Click on "Undeclared".

To modify the type of the optical interface type of a unit

• Select the unit



2-13

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

• Select "OOS" in the "Primary state" field

• Select the optical module in the Tree structure

• Select "Modify Equipment" than choose the new interface type in the "Equipment expected" field

• Click on "Modify".

The equipment configuration complies with the units inserted into the equipment being tested.

Remote inventory

Unit part number and serial number check to verify compliance with what specified in the "Plant documentation" and the "Factory test report sheet".

Procedure

• Select the unit in the Tree structure of the Main window

• Select "Remote inventory"; a new window opens, showing the relevant data.

Cross-Connection settings for Local Measures with Craft Terminal

The following are the characteristics of the initial "Cross connection":

• All ports must be unidirectionally matrix loopback connected

• All possible synchronisms must be excluded

• The equipment works in "Free-running" mode.

Note: For a detailed description of the software menu refer to theUser Provisioning Guide (see “Related information” (p. 1-xii))

Standard connections

Use the procedures reported in Chapter 4, “Connections, configurations and characteristics” on page 4-1, for the unidirectional matrix loopback connections of all ports present (of any type of bit rate).

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



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


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

3 Tests and measurements

Purpose

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

Contents


• “Instruments, Accessories and related documents” (p. 3-2)

• “Connection points position” (p. 3-4)

• “Local Measures list and operating sequence” (p. 3-8)

• “Point-to-point measures list and operating sequence” (p. 3-41)

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

Instruments, Accessories and related documentsTests and measurements


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

Instruments, Accessories and related documents

Table 3-1 Instruments

Table 3-2 Accessories

REF. INSTRUMENTS Qty CHARACTERISTICS

a. Pattern Generator / Error Detector

1 Signals available:- STM-1/4/16 optical, G.957 compliant- Ethernet 10/100 Mbps- Gb Ethernet, 10 Gb Ethernet

b. Optical power meter (radiometer)

1 2nd window; 3rd window

c. Single-mode variable optical Attenuator (VOA)

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

d. Digital multimeter 1

e. Craft terminal (Personal Computer)

Refer to the User Provisioning Guide (see “Related information” (p. 1-xii)). It can be supplied by Alcatel-Lucent.

f. Frequency counter 1 10 MHz ±1 Hz

REF. ACCESSORIES Qty CHARACTERISTICS

g. Coaxial Cables 2 Terminations:- Instrument side depending on (a.)- Equipment side depending on type of DDF

h. 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

i. Optical loop 4 Terminations dependent on unit/ODF connectors - Loss=12 dB

j. CT (LAN) cable 1 Termination:- RJ45 connector (LAN port) on PC- RJ45 connector on MT100 (CT port) - (16)

Instruments, Accessories and related documentsTests and measurements


3-3

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

Table 3-3 EC debugger cable pinout

k. EC100 debugger cable 8DG25468AA--(see next Table 3-1)

1 Termination:- SUB-D 9-pin connector on PC (COM1 port)- mUSB connector on EC100 (Debugger port) - (20)

l. Ethernet cable 1 Termination:- RJ45 connector (LAN port) on PC- RJ45 connector on EC100 (Debugger port) - (19)

m. Cables for synchronism 1 Termination:- Instrument (g.)- Synchronism termination (120 or 75 ohm)

n. Single-mode single-fiber splices 4 Terminations dependent on unit/ODF connectors, radiometer and attenuator

o. Multi-mode single-fiber splices 4 Terminations dependent on unit/ODF connectors, radiometer and attenuator

p. Fixed attenuators kit (suggested) 1 Suggested values: 1, 2, 3, 4, 5, 6 dB - MU type

q. Fixed attenuators kit (suggested) 1 Suggested values: 1, 2, 3, 4, 5, 6 dB - SC type

r. Cleaning kit for optical fibers 1

Mini USB male Signal SUB-D 9 pin female

Pin 3 TX Pin 3

Pin 2 RX Pin 2

Pin 5 GND Pin 5

Pin 1 DTR Pin 4

REF. ACCESSORIES Qty CHARACTERISTICS

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

Connection points positionTests and measurements


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

Connection points position

Figure 3-1 Common cards connection points position

1 A 1 B

2 A 2 B

3 4 5 6 7 8 9 1 0 1 11 2 1 3 1 4 1 5

A C C E S S C A R D S

T R A F F IC C A R D S

E X T E N S IO N IN T E R F A C E

1 6

1 7

1 8

1 9

S lo t 1 2 3 4 5 6 7 8 9 1 0 1 1 1 2 1 3 1 4 1 5 1 6 1 7

S lo t 2 5 2 6 2 7 2 8 2 9 3 0 3 1 3 2 3 3 3 4 3 5 3 6 3 7 3 8 3 9 4 0



3-5

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

Table 3-4 Numbering and functions referred to the common cards Connection Points

ACCESS POINT Slot FUNCTION

1.

EXTENSIONINTERFACE

Power Supply positive pole Connector (RTN)

2. Power Supply negative pole Connector (-48VDC)

3. Mechanical Ground Connector

4. 25-pin female Sub-D connector for Housekeeping (HK)

5. 25-pin female Sub-D connector for Auxiliary Channels (AUX)

6. 9-pin male Sub-D connector for Rack Lamps 1 (RL1); it is connected to the TRU (or to the shelf above)

7. 9-pin female Sub-D connector for Rack Lamps 2 (RL2); it is connected to the shelf below

8. 15-pin female Sub-D connector for Remote Alarms (RA)

9. 15-pin female Sub-D connector for shelf identifier (ShID)

10. RJ45 connector for step-up A signals

11. RJ45 connector for step-up B signals

12. Synch type (balanced/unbalanced) selection (COAX/DIFF)

13. 75-Ohm Coax unbalanced connectors for (top to bottom):• Synch A Tx• Synch A Rx• Synch B Tx• Synch B Rx

14. 9-pin Sub-D female balanced connector (120 Ohm) for SYNCH A

15. 9-pin Sub-D female balanced connector (120 Ohm) for SYNCH B

16. 9, 10 RJ-45 connector: 10-/100-Mbps LAN interface for Craft Terminal (ZIC) connection

17. 9, 10 RJ-45 connector; 10-/100-Mbps redundant LAN management interfaces (Q-interfaces) to connect the 135x NMS (DCN)

18. 1, 2 RJ45 connector: 10-/100-Mbps ETH debug interface

19. 1, 2 RS232 on mUSB debug connector

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



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

Table 3-5 TSS-100 traffic cards connection points

CARD Slot FUNCTION

1P10GSO03 to 0613 to 16

10-Gbps (STM-64/OC-192) optical card with optical connections on XFP module

4P2G5SO03 to 0613 to 16

2.5-Gbps (STM-16/OC-48) optical card with optical connections on SFP modules. In case only the first two ports/SFPs are used, the unit can also be plugged in slots 7, 8, 11, 12 (5G slots)

8PSO03 to 0811 to 16

155 -/622-Mbps (STM-1/OC-3 - STM4/OC-12) optical card with optical connections on SFP modules. It also supports electrical connections on the access module.

PP10G03+04, 05+06, 07+08, 11+12, 13+14, 15+16

10G Packet (Transport) Processor; it is a Layer 2 data aggregator capable of switching incoming data from two access cards (PE8XGE) equipped with eight SFPs or one access card (PEX10GE) equipped with one XFP, and traffic coming from the matrix unit. PP10G doesn't provide optical connections

PE8XGE 25 to 40Packet Expander able to collect 8 SFP 10/100/1000 baseT / 1000 baseX channels and to route them to the PP10G.Optical connections are on SFP modules

PEX10GE 25 to 40Packet Expander routes one 10 GE channel to the PP10G.Optical connection is on XFP module

E1DS1M

5 to 7 (W) 8 (W or P) 1

11 (W or P)12 to 14(W)

56 x E1 (DS1) PDH multiplexer card for balanced and unbalanced interfaces. The electrical accesses are located on two 28 x E1 (DS1) access cards (E1UAC and E1DS1BAC, see below)

E1UAC 25 to 40Collects 28 E1 (DS1) channels, connected to 64 x 75 Ohm unbalanced coax connectors, available on the front panel

E1DS1BAC 25 to 40Collects 28 E1 (DS1) channels, connected to 2 x 120 Ohm Sub-D High Density 78-pin female balanced connectors

E1DS1PAC31, 32 or

33, 34

28-Port E1/DS1 Access Protection. It controls protection switching for the E1/DS1 modules in its protection group. It doesn't have any connector on its front plate

E3DS3TM

5 to 7 (W)8 (W or P) 2 11 (W or P)12 to 14(W)

24 x E3 (DS3) PDH multiplexer card for balanced and unbalanced interfaces. The electrical accesses are located on two 12 x E3 (DS3) access cards (12XE3AC and 12XDS3AC, see below)

12XE3A 25 to 40Collects 12 x E3 channels, connected to 24 x (12 Tx and 12 Rx) 1.0/2.3 coax connectors, available on the front panel



3-7

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

12XDS3AC 25 to 40Collects 12 x DS3 channels, connected to 24 x (12 Tx and 12 Rx) 1.0/2.3 coax connectors, available on the front panel

E3DS3PAC31, 32 or

33, 34

12-Port E3 (DS3) Access Protection. It controls protection switching for the E3/DS3 modules in its protection group. It doesn't have any connector on its front plate

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

On the related unit

STM-1, STM-4, STM-16, multi-rate, GE, B&W SFP modules providing optical connections to the cards on which they are plugged. ETHMR only, provides electrical connections

SS-162C, SL-162C

On the related unit

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

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

On the related unit

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

XL-642COn the related

unit10-Gbps DWDM XFP, providing optical connections to the cards on which they are plugged

CARD Slot FUNCTION

Notes on Table 3-5, “TSS-100 traffic cards connection points” (p. 3-6)

1. Slots 8 and 11 are reserved for protection packs, but only one of them can be used for protection. That is, if the pack in slot 8 is the protection pack, then the pack in slot 11 is a working pack, and contrariwise

2. in slot 8 the unit protects the group in slots 5 to 7, in slot 11 the unit protects the group in slots 12 to 14

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

Local Measures list and operating sequenceTests and measurements


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

Local Measures list and operating sequence

Purpose

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

Contents

This paragraph contains the following topics:

• “Free running frequency check” (p. 3-9)

• “Electrical (PDH) ports test and EPS check” (p. 3-11)

• “Optical SDH (STM-1/4/16/64) ports test” (p. 3-13)

• “Optical GE and 10GE ports test” (p. 3-15)

• “DATA transport tests” (p. 3-17)

– “GE Transport on VC4-xV” (p. 3-17)

– “10GE Transport on VC4-xV” (p. 3-20)

– “Q-Bridge switching test, untagged frames” (p. 3-23)

• “Higher order SNCP protection check (line ports)” (p. 3-26)

• “Lower order SNCP protection check (line ports)” (p. 3-28)

• “Protection test MATRIX/CRU EPS” (p. 3-30)

• “Synchronism priority and Holdover (if present)” (p. 3-32)

• “Alarms check (if connected)” (p. 3-34)

• “Final checks” (p. 3-40)



3-9

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

Free running frequency check

Purpose

To verify the correct value of the frequency of the oscillator on the MATRIX.

Test instruments (see Table 3-1, “Instruments” (p. 3-2))

• Craft Terminal (e.)

• Frequency Counter (f.)

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

• Cable for synchronism (m.)

• CT (LAN) cable (j.)

Test Bench

Figure 3-2 Free-running frequency check BLOCK DIAGRAM

1850TSS-100

FREQUENCY COUNTER

Extension Interface

Coax Tx – Synch A or B)

C.T.

E

J

FREQUENCYCOUNTER

M

F

EC10

0 A

EC10

0 B

POW

100

A

POW

100

B

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



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

Procedure (refer to Figure 2-1, “Craft Terminal (ZIC) Main window” (p. 2-10) and the previous Figure 3-2, “Free-running frequency check” (p. 3-9)

• In the Client window, select the "Internal Synch" option in the "Synch" menu

• Check that no synchronism source has already been configured (the "PassportAID" field has to be empty)

• Connect the outgoing synchronism to the frequency counter

• In the Client window, select the "Output Synch" option in the "Synch" menu

• Check that no reference has been selected for each Timing Reference except for the internal oscillator block "G.813". On the contrary remove all the timing reference source from each Timing Reference as follows:

– Select the Timing Reference

– Select "Synch" -> "Internal Synch" -> select the "AID" -> click on "Release the assigned port"

– Check that the "Free running" "Operating mode" is present in the "Internal SYNCH Group" window

• Check that the frequency counter reads a measured value of 2048 kHz ±4.6 ppm.



3-11

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

Electrical (PDH) ports test and EPS check

Multi-demultiplexing check and AIS forwarding to the port (one by one port with software loop at matrix level)

Purpose

This test verifies the Bit Error Rate at the electrical port of DDF as specified for the connections reported in the Plant Documentation.

Test instruments (see Table 3-1, “Instruments” (p. 3-2))

• Craft Terminal (e.)

• Pattern Generator/Error Detector (a.)

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

• Coaxial cable (g.) or Shielded pair (h.)

• CT (LAN) cable (j.)

Test Bench (see Figure 3-3, “PDH Ports test” (p. 3-12))

• Set up the matrix loop via software.

Note: Different electrical connections can be performed,according to the access card used

Procedure

• Preset the instrument to transmit a signal (based on the type of port used) with the following requirements:

• Connect the Pattern Generator to the input and the Error Detector to the output of the port to be tested.

• Check that the Error Detector has read no errors and that there are no alarm indications on the units involved

• Disconnect the Pattern Generator from the port

• Check if AIS signal, all ONES, is present (sent from the output side of the port connected to the Error Detector)

• Other alarms present on the Error Detector could be: PATTERN LOSS

E1 interface E3 interface T3 interface

Bit rate 2048 Kbit/s ± 50 ppm 34368 Kbit/s ± 20 ppm 44736 Kbit/s ± 20 ppm

Code HDB3 HDB3 B3ZS

Sequence 215 -1 pseudorandom 215 -1 pseudorandom 215 -1 pseudorandom

Level 2.3Vp (75 ohm) or 3Vp (120 ohm)

1 Vp (75 ohm)

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



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

• Repeat the checks on all the other ports, checking the absence of errors for few seconds

EPS check

• For EPS protection check, connect the Pattern Generator at the I/O of the protected card (E1DS1M for E1 signals, E3DS3TM for E3 signals) and check 0 errors. Extract the protected port (in slot 5 in the previous figure) and check "0" errors after an initial burst of errors. Check also the AIS alarm as previously described

• Repeat the check on all the ports included in the protecting board

• Repeat the check for all the present protecting boards (in case of EPS 1+1).

Figure 3-3 PDH Ports test

56XE1 protecting

BLOCK DIAGRAM

Pattern Generator Error Detector

Port Loop

1850TSS-100MATRIX

"n"

J C.T. E

DDF

PATTERN GENERATOR

ERROR DETECTOR

Rx PORT Tx PORT

A

G H or

H G or

EC10

0EC

100

POW

100

POW

100

28XE1 75 ohm 28XE1 120 ohm

56XE1



3-13

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

Optical SDH (STM-1/4/16/64) ports test

Purpose• Let through data to check if the ports are properly connected to the ODF• Check PTx• Check that ALS is working properly.

Test instruments (see Table 3-1, “Instruments” (p. 3-2))• Craft Terminal (e.)• Pattern Generator/Error Detector (a.)• Power meter (b.)• x dB fixed attenuator

Accessories (see Table 3-2, “Accessories” (p. 3-2))• Single-mode (n.) or multi-mode (o.) single-fiber splices, according to the interface type• CT (LAN) cable (j.)

Test Bench (see Figure 3-4, “STM-n Ports test” (p. 3-14))


Refer to Table 3-5, “TSS-100 traffic cards connection points” (p. 3-6) for SFP / XFP list, para. “SFP and XFP modules optical characteristics” (p. 4-16) for technical specifications.

Procedure

• By means of CT applications, enable the Automatic Laser shutdown, as shown in “Procedure to enable and disable the ALS” (p. 4-15), on the looped optical port in test

• PTx power test

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

STM-1 interfaceBit rate 155,520 kbit/sCode/interface (SFP) S-1.1, L-1.1, L-1.2 (see “SFP and XFP modules optical characteristics”

(p. 4-16) for details)Type optical STM-1



STM-16 interfaceBit rate 2.48832 Gbit/sCode/interface (SFP) I-16.1, S-16.1, L-16.1, L-16.2, APD CWDM, PIN CWDM (see “SFP and

XFP modules optical characteristics” (p. 4-16) for details)Type optical STM-16

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



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

• Insert the signal and test error-free data transit

• Connect the power meter to the optical port output being tested

• Check that the optical power is within the range stated on the tables in “SFP and XFP modules optical characteristics” (p. 4-16)

• Disconnect the pattern generator from the STM-N input port. Check no power on Power Meter

• Repeat the test for each optical unit.

Figure 3-4 STM-n Ports test

Note: Insert x dB fixed attenuator, according to the opticalcharacteristics of instruments and boards

STM-64 interfaceBit rate 9.95328 Gbit/sCode/interface (SFP) B&W = I-64.1, S-64.2b, P1L1-2D2,

APD DWDM for long haul (ITU-T G.698.2 - DW100U-2AXC).See ““SFP and XFP modules optical characteristics” (p. 4-16) for details

Type optical STM-64

BLOCK DIAGRAM

Pattern Generator Error Detector Port "n" Loop

1850TSS-100

MATRIXSDH Optical

J C.T. E

ODF

PATTERN GENERATOR

ERROR DETECTOR

Rx PORT Tx PORT

T

POWER METER A

O

B

T N or

N O or

EC10

0 A

EC

100

B

POW

100

A

POW

100

B

8PSO 1P10GSO 4P2G5SO



3-15

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

Optical GE and 10GE ports test

Purpose• Let through data to check if the ports are properly connected to the ODF• Check PTx

Test instruments (see Table 3-1, “Instruments” (p. 3-2))• Craft Terminal (e.)• Pattern Generator/Error Detector (a.)• Power meter (b.)• x dB fixed attenuator


Test Bench (see Figure 3-5, “GE and 10GE ports test” (p. 3-16))


Refer to Table 3-5, “TSS-100 traffic cards connection points” (p. 3-6) for SFP / XFP list, para. “SFP and XFP modules optical characteristics” (p. 4-16) for technical specifications.

Procedure

• By means of CT applications, set "up" the Administrative state of the unit as described below

– In the Tree structure, select the access unit (PEX10GE in slot 28 or PE8XGE in slot 31), e.g., Brd28: PEX10GE), the module (e.g., Mdl1: 10GB), and the port (e.g., Prt1: 10GB)

– In the "State" field of the Client window, set "up" the "Admin state".

• PTx power test

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

For further details, see “B&W SFPs Optical Characteristics” (p. 4-16).

APD and PIN CWDM SFPs are also available to manage colored wavelengths. For further details, see “B&W XFPs Optical Characteristics” (p. 4-21)

Gigabit Ethernet interface on optical SFP (IEEE 802.3)Interface type 1000 Base-S 1000 Base-L 1000 Base-Z 1000 Base-BBit rate 1.250 Gbps 1.250 Gbps 1.250 Gbps 1.250 GbpsWavelength 820 -> 860 nm 1270 -> 1355 nm 1540 -> 1570 nm 1480 -> 1500 / 1260 -> 1360

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 GbpsWavelength (nm) 840->860 1290->1330 1530->1565 1530->1565 C-Band, 100-GHz grid

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



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

For further details, see “B&W XFPs Optical Characteristics” (p. 4-21), and “DWDM XFPs Optical Characteristics” (p. 4-22)

– Insert the signal and test error-free data transit

– Connect the power meter to the optical port output being tested

– Check that the optical power is within the range stated on the table in “B&W XFPs Optical Characteristics” (p. 4-21), and “DWDM XFPs Optical Characteristics” (p. 4-22)

– Set the "Admin. State" "down" then check that there is no power on the Power Meter

– Repeat the test for each optical unit.

Figure 3-5 GE and 10GE ports test


J C.T. E

POWER METER A

B

ODF

PATTERN GENERATOR

ERROR DETECTOR

Rx PORT Tx PORT

T O

T N or

N O or

PE8XGE

EC10

0 A

EC

100

B

POW

100

A P

OW

100

B

PP10G

BLOCK DIAGRAM


GbE or 10GEAccess Port

n

1850 TSS-100

PEX10GE

MATRIX

Packet Procesor



3-17

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

DATA transport tests

GE Transport on VC4-xV

• Check GE packets transport by means of VC4-xV (virtual concatenation).

Purpose• Check if the Virtual concatenated ETS cross-connection works properly at maximum

capacity of the Virtual concatenation group VC4-xV

• Let through data to check if the ports are properly connected to ODF

• Alarms detection.

Test instruments (see Table 3-1, “Instruments” (p. 3-2))• Craft Terminal (e.)• Pattern Generator/Error Detector (a.)• x dB fixed attenuator

Accessories (see Table 3-2, “Accessories” (p. 3-2))• Optical loop (i.).• Single-mode (n.) or multi-mode (o.) single-fiber splices, according to the interface type• CT (LAN) cable (j.)

Test Bench (see Figure 3-6, “Test of GE transport on VC4-xV” (p. 3-19))

Refer to Table 3-5, “TSS-100 traffic cards connection points” (p. 3-6) for SFP list, para. “SFP and XFP modules optical characteristics” (p. 4-16) for technical specifications.

Procedure

• Cross-connect the GE port (on PE8XGE access card) to the SDH port via the Packet Processor unit PP10G and the Matrix (MT100)

• By CT create a number of active VC4-xV (x = 7) on PP10G, as shown in “HO Unprotected Bidir. XC between a Remote data port (VCG, VC4-nV) and an STM-N port” (p. 4-7)

• Cross-connect the VC4-7V to an SDH port (STM-16 or STM-64), as shown in P“HO Unprotected Bidir. XC between a Remote data port (VCG, VC4-nV) and an STM-N port” (p. 4-7)

• Cross-connect the VC4-7V to one port of the 8 x 1 GE access card (PE8XGE), as shown in “HO unprotected bidir cross-connection between a local and a remote data port” (p. 4-5)

• Alarms detection:

The Pattern Generator must not be connected to PE8XGE.

– Perform the cross-connection as described above

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



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

– In the Tree structure, select the access unit PE8XGE (e.g., Brd29: PE8XGE), the module (e.g., Mdl1: ETHMR or 1000B), and the port (e.g., Prt1: 1 GB)

– In the "State" field, set "up" the "Admin state"

– In the Client window, check that the LOS alarm is present in the "Alarms" field (and the LED relevant the SFP in test is OFF).

– Connect the Pattern Generator/Error Detector to the port/SFP to be tested, and start transmitting at 100% of the available bandwidth

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

– In the Tree structure, select the PP10G unit (connected to PE8XGE) and the port (e.g., Prt1: VCG)

– In the "Physical" folder of the Client window, set "up" the "Admin state" in "State" field

– Open the optical loop on SDH unit

– In the Client window, check the presence of the TSF alarm on the remote port (on PP10G)

– 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.

Pattern Generator / Error detector setupPort type GEAuto negotiation OFFFrame length 1518 bytesBandwidth 100%

Optical interfaces (SFP) types (refer to “SFP and XFP modules optical characteristics” (p. 4-16) for details)

GE interface types (SFP on PE8XGE)

Optical B&W = 1000Base-SX/1000Base-LX/1000Base-ZX/1000Base-BXElectrical B&W = 1000 Base-TCWDM = APD (C8L1-1D2) for long haul

PIN (C8S1-1D2) for short haul



3-19

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

Figure 3-6 Test of GE transport on VC4-xV


PE8XGE

Optical loop

Pattern Generator/ Error Detector

ODF

A

N O

I

or

BLOCK DIAGRAM

Pattern Generator

Error Detector

GbEAccess

Port n

1850 TSS-100MATRIX

Packet Procesor

SDH Port

N Oor

N Oor

EC10

0 A

EC

100

B

POW

100

A P

OW

100

B

1P10GSO PP10G J

C.T. E

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



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

10GE Transport on VC4-xV

• Check 10 GE packets transport by means of VC4-xV (virtual concatenation).

Purpose• Check if the Virtual concatenated ETS cross-connection works properly with limited

capacity (7 VC4) of the Virtual concatenation group VC4-xV.

• Let through data to check if the ports are properly connected to ODF

• Alarms detection.


Accessories (see Table 3-2, “Accessories” (p. 3-2))• Optical loop (i.).• Single-mode (n.) or multi-mode (o.) single-fiber splices, according to the interface type• CT (LAN) cable (j.)

Test Bench (see Figure 3-7, “Test of 10GE transport on VC4-xV” (p. 3-22))

Refer to Table 3-5, “TSS-100 traffic cards connection points” (p. 3-6) for XFP list, para. “SFP and XFP modules optical characteristics” (p. 4-16) for technical specifications.

Procedure

• Cross-connect the 10GE port (on PEX10GE) to the SDH STM-64 port via the Packet Processor unit PP10G and the Matrix (MT100)

• By CT create a number of active VC4-xV (x = 1 to 64, 7 VC4 are used in current example, VC4-7V) on PP10G, as shown in “HO Unprotected Bidir. XC between a Remote data port (VCG, VC4-nV) and an STM-N port” (p. 4-7)

• Cross-connect the VC4-7V to an SDH port (STM-64), as shown in “HO Unprotected Bidir. XC between a Remote data port (VCG, VC4-nV) and an STM-N port” (p. 4-7)

• Cross-connect the VC4-7V to the 10 GE access card (PEX10GE), as shown in “HO unprotected bidir cross-connection between a local and a remote data port” (p. 4-5)

• Alarms detection:

The Pattern Generator must not be connected to PEX10GE.

– Perform the cross-connection as described above

– In the Tree structure, select the access unit PEX10GE (e.g., Brd29: PEX10GE), the module (e.g., Mdl1: 10GB), and the port (e.g., Prt1: 10GB)

– In the "State" field, set "up" the "Admin state"



3-21

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

– In the Client window, check that the LOS alarm is present in the "Alarms" field (and the LED relevant the XFP in test is OFF)

– Connect the Pattern Generator/Error Detector to the port/XFP to be tested, and start transmitting at 10% of the available bandwidth

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

– In the Tree structure, select the PP10G unit (connected to PEX10GE) and the port (e.g., Prt1: VCG)

– In the "Physical" folder of the Client window, set "up" the "Admin state" in "State" field

– Open the optical loop on SDH unit

– In the Client window, check the presence of the TSF alarm on the remote port (on PP10G)

– 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.

Pattern Generator / Error detector setupPort type 10 GEAuto negotiation OFFFrame length 1574 bytesBandwidth 10%

Optical interfaces (XFP) types (refer to “SFP and XFP modules optical characteristics” (p. 4-16) for details)

10GE interface types (XFP on PEX10GE)

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

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



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

Figure 3-7 Test of 10GE transport on VC4-xV


PEX10GE

BLOCK DIAGRAM


10 GbEAccess

Port

1850 TSS-100MATRIX

Packet Procesor

SDH Port

EC10

0 A

EC

100

B

POW

100

A P

OW

100

B

1P10GSO PP10G

Optical loop


ODF

A

N O

I

or

N Oor

N O or

J C.T. E



3-23

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

Q-Bridge switching test, untagged frames

Purpose• Check that the Q-Bridge is able to transport tagged traffic among the ports set.



Test Bench (see Figure 3-8, “Bridge VLAN switching test, untagged frames” (p. 3-25))

Refer to Table 3-5, “TSS-100 traffic cards connection points” (p. 3-6) for SFP list, para. “SFP and XFP modules optical characteristics” (p. 4-16) for technical specifications.

Procedure

• In the Client window, select the "Bridge Config" option in "Data" menu

• In "Bridge Configuration" field of the "Bridge Management" tab, set "Bridge Type" as "Virtual" than click on "Save & Continue"

• Now we have to set the port as a Bridge: select the packet processor unit, clicking on e.g., Brd15: PP10G in the Tree structure. In the Client window, check that "L2 switch mode" is "bridge"

The bridge has been created. Now the ports (two GE ports in this case) have to be connected to the bridge.

• The following step is to set the Ethernet local port. Select the board (e.g., Brd29: PE8XGE), the module (e.g., Mdl: 1000B) and the port (e.g., Prt1: 1GB). In the "Physical" tab of the Client window

– Set "bridge" the "Client type" of the "Ethernet port" field and save

– Set "Enable auto-negotiation" in "MAU" field and click on "Enable auto-negotiation"

– Set "up" the Administrative state" of the "State" field and save

• Click on the "Bridge" tab, than choose the VLAN to which this port has to be connected (e.g., "1" - it is the default VLAN created by the system). The VLAN tag is located at the bottom of this window. A new window appears showing the result of this procedure: this port has been connected to the chosen VLAN (1 in this case) of the bridge

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



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

• Repeat the previous procedure for the other GE port that has to be connected to this VLAN

• Connect the Pattern Generator/Error detector and check that no errors are read

Note: It is required to properly configure the instrument (sourceand destination address), so that Port A transmit to Port B.

Pattern Generator / Error detector setupPort type GEAuto negotiation ONFrame length 1518 bytesBandwidth 100%

Optical interfaces (SFP) types (refer to “SFP and XFP modules optical characteristics” (p. 4-16) for details)

GE interface types (SFP on PE8XGE)

Optical B&W = 1000Base-SX/1000Base-LX/1000Base-ZX/1000Base-BXElectrical B&W = 1000 Base-TCWDM = APD (C8L1-1D2) for long haul

PIN (C8S1-1D2) for short haul



3-25

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

Figure 3-8 Bridge VLAN switching test, untagged frames


BLOCK DIAGRAM

Pattern Generator

Error Detector

1850 TSS-100

GbEPort

MATRIX


ODF

A

GbEPort

PE8XGE

EC10

0 A

EC

100

B

POW

100

A P

OW

100

B

PP10G J

C.T. E

A

A B

B

A A B B Via Matrix

N Oor

N Oor

N O or

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



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

Higher order SNCP protection check (line ports)

Purpose• Verify the SNCP protection efficiency of higher order signals.


Accessories (see Table 3-2, “Accessories” (p. 3-2))• Optical loop (i.)• Single-mode (n.) or multi-mode (o.) single-fiber splices, according to the interface type• CT (LAN) cable (j.)

Test Bench (see Figure 3-9, “SNCP protection check (line ports)” (p. 3-27))

Refer to Table 3-5, “TSS-100 traffic cards connection points” (p. 3-6) for SFP/XFP list, para. “SFP and XFP modules optical characteristics” (p. 4-16) for technical specifications.

Procedure

• Cross-connect the AU4 of the tributary port and the AU4 of the line ports as reported on the table below. Performs the test using two different line (STM-16 or STM-64) ports per each tributary (STM-1/4) port

• Preset the instrument to transmit a signal with the following requirements:

• Check that no errors are read on the Error Detector

• Open one of the Optical loop present on the ODF

• Check after a transient condition that no errors are read by the Error Detector.

Type of protected cross-connections See ParagraphSTM-1 / STM-4 -> STM-16 / STM-64 “HO Bidir protected unstructured cross-connection between

an STM-1/STM-4 port and STM-n ports” (p. 4-4)



orSTM-4 interface

Bit rate 622,080 kbit/sCode/interface (SFP) S-4.1, L-4.1, L-4.2 (see “SFP and XFP modules optical characteristics”




3-27

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

Figure 3-9 SNCP protection check (line ports)


Note: Only one type of cross-connection is reported in the figure.The figure can change depending on the type of trib. port and onthe line port selected.

Optical loop

Optical loop

A

I

I

BLOCK DIAGRAM

Pattern Generator

Error Detector STM-1Port

PortLine

Loop

1850TSS-100

MATRIX

PortLine

Loop"A"

"B"

T T

ODF

Pattern Generator

Tx PORT

Error Detector

Rx PORT

ODF

JC.T. E

N Oor

4P2G5SO

EC10

0 A

EC

100

B

POW

100

A

POW

100

B

8PSO

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



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

Lower order SNCP protection check (line ports)

Purpose• Verify the SNCP protection efficiency of lower order signals.



Test Bench (see Figure 3-9, “SNCP protection check (line ports)” (p. 3-27))


Procedure

• Cross-connect the TU12 or TU3 of the tributary port and the TU12/ TU3 of the line ports as reported on the table below. Performs the test using two different line (STM-16 or STM-64) ports per each tributary (STM-1) port.

If the 2 Mbps or 34 Mbps or 45 Mbps is used, cross-connect the E1/E3/T3 signal with the relevant TU12/TU3 of the line ports as reported on the table below

Type of protected cross-connections See ParagraphTU12 -> STM-16 / STM-64 “Lower order (TU12) bidir protected XC between an

STM-1/STM-4 port and STM-n ports” (p. 4-8)TU3 -> STM-16 / STM-64 “Lower order (TU3) bidir protected XC between an STM-

1/STM-4 port and STM-n ports” (p. 4-11)34/45 Mbit/s -> STM-16 / STM-642 Mbit/s -> STM-16 / STM-64



3-29

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



• Open one of the Optical loop present on the ODF

• Check after a transient condition that no errors are read by the Error Detector.

TU12 / TU3 interfaceBit rate 155,520 kbit/sCode/interface (SFP) S-1.1, L-1.1, L-1.2 (see “SFP and XFP modules optical characteristics”

(p. 4-16) for details)Type optical STM-1Structure TU12 / TU3Payload VC12 bulk / VC3 bulk

E1 interface E3 interface T3 interfaceBit rate 2048 Kbit/s ± 50 ppm 34368 Kbit/s ± 20 ppm 44736 Kbit/s ± 20 ppmCode HDB3 HDB3 B3ZSSequence 215 -1 pseudorandom 215 -1 pseudorandom 215 -1 pseudorandomLevel 2.3Vp (75 ohm) or 3Vp

(120 ohm)1 Vp (75 ohm)

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



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

Protection test MATRIX/CRU EPS

Purpose• Check that EPS is working properly

• Check that in the following switching no data has been lost apart from an initial transient state.



Test Bench (see Figure 3-10, “MATRIX/CRU EPS protection check” (p. 3-31))


For the Alcatel-Lucent 1850 TSS-100 shelf configuration, refer to Figure 3-9, “SNCP protection check (line ports)” (p. 3-27)

Procedure

• Perform the same cross connection used for the previous SNCP protection test (refer to “Higher order SNCP protection check (line ports)” (p. 3-26) and “Lower order SNCP protection check (line ports)” (p. 3-28))



• Remove the WORKING matrix and insert it again; after a brief transient, check that no errors are read.

STM-1 interfaceBit rate 155,520 kbit/sCode/interface (SFP) S-1.1, L-1.1, L-1.2 (see “SFP and XFP modules optical

characteristics” (p. 4-16) for details)Type optical STM-1



3-31

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

Figure 3-10 MATRIX/CRU EPS protection check


Note: The figure can change depending on the type of trib. portand on the line port selected.

BLOCK DIAGRAM

Pattern Generator

Error Detector STM-1Port

Line Port STM-16/64

Loop1850TSS

MATRIX A

Loop"A"

"B"Line Port STM-16/64

MATRIX B

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



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

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.


Accessories (see Table 3-2, “Accessories” (p. 3-2))• Cable for synchronism (m.)• Single-mode (n.) or multi-mode (o.) single-fiber splices, according to the interface type• CT (LAN) cable (j.)

Test Bench (see Figure 3-11, “Synchronism priority and Holdover” (p. 3-33))


For the Alcatel-Lucent 1850 TSS-100 shelf configuration, refer to Figure 3-9, “SNCP protection check (line ports)” (p. 3-27)

Procedure

• Select "Internal Synch" option from the "Synch" menu of the Client window

• Now we have to select a timing reference clock for each timing reference.

The example given in the following assumes the presence of two reference clocks:

1. Clock derived from a STM-n port.

CT procedure to select a reference clock from the line signal, e.g. from an SDH unit:

– In the "AID" column of the Client window, select the reference clock (e.g. LINE REF SYS-1-1-0)

– In the new window, click on "Select" and choose the SDH unit, the module and the port. Than choose the Priority: "0" (it is the highest priority)

– Click on "Save & Continue"

2. External clock (2-MHz A or B) from the coax Rx connector (A or B) of the external interface (refer to Figure 3-1, “Common cards connection points position” (p. 3-4) and Figure 3-4, “Numbering and functions referred to the common cards Connection Points” (p. 3-5).

CT procedure to select a reference clock from a 2-MHz external clock:

– Select an external Timing reference in the "AID" field of the Client window

– Click on e.g., "EXTREF1-1-0". A new window opens



3-33

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

– In the new window, click on "Select" than choose the global synch. Source, e.g., BITS-0. In the "Unit" field of the "Synchro" window, the "Source" is BITS-1-1-0

– Select the priority e.g., "1"

– Select "Internal Synch." Option in "Synch." menu. The window shows that the chosen EXTERNAL REFERENCE (EXTREF-1-1-0) is associated with BITS-1-1-0

– Click on "Save & Continue"

3. Remove the STM-n optical cable (the highest priority)

4. Check on the Craft Terminal that the reference signal is extracted from the Timing Reference Block with priority (1); it is in "Autoswitch" state (External clock)

5. Remove the 2-MHz electrical cable (external clock)

6. Check on the Craft Terminal that the "Operating mode" is "Holdover".

Figure 3-11 Synchronism priority and Holdover


Note: The figure can change depending on the type of trib. portand on the line port selected.

A

Pattern Generator

Error Detector

J C.T. E

N O or

4P2G5SO

EC10

0 A

EC

100

B

POW

100

A

POW

100

B

ClockDDF

2048 KHz

M

BLOCK DIAGRAM

PortSTM-N

Timing& Sync.

Pattern Generator

Error Detector

2MHz Clock Generator

T0 Holdover

T3

T1

1850 TSS-100

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



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

Alarms check (if connected)

Purpose• Verify the correct restitution of the caused alarms and housekeeping alarms.

Test instruments (see Table 3-1, “Instruments” (p. 3-2))• Craft Terminal (e.)

Accessories (see Table 3-2, “Accessories” (p. 3-2))• 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.

• CT (LAN) cable (j.)Note: Vtest must not exceed 72V, and the output current from thepin must not exceed 50 mA, further the LED used should bear a 10mA current.

Test Bench (see Figure 3-12, “Alarms check” (p. 3-34))

Figure 3-12 Alarms check

Note: Check for alarms also on the EC100 front panel (see“EC100 card front view” (p. 4-23)).

BLOCK DIAGRAM

Vbatt 1

Vbatt 2

Vserv BREAKER B

BREAKER A

RACK LAMPS

POW100 – sl 17

POW100 – sl 18

RACK LAMPS connectorRM cable

1850TSS-100

LED Rs

-Vtest LAMP BLOCK

Vbatt1 BREAKER A

Vbatt 2BREAKERB

J C.T. E EC

100

A

EC10

0 B

POW

100

A

POW

100

B

CRITICAL MAJOR MINOR

slot

17

Slot

18

DDF



3-35

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

1. Primary Power Supply alarm check

Procedure

• Switch-OFF one Primary power supply (Breaker A)

• Verify that the NURG indication at the top of the rack (rack lamps) lights ON

• Verify that the NURG (minor) alarm LED of the EC100 lights ON, point (15) in Figure 4-1, “EC100 card (Equipment Controller) - front view” (p. 4-23)

• Verify that the MINOR alarm LED lights ON, in the External Interface panel (see Figure 3-12, “Alarms check” (p. 3-34))

• Verify that the "Lamps block", connected to the NURG pin of the Remote Alarms connector, turns ON

• In the Tree structure, click on the shelf (e.g. Shelf1: S100F)

• Verify the presence of the APWR (power A) alarm, in the "Alarms & Conditions" field

• Switch-ON Breaker A.

• Switch-OFF one Primary power supply (Breaker B)

• Verify that the NURG indication at the top of the rack (rack lamps) lights ON

• Verify that the NURG (minor) alarm LED of the EC100 lights ON, point (15) in Figure 4-1, “EC100 card (Equipment Controller) - front view” (p. 4-23)

• Verify that the MINOR alarm LED lights ON, in the External Interface panel (see Figure 3-12, “Alarms check” (p. 3-34))

• Verify that the "Lamps block", connected to the NURG pin of the Remote Alarms connector, turns ON

• In the Tree structure, click on the shelf (e.g. Shelf1: S100F)

• Verify the presence of the APWR (power A) alarm, in the "Alarms & Conditions" field

• Switch-ON Breaker B.

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



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

2. Remote alarms check (if present)

Refer to Figure 3-1, “Common cards connection points position” (p. 3-4) and Figure 3-13, “Extension interface electrical connectors location and pinout” (p. 3-39) for Rack Lamps (RL) and Remote Alarms (RA) connectors location and pinout.

• If present, remove all the alarms

• Originate the alarms as instructed below and verify that the Lamps block turns ON

Note: N.B.The "lamp block" must be connected to the remotealarm pin in test.

Table 3-6 Rack alarms connector pin-out

RA = Remote Alarm

INT Extract one unit

URG Disconnect the multiplexing SDH unit loop

NURG Increase the attenuation with the optical attenuator

TOR Disconnect one station battery (breaker 1)

TAND Disconnect two station battery (breaker 1 and 2)

# Pin Signal Description1 RA_ANDBATT Fault or loss of both station batteries

2 RA_ORBATT Fault or loss of one station battery

3 RA_URG Urgent alarm

4

5 RA_ANC Fault or loss of both equipment-internal service power supplies

6

7 RA_NURG Not urgent alarm

8

9 RA_ORC Fault or loss of one equipment-internal service power supply

10

11 RA_INT Internal alarm

12

13 RA_IND Indeterminate alarm

14

15 RA_REF Voltage reference of remote alarms

16 GND Electrical ground - Case




3-37

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

3. Rack lamps check

Procedure

Refer to Figure 3-1, “Common cards connection points position” (p. 3-4) and Figure 3-13, “Extension interface electrical connectors location and pinout” (p. 3-39) for Rack Lamps (RL) connector location and pinout.

• If present, remove all the alarms

• Originate the alarms as instructed below and verify that the related Rack Lamps LED at the top of the rack (TRU) turns ON.

4. Housekeeping alarms check (if present)

Procedure

Refer to Figure 3-1, “Common cards connection points position” (p. 3-4) and Figure 3-13, “Extension interface electrical connectors location and pinout” (p. 3-39) for HK connector location and Table 3-7, “Housekeeping connector pin-out” (p. 3-38) for HK connector pinout.

• Select "Housekeeping" option in the "System" menu of the Client window. The four "External Controls" (CPO) and the eight "External input signals" (CPI) are displayed on the CT

• Connect one housekeeping input (HK_IN) alarm pin at a time to the HK-REF (pin 24) and check the alarm detection on the CT in the "Type" field (it has to be set "Active low". This is the default setting)

• Configure the Housekeeping output (HK_OUT) alarm

• Connect the "Lamp block" between the N and P contacts of the couple of HK-OUT signal to be tested (i.e. between HK_OUTN_1 and HK_OUTP_1)

• By clicking on each HK (output or input) it is possible to set the Alarms "Polarity": "Active low" or "active high". The default setting is "active low"

URG Extract one unit (in service). Moreover this procedure turns-ON the major (M) LED on EC100. The major alarm is also displayed on CT; for checking:

• Click on the "Alarms" tab of the Client window, than on "View all alarms and conditions".

NURG Switch OFF one Breaker. Moreover, this procedure turns ON the minor (m) LED on EC100. The minor alarm is also displayed on CT; for checking:

• Click on the "Alarms" tab of the Client window, than on "View all alarms and conditions"

MEM With an URG or NURG alarm raised, press the "alarm cut-off key" (point 11) on EC320. Moreover this procedure turns-ON the Attended (AT) alarm LED on EC100

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



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

• Verify that the related alarm is present in the "Type" field, by observing that the "lamp block" turns ON; the alarm is also raised on the CT.

Table 3-7 Housekeeping connector pin-out

HK = Housekeeping

# Pin Signal Description1

2 HK_OUTN_1CPO1

# 1 Output; N wire

3 HK_OUTP_1 # 1 Output; P wire

4

5 HK_OUTN_2CPO2

# 2 Output; N wire


7

8 HK_OUTN_3CPO3

# 3 Output; N wire


10

11 HK_OUTN_4CPO4

# 4 Output; N wire


13

14

15 HK_IN1 CPI1 # 1 Input








23

24 HK_REF Voltage reference of input housekeeping

25





3-39

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

Figure 3-13 Extension interface electrical connectors location and pinout

5. Fan 19" alarm test

Procedure

• Extract the FAN unit

• Click on "alarms" tab in the Client window, than on "View all alarms & conditions"

• Verify that the TMPRORMVL alarm is present in the "Event" column.

HOUSEKEEPING

IN OUT 113

1425 113

1425 AUX CHANNELS

RACK LAMPS 1

RACK LAMPS 2

REMOTE ALARMS

SHELF IDENTIFIER

1 56 95 1 9 6

189 15189 15

STEPUPA

STEPUPB SYNCH A

SYNCH B

+ BATT B (RTN)

- BATT B (-48VDC)

+ BATT A (RTN)

- BATT A (-48VDC)

Mechanical Ground 5 1

9 65 1 9 6

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



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

Final checks

Purpose

• Check that the equipment has been properly configured.


Accessories (see Table 3-2, “Accessories” (p. 3-2))• CT (LAN) cable (j.)

The following operations must be carried out at the end of the STAND-ALONE tests:

• Disconnect all the cross-connections made on the equipment during the test operation phase

• If set down in the executive Design configure the following:

– The LAPD protocol based on the line interfaces implemented

– The IP address

– The NE local address NSAP

according to the customer requests.

Point-to-point measures list and operating sequenceTests and measurements


3-41

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

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. 3-8).

In this paragraph are detailed:

• “Rx Optical "line port" power check” (p. 3-42)

• “Optical "line port" link margin” (p. 3-43)

• “Point-to-point error monitoring check” (p. 3-45)

• “Ring error monitoring check” (p. 3-46)

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



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

Rx Optical "line port" power check

Purpose

• Verify the optical power of the signal received from the remote 1850TSS (Station B on the test bench).


• Optical power meter (b.)

Accessories (see Table 3-2, “Accessories” (p. 3-2))• CT (LAN) cable (j.)

Test Bench:

Figure 3-14 Rx Optical "line port" power check

Procedure

• Disconnect the Rx optical cable line from the ODF and connect it to the Power Meter input

• By means of the C.T. disable ALS (see Part “Procedure to enable and disable the ALS” (p. 4-15)) on the STM-N port in Station A

• Wait for 180 sec. and then check that the Rx optical power complies with the expected value.

Note: Rx power must be calculated on plant data. (PTx -Theoretical line attenuation based on Customer data).

• Repeat the check on the other port with "Line port" function.

1850TSS-100 1850TSS-100

ODF ODF

POWER METER

STM-N STM-N port port

Station - A Station - B

C.T.

Rx line optical cable

J



3-43

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

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 (see Table 3-1, “Instruments” (p. 3-2))• Pattern Generator/Error Detector (a.)

• Optical power meter (b.)

• Variable optical attenuator (c.)

• Craft Terminal (e.)• x dB fixed attenuator

Accessories (see Table 3-2, “Accessories” (p. 3-2))• Optical loop (i.)• CT (LAN) cable (j.)

Test Bench:

Figure 3-15 Optical "line port" link margin

1850TSS-100

ODF


VARIABLE

1850TSS-100

STM-NSTM-N STM-N STM-N ODFODF

loop

port port port port

ERROR DETECTOR PATTERN

GENERATOR

ODF

ATTENUATOR

POWER METER

C.T.

RX line cable

J

I

A

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



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

Procedure

STATION-A

• Connect the Pattern Generator output to the STM-N port input and the Pattern Generator input to the STM-N port output; all connections must be made on the ODF

• 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 ODF

• Preset the instrument according to the port type under test and send a fixed PRBS sequence.

STATION-B

• On the ODF make a loop on the STM-N concerned with the point to point connection

STATION-A

• With the Pattern Generator send a fixed PRBS sequence

• Check that the Error Detector has read no errors

• Increase the optical attenuation till errors are read on the Error Detector

• Reduce attenuation till no errors are read.

• Disconnect the optical cable from the STM-n input port (point A in previous Figure 3-15, “Optical "line port" link margin” (p. 3-43)) and connect it to the Power meter input

• Margin level must be minimum 4 dB better than the values reported in Part “SFP and XFP modules optical characteristics” (p. 4-16)

• Disable ALS through the C.T. (see “Procedure to enable and disable the ALS” (p. 4-15))

• 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. 3-42)) and the Rx optical power when introducing attenuation (as above explained) is the "link margin".

Repeat the check on the other port with "Line port" function.



3-45

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

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 (see Table 3-1, “Instruments” (p. 3-2))• Pattern Generator/Error Detector (a.)• x dB fixed attenuator

Accessories (see Table 3-2, “Accessories” (p. 3-2))• Optical loop (i.)

Test Bench:

Figure 3-16 Point-to-point error monitoring check

Procedure

STATION-A

• Connect the Pattern Generator output to the 1850TSS-100 "port" input and the Error Detector input to the Alcatel-Lucent 1850 TSS-100 "port" output; all the connection must be made on the ODF.

STATION-B


STATION-A

• Set the Pattern Generator according to the Alcatel-Lucent 1850 TSS-100 "port" characteristics and send a fixed PRBS sequence

• After a certain period of time check that no errors are read on the Error Detector

• Repeat the check on the other port with the Alcatel-Lucent 1850 TSS-100 "Line port" function.

1850TSS-100

ODF

Station - A Station - B 1850TSS-100

STM-N STM-N ODF

loop

port port port port

ERROR DETECTOR PATTERN

GENERATOR

ODF ODF I

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



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

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 (see Table 3-1, “Instruments” (p. 3-2))• Pattern Generator/Error Detector (a.)• x dB fixed attenuator

Accessories (see Table 3-2, “Accessories” (p. 3-2))• Optical loop (i.)

Test Bench

Figure 3-17 Ring error monitoring check

1850TSS-100

ODF


1850TSS-100

STM-N STM-NODFport port port

port

ERROR DETECTOR

ODF

ODF

STM-N port port STM-N

portport ODF

PATTERN GENERATOR

Station - C

I



3-47

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

Procedure

STATION-A

• Connect the Pattern Generator output to the 1850TSS-100 "port" input and the Error Detector input to the Alcatel-Lucent 1850 TSS-100 "port" output; all the connection must be made on the ODF.

STATION-B


STATION-A

• Set the Pattern Generator according to the Alcatel-Lucent 1850 TSS-100 "port" characteristics and send a fixed PRBS sequence

• After a certain period of time check that no errors are read on the Error Detector

• Repeat the check on the other port with the Alcatel-Lucent 1850 TSS-100 "Line port" function.

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

Restore factory defaultTests and measurements


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

Restore factory default

At the end of the turn-up procedure, it is suggested to perform

• In the Client window, select "DB backup & SID" option in the "System" menu

• In "Running Database" field of the Client window, click on "Restore factory default" and choose "Save current LAN configuration" or "Don't save current LAN configuration", according to the customer needs.

This procedure allows to remove all the settings performed during the turn-up procedure, and to clean the system database.


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

4 Connections, configurations and characteristics

Contents

This chapter mainly contains detailed lists of procedures step typically created with craft terminal configurations and optical characteristics.

These details are always referred from the previous chapters.


• “Unidir HO STM-n cross-connection - Matrix looped STM-n” (p. 4-2)

• “HO Bidir protected unstructured cross-connection between an STM-1/STM-4 port and STM-n ports” (p. 4-4)

• “HO unprotected bidir cross-connection between a local and a remote data port” (p. 4-5)

• “HO Unprotected Bidir. XC between a Remote data port (VCG, VC4-nV) and an STM-N port” (p. 4-7)

• “Lower order (TU12) bidir protected XC between an STM-1/STM-4 port and STM-n ports” (p. 4-8)

• “Lower order (TU3) bidir protected XC between an STM-1/STM-4 port and STM-n ports” (p. 4-11)

• “Procedure to enable and disable the ALS” (p. 4-15)

• “SFP and XFP modules optical characteristics” (p. 4-16)

• “EC100 card front view” (p. 4-23)

• “MT100 card front view” (p. 4-24)

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

Unidir HO STM-n cross-connection - Matrix looped STM-nConnections, configurations and characteristics


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

Unidir HO STM-n cross-connection - Matrix looped STM-n

Procedure

• In the Client window, select "TDM" option in the "Connection" menu

• Click on "Create": The "X Connection" window opens, allowing to choose the "CCT - Type" ("1WAY"), the unit and the AU4 to cross-connect.

BLOCK DIAGRAM


Port

1850TSS-100

MATRIX

STM-1/4

Loop STM-n

Unidir HO STM-n cross-connection - Matrix looped STM-nConnections, configurations and characteristics


4-3

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

• In "From" row, click on "select": in the new window, choose the board (e.g., Brd3: 1P10GSO) and click on the module (e.g., Mdl1: XI-641). In "Resource" field, all the available AU4 are listed. Click on one of them to choose (e.g., STM64AU4-1-1-3-1-1): it is presented in "From" row of the "X Connection" window.

• Now we have to choose the other AU4 to be cross-connected. In "To" row of the "X Connection" window, click on "select": in the new window, choose the same board (e.g., Brd3: 1P10GSO) and click on the module (e.g. Mdl1: XI-641). In "Resource" field, choose the same AU4 previously selected (e.g., STM64AU4-1-1-3-1-1): it is presented in "To" row of the "X Connection" window.

• Click on "Save XC & Exit" to create the cross-connection

• To check the created cross-connection, click on "Search" in "Filters" window. All the cross-connections performed on this equipment are displayed

• To remove a cross-connection, select the cross connection by clicking in the square on the left (v in the square) and click on "Delete".

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

HO Bidir protected unstructured cross-connectionbetween an STM-1/STM-4 port and STM-n ports

Connections, configurations and characteristics


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

HO Bidir protected unstructured cross-connection between an STM-1/STM-4 port and STM-n ports

Procedure

• In the Client window, select "TDM" option in the "Connection" menu

• Check that there are no cross-connections, by clicking on "Search" in "Filters" window: if cross-connections are presented, select all of them by clicking in the square on the left (v in the square) and click on "Delete"

• Click on "Create" in "Filters" window. The "X Connection" window opens, allowing to choose the "CCT - Type" ("2WAY-SNCP"), the units and the AU4s to cross-connect

• The "From", "Protecting" and "To" fields have to be filled, to create the cross connection

• In "From" row, click on "select" to choose the AU4 of the "Working" line. In the new window, choose the board (e.g. Brd3: 1P10GSO) and click on the module (e.g. Mdl1: XI-641). In "Resource" field, all the available AU4 are listed. Click on one of them to choose: (e.g., STM64AU4-1-1-3-1-1): it is presented in "From" row of the "X Connection" window

• In "Protecting" row, click on "select" to choose the AU4 of the "Protecting" line. In the new window, choose the board (e.g. Brd4: 1P10GSO) and click on the module (e.g. Mdl1: XI-641). In "Resource" field, all the available AU4 are listed. Click on one of them to choose: (e.g., STM64AU4-1-1-4-1-1): it is presented in "Protecting" row of the "X Connection" window

• In "To" row, click on "select" to choose the AU4 of the "Tributary" STM-1 unit. In the new window, choose the board (e.g., Brd6: 8PSO) and click on the module (e.g., Mdl2: SI-11). In the "Resource" field, the AU4 is listed. Click on it to choose. It is presented in "To" row of the "X Connection" window


• To remove a cross connection, select the cross-connection by clicking in the square on the left (v in the square) and click on "Delete".

HO unprotected bidir cross-connection between a localand a remote data port



4-5

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

HO unprotected bidir cross-connection between a local and a remote data port

To perform this cross-connection, it is required to configure a P2P connection between the local port (the access data unit) and the remote port (the packet processor).

• First we have to create the local port. In the Tree structure, click on the Data access unit (e.g., Brd37: PE8XGE). Select the (SFP or XFP) module (e.g., Mdl3: 1000B) and the GE port (e.g., Prt1: 1GB): In the Client window, set "ETS" the "Client type" in "Ethernet port" field then set "up" the "Administrative state" in "State" field and Save

• Now we have to create the Virtual Concatenated Group (VCG). Select a Packet Processor, (e.g., Brd3: PP10G), then click on "Create" at the bottom of the Client window. The new window is allowed to set:

– "VCG type" = VC4 for higher order VCG, VC12 for lower order VCG. Choose VC4

– "VCG position" = It indicates the first VCG available of this unit. As it is the first installation, its value is "1". If other VCG would be already created, a bigger number would be presented. We can keep it or manually change it, and choose a free VCG

– "Virtual concatenation level" = we set its value according to our needs. We can choose, e.g., 7 to concatenate a whole GE signal at 1250 Mbps with 7 VC4

– "Create identical copies" = it allows creating other VCG groups, having the same characteristics of the one above described (7 VC4). As an example:

– If we choose "1", it means 1 copy x 7 (Virtual Concatenation level) VC4 (VCG type) in VCG position = 1. In this example we choose "1"

– If we choose "2", it means 2 copy x 7 (Virtual Concatenation level) VC4 (VCG type) in VCG position = 1 and 2.

• Click on "Save & Exit".

• The newly created VCG group will appear at the bottom of the new window showing the "Remote Port" number (1 in this case), the "Resource" (e.g., VCG-1-1-3-1, meaning rack-subrack-slot-remote port number or VCG position). To delete a VCG group, select it (V in square on the left) and click on "Delete".

BLOCK DIAGRAM


(Ingress) 10 GE or GE

AccessPort

1850 TSS-100MATRIX

(Egress) Packet

ProcesorSDH Port

MATRIX

UNITS INVOLVED IN THIS XC

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

HO unprotected bidir cross-connection between a localand a remote data port



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

• Select the created VCG group and set "ETS" the "Client type" in "Ethernet port" field then set "up" the "Administrative state" in "State" field in the Client window and Save

• Select the "Server" tab on the top-left of the Client window, and set the "Active channels" as "7" (it has to be the same as the Virtual concatenation level)

• Click on "Save changes".

We have created the local port and the VCG in the remote port, now we have to create the cross-connection between the two ports.

• In the client window, select "ETS/P2P" in the "Connection" menu

• Click on "Create". The "P2P/ETS connection" window opens, allowing to choose the "Service type" = "P2P - BIDIR", the "ingress" and "egress" ports, and the "User label" as described in the following:

– In "Ingress port" row, click on "Select" - The new window requires to choose the Data access unit (e.g., Brd37: PE8XGE). Than click on the module (e.g., Mdl3: 1000B) and the GE port (e.g., DATA-1-1-25-3-1): it is presented in "Ingress port" field. This is the local port

– In "Egress port" row, click on "Select" - In the new window, click on the egress data unit, the same Packet Processor where we've just created the VCG, (e.g., Brd3: PP10G): the previously created VCG, e.g., VCG-1-1-3-1) is presented in the right side of the window. Click on it to insert in the "Egress port" row of the P2P/ETS connection" window

– Set the "User label", e.g., "2".

• Click on "Save & Exit".

HO Unprotected Bidir. XC between a Remote data port(VCG, VC4-nV) and an STM-N port



4-7

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

HO Unprotected Bidir. XC between a Remote data port (VCG, VC4-nV) and an STM-N port

Procedure

The procedure is performed on a STM-64 port. In case a STM-16 port is used, the procedure is the same.

• In the client window, select the "TDM" option in the "Connection" menu, than click on "Create". The "X Connection" window opens

• Select the "CCT - Type" = "2WAY" (bidirectional unprotected).

Now we have to cross-connect the VCG of the remote port (Packet Processor) with the (7) AU4s of the STM-64 unit. The Packet Processor is the one in slot 3 whose VCG has been already configured in the previous example (see “HO unprotected bidir cross-connection between a local and a remote data port” (p. 4-5)), with Virtual concatenation level = 7.

• Selection of the VCG VC4 of the remote data port - In the "From" row of the "X Connection" window, click on "select." In the new window, click on the unit (e.g., Brd3: PP10G). All the available VCGs are listed in "Current equipment resource" field. Click on the "Resource" belonging to the previously created VCG (it is suggested the first one), e.g., VCGVC4-1-1-3-2-1: it will be inserted in the "From" row

• Now we have to select the AU4 to be cross-connected to the previously chosen VCGVC4. In "To" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd13: 1P10GSO) and click on the module (e.g., Mdl1: XI-641), then click on one of the available AU4, e.g., STM64AU4-1-1-13-1-1

• As the Virtual Concatenation level is 7, to cross-connect all the VC4s of the VCG with 7 different AU4 of the SDH unit, repeat this procedure 6 times, to connect each one of the other 6 VC4 of the VCG, with one AU4 of the STM-64 unit


• To check the created cross-connection, select "TDM" option in the "Connection" menu, and then click on "Search" in the "Filters" window. All of the cross-connections performed on this equipment will be displayed.

BLOCK DIAGRAM


10 GE or GE

AccessPort

1850 TSS-100MATRIX

(From)Packet

Processor

(To) SDH Port

MATRIX

UNITS INVOLVED IN THIS XC

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

Lower order (TU12) bidir protected XC between an STM-1/STM-4 port and STM-n ports



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


Procedure

The first operation is to create the Lower order format structure in the involved AU, belonging to the tributary STM-1/4 unit ("To" port - STM-1 is used in current example) and the line ports ("From" and "Protecting" ports - STM-64 is used in current example. In the case where STM-16 ports are used, the procedure is the same).

• In the client window, select the "TDM" option in the "Connection" menu, and then click on "Create". The "X Connection" window opens

• Select the "CCT - Type" = "2WAY" (bidirectional unprotected)

• Creation of the Lower order format structure in the AU4 of the STM-1 tributary unit ("To" Port in figure). In "From" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd6: 8PSO), the module (e.g., Mdl3: SI-11), and the port in "Resource" field (the port/AU4 is presented in this field), e.g., STM1AU4-1-1-6-3-1. The chosen port is inserted in "From" row

• In "To" row of the "X Connection" window, click on "select". In the new window, click on LOPOOL-1-1-1" (lower order pool) in "Global resources" to insert it in "To" row

• Click on "Save XC & Continue". The AU4 (1) of the STM-1/4 unit in slot 6 has been LO structured

• Creation of the Lower order format structure in the AU4 of the STM-64 line working unit ("From" Port "A" in figure). In "From" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd3: 1P10GSO), the module (e.g., Mdl1: XI-641), and the port in "Resource" field (all the ports/AU4 are presented in this field), e.g., STM64AU4-1-1-3-1-3. The chosen port is inserted in "From" row

• In "To" row of the "X Connection" window, click on "select". In the new window, click on LOPOOL-1-1-1" (lower order pool) in "Global resources", to insert it in "To" row

• Click on "Save XC & Continue". The AU4 (3) of the STM-64 unit in slot 3 has been LO structured

BLOCK DIAGRAM


(To)Port

1850TSS-100

MATRIXLoop

Loop

STM-n

STM-n

STM-1/4

(From) Port “A”

(Protect) Port “B”




4-9

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

• Creation of the Lower order format structure in the AU4 of the STM-64 line protecting unit ("Protecting" Port "B" in figure). In "From" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd4: 1P10GSO), the module (e.g., Mdl1: XI-641), and the port in "Resource" field (all the ports/AU4 are presented in this field), e.g., STM64AU4-1-1-4-1-3. The chosen port is inserted in "From" row

• In "To" row of the "X Connection" window, click on "select". In the new window, click on "LOPOOL-1-1-1" (lower order pool) in "Global resources" to insert it in "To" row

• Click on "Save XC & Continue". The AU4 (3) of the STM-64 unit in slot 4 is LO structured

Now we have to cross-connect the TU12 of the tributary unit with the TU12s of the line units.

• In the client window, select "TDM" option in the "Connection" menu, and then click on "Create". The "X Connection" window opens

• Select the "CCT - Type" = "2WAY SNCP" (bidirectional protected)

• To choose the main/working line unit, in "From" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd3: 1P10GSO, the same previously selected as working in this procedure) and the module (e.g., Mdl1: XI-641). In "Current equipment resources", open (click on ) the AU4 previously LO structured, e.g., STM64AU4-1-1-3-1-3. All the available TU12s are presented. Choose one (e.g., MVC4TU12-1-1-9-6-1-1-1): it appears in "From" row of the "X Connection" window

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




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

• To choose the protecting line unit, in "Protecting" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd4: 1P10GSO, the same previously selected as protecting in this procedure) and the module (e.g., Mdl1: XI-641). In "Current equipment resources", open (click on ) the AU4 previously LO structured, e.g., STM64AU4-1-1-4-1-3. All the available TU12s are presented. Choose one (e.g., MVC4TU12-1-1-9-7-1-1-1): it appears in "Protecting" row of the "X Connection" window

• To choose the tributary unit, in the "To" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd6: 8PSO, the same previously selected as tributary in this procedure) and the module (e.g. Mdl3: SI-11). In "Resource", open (click on ) the AU4 previously LO structured, e.g., STM1AU4-1-1-6-3-1. All the available TU12 are presented. Choose the one has to be cross connected, e.g. MVC4TU12-1-1-9-5-1-1-1: it appears in "To" row of the "X Connection" window


• To check the created cross-connection, select "TDM" option in the "Connection" menu, than click on "Search" in "Filters" window. All the TDM cross-connections performed on this equipment will be displayed. The cross-connection is identified as in the following

• To remove a cross-connection, select it by clicking in the square on the left (v in the square) and click on "Delete".

Signal Type From ToLOVC12 2 WAY SNCP MVC4TU12-1-1-9-6-1-1-1 (active) MVC4TU12-1-1-9-5-1-1-1

MVC4TU12-1-1-9-7-1-1-1 (stdby)




4-11

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


Procedure

The first operation is to create the Lower order format structure in the involved AU, belonging to the tributary STM-1/4 unit ("To" port - STM-1 is used in current example) and the line ports ("From" and "Protecting" ports - STM-64 is used in current example. In case of STM-16 ports are used, the procedure is the same).

• In the client window, select "TDM" option in the "Connection" menu, and then click on "Create". The "X Connection" window opens

• Select the "CCT - Type" = "2WAY" (bidirectional unprotected)

• Creation of the Lower order (TU12) format structure in the AU4 of the STM-1 tributary unit ("To" Port in figure). In the "From" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd6: 8PSO), the module (e.g., Mdl3: SI-11), and the port in "Resource" field (the port/AU4 is presented in this field), e.g., STM1AU4-1-1-6-3-1. The chosen port is inserted in "From" row

• In the "To" row of the "X Connection" window, click on "select". In the new window, click on "LOPOOL-1-1-1" (lower order pool) in "Global resources" to insert it in "To" row

• Click on "Save XC & Continue". The AU4 (1) of the STM-1/4 unit in slot 6 has been LO structured. This procedure creates the TU12 structure, now we have to create the TU3 one

• Creation of the Lower order (TU3) format structure in the AU4 of the STM-1 tributary unit ("To" Port in figure). In the Tree structure of the Main window, select the AU4 previously LO structured: select the board (e.g., Brd6: 8PSO), the module (e.g., Mdl3: SI-11), and the port (e.g. Prt1: STM-1)

• In the Client window, click on the "CHANNELS" tag, then select the AU4 previously LO structured e.g., STM1AU4-1-1-6-3-1 (click on ): three TU12 groups (21 x TU12 each one) are displayed. Select one of them (click in the square on the top left) to create the TU3. The just created TU3, e.g. MVC4TU3-1-1-9-4-1, is now present in the Client window with a v in the square (one TU3 and two TU12 groups are now displayed)

BLOCK DIAGRAM


(To)Port

1850TSS-100

MATRIXLoop

Loop

STM-n

STM-n

STM-1/4

(From) Port “A”

(Protect) Port “B”

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




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

• Creation of the Lower order (TU12) format structure in the AU4 of the STM-64 line working unit ("From" Port "A" in figure). In "From" row of the "X Connection" window, click on "select". In the new window, we have to select the board (e.g., Brd3: 1P10GSO), the module (e.g., Mdl1: XI-641), and the port in "Resource" field (all the ports/AU4 are presented), e.g., STM64AU4-1-1-3-1-3. The chosen port is inserted in "From" row

• In "To" row of the "X Connection" window, click on "select". In the new window, click on "LOPOOL-1-1-1" (lower order pool) in "Global resources", to insert it into the "To" row

• Click on "Save XC & Continue". The AU4 (3) of the STM-64 unit in slot 3 has been LO structured. This procedure creates the TU12 structure, now we have to create the TU3 one

• Creation of the Lower order (TU3) format structure in the AU4 of the STM-64 line working ("From" Port "A" in figure). In the Tree structure of the Main window, we have to select the AU4 previously LO structured: select the board (e.g., Brd3: 1P10GSO), the module (e.g., Mdl1: XI-641), and the port (e.g., Prt1: STM-64)

• In the Client window, click on "CHANNELS" tag, then select the AU4 previously LO structured e.g., STM64AU4-1-1-3-1-3 (click on ): three TU12 groups (21 x TU12 each one) are displayed. Select one of them (click in the square on the top left) to create the TU3. The just created TU3, e.g., MVC4TU3-1-1-9-2-1, is now present in the Client window with a v in the square (one TU3 and two TU12 groups are now displayed)




4-13

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

• Creation of the Lower order (TU12) format structure in the AU4 of the STM-64 line protecting unit ("Protecting" Port "B" in figure). In the "From" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd4: 1P10GSO), the module (e.g., Mdl1: XI-641), and the port in "Resource" field (all the ports/AU4 are presented in this field), e.g., STM64AU4-1-1-4-1-3. The chosen port is inserted in "From" row

• In "To" row of the "X Connection" window, click on "select". In the new window, click on "LOPOOL-1-1-1" (lower order pool) in "Global resources", to insert it in "To" row

• Click on "Save XC & Continue". The AU4 (3) of the STM-64 unit in slot 4 has been LO structured. This procedure creates the TU12 structure, now we have to create the TU3 one

• Creation of the Lower order (TU3) format structure in the AU4 of the STM-64 line protecting unit ("Protecting" Port "B" in figure). In the Tree structure of the Main window, we have to select the AU4 previously LO structured: select the board (e.g., Brd4: 1P10GSO), the module (e.g., Mdl1: XI-641), and the port (e.g., Prt1: STM-64)

• In the Client window, click on "CHANNELS" tag, then select the AU4 previously LO structured e.g., STM64AU4-1-1-4-1-3 (click on ): three TU12 groups (21 x TU12 each one) are displayed. Select one of them (click in the square on the top left) to create the TU3. The just created TU3, e.g., MVC4TU3-1-1-9-5-1, is now present in the Client window with a v in the square (one TU3 and two TU12 groups are now displayed)

Now we have to cross-connect the TU3 of the tributary unit with the TU3s of the line units

• In the client window, select "TDM" option in the "Connection" menu, then click on "Create". The "X Connection" window opens

• Select the "CCT - Type" = "2WAY SNCP" (bidirectional protected)

• To choose the main/working line unit, in "From" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd3: 1P10GSO is the line working unit in this procedure) and the module (e.g., Mdl1: XI-641). In "Current equipment resources", open (click on ) the AU4 previously LO structured (e.g., STM64AU4-1-1-3-1-3), then select the TU3, e.g., MVC4TU3-1-1-9-2-1 (click on): it appears in the "From" row of the "X Connection" window

• To choose the protecting line unit, in the "Protecting" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd4: 1P10GSO is the line working unit in this procedure) and the module (e.g., Mdl1: XI-641). In "Current equipment resources", open (click on ) the AU4 previously LO structured (e.g., STM64AU4-1-1-4-1-3), and then select the TU3, e.g., MVC4TU3-1-1-9-5-1 (click on): it appears in "Protecting" row of the "X Connection" window

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




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

• To choose the tributary unit, in "To" row of the "X Connection" window, click on "select". In the new window, select the board (e.g., Brd6: 8PSO is tributary unit in this procedure) and the module (e.g., Mdl3: SI-11). In "Resource", open (click on ) the AU4 previously LO structured, e.g., STM1AU4-1-1-6-3-1, then select the TU3 (e.g., MVC4TU3-1-1-9-4-1 click on): it appears in the "To" row of the "X Connection" window


• To check the created cross-connection, select the "TDM" option in the "Connection" menu, than click on "Search" in the "Filters" window. All the TDM cross-connections performed on this equipment will be displayed. The cross-connection is identified as in the following:

• To remove a cross-connection, select it by clicking in the square on the left (v in the square) and click on "Delete".

Procedure to enable and disable the ALSConnections, configurations and characteristics


4-15

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

Procedure to enable and disable the ALS

Procedure

a. How to disable ALS:• In the Tree Structure, select the board and open it

• Select the module and open it

• Select the port

• Select the "Physical" folder of the Client window

• In the "Physical layer" field, set "Disabled" the "ALS enabled" option.

b. How to enable ALS• In the Tree Structure, select the board and open it

• Select the module and open it

• Select the port

• Select the "Physical" folder of the Client window

• In the "Physical layer" field, set "Enabled" the "ALS enabled" option.

DANGERWhen having to disconnect the Optical Fiber, follow the procedure stated below to avoid laser radiation. The triangle will indicate presence

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

SFP and XFP modules optical characteristicsConnections, configurations and characteristics


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

SFP and XFP modules optical characteristics

B&W SFPs Optical Characteristics

nb1: if SLM lasernb2: if MLM laser

ParameterETSI interface STM-1 S-1.1 STM-1 L-1.1 STM-1 L-1.2

UnitANSI interface IR-1 OC3 LR-1 OC3 LR-2 OC3

Digital 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 100 -> 155.520 2.048 -> 155.520 155.520 MbpsMin. extinction ratio 8.2 10 10 dBSpectral width

Max. -20dB bandwidth NA 1 nb1 1 nmMax. RMS width 7.7 3 nb2 NA nm

Minimum SMSR NA 30 if SLM laser 30 dBMax. chromatic dispersion -100 -> +100 -250 -> +250 1900 ps/nmMin. sensitivity, @ BER=1E-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) / Fibre type LC / SMF LC / SMF LC / SMFAcronym SS-11 SL-11 SL-12

ParameterETSI interface STM-4 S-4.1 STM-4 L-4.1 STM-4 L-4.2

UnitANSI interface IR-1 OC12 LR-1 OC12 LR-2 OC12

Digital 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 622.080 622.080 622.080 MbpsMin. extinction ratio 8.2 10 10 dBSpectral width

Max. -20dB bandwidth NA 1 1 nmMax. RMS width 2.5 NA NA nm

Minimum SMSR NA 30 30 dBMax. chromatic dispersion -100 -> +100 -250 -> +250 1900 ps/nmMin. sensitivity, @ BER=1E-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



4-17

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

ParameterETSI interface STM-16 I-16.1 STM-16 S-16.1

UnitANSI interface SR-1 OC48 IR-1 OC48

Digital signal STM-16 compliant with G.707 and G.958

Min. launched power -10 -5 dBm

Max. launched power -3 0 dBm

Allowed bit rates 2.48832 2.125; 2.48832 Gbps

Min. extinction ratio 8.2 8.2 dB

Spectral width

Max. -20dB bandwidth NA 1 nm

Max. RMS width 4 NA nm

Minimum SMSR NA 30 dB

Max. chromatic dispersion -12 -> +12 -100 -> +100 ps/nm

Min. sensitivity, @ BER=1E-10 -18 -18 dBm

Min. overload -3 0 dBm

Max. optical path penalty 1 1 dB

Max. receiver reflectance -27 -27 dB

Optical connector (Tx/Rx) / Fibre type LC / SMF

Acronym SI-161 SS-161

ParameterETSI interface STM-16 L-16.1 STM-16 L-16.2

UnitANSI interface LR-1 OC48 LR-2 OC48

Digital signal STM-16 compliant with G.707 and G.958

Min. launched power -2 -2 dBm

Max. launched power +2 +2 dBm

Allowed bit rates 2.48832 2.48832 Gbps

Min. extinction ratio 8.2 8.2 dB

Spectral width

Max. -20dB bandwidth (nm) 1 1 nm

Max. RMS width (nm) NA NA nm

Minimum SMSR 30 30 dB

Max. chromatic dispersion -250 -> +250 +1600 ps/nm

Min. sensitivity, @ BER=1E-10 -27 -28 dBm

Min. overload -8 -8 dBm

Max. optical path penalty 1 2 dB

Max. receiver reflectance -27 -27 dB

Optical connector (Tx/Rx) / Fibre type LC / SMF

Acronym SL-161 SL-162

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



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

ParameterETSI interface S-16.1 Multirate Multiformat

UnitANSI interface IR-1 OC48 Multirate Multiformat

Addressed wavelength 1290 -> 1330 nmMin. launched power -5 dBmMax. launched power 0 dBmAllowed bit rates 100 -> 2700 Mbps

Min. extinction ratioFor bit rates > 2.125Gbps = 8.2 For bit rates < 2.125Gbps = 9

dB

Spectral width

Max. -20dB bandwidth (nm) 1 nmMax. RMS width (nm) NA nm

Minimum SMSR 30 dBMax. chromatic dispersion -100 -> +100 ps/nmMin. sensitivity, @ BER=1E-10 -18 dBmMin. overload 0 dBmMax. optical path penalty 1 dBMax. receiver reflectance -27 dBOptical connector (Tx/Rx) / Fibre type LC / SMFAcronym SS-161AR

Parameter 1000Base-BX (FE) UnitDigital signal Gigabit Ethernet compliant with IEEE 802.3

DOWNLOAD UPLOAD

TX wavelength 1480 -> 1500 1260 -> 1360 nmMin. launched power -9.0 dBmMax. launched power -3.0 dBmAllowed bit rates 1.25 GbpsMin. extinction ratio 6.0 dBSpectral width

Max. -20dB bandwidth 0.88 NA nmMax. RMS width NA <3.5 nm

Minimum SMSR 30 NA dBMax chromatic disp. - ps/nmRX wavelength 1260 -> 1360 1480 -> 1500 GbpsMinimum sensitivity, @ BER=1E-10 with fiber -20.5 dBmMin. overload -3.0 dBmMax. optical path penalty - dBMax. receiver reflectance -12 dBOptical connector (Tx/Rx) / Fiber type LC/PC / 9/125 µm SMFTarget distance 10 KmAcronym / Interface type 1000B / 1000Base-BX10



4-19

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

Parameter 1000Base-SX 1000Base-LX/LH (10) 1000Base-ZX UnitDigital signal Gigabit Ethernet compliant with IEEE 802.3

Min. launched power -9.5 -11 0 dBm

Max. launched power -4 -3 +5 dBm

Allowed bit rates 1.250 1.250 1.250 Gbps

Min. extinction ratio 9.0 9.0 9.0 dB

Spectral width

Max. -20dB bandwidth

NA NA 1 nm

Max. RMS width 0.85 4 NA nm

Minimum SMSR NA NA 30 dB

Max. chromatic dispersion - - 1200 ps/nm

Min. sensitivity, @ BER=1E-10 -17 -19 -24 dBm

Min. overload 0 -3 0 dBm

Max. optical path penalty - - 2 dB

Max. receiver reflectance -12 -12 -12 dB

Optical connector (Tx/Rx) LC LC LC

Fiber type50/125µm MMF - 550m62.5/125µm MMF - 275m

10km 9/125 µm SMF50/125 µm MMF - 550m62.5/125µm MMF - 550m

9/125 µm SMF

Acronym 1000B 1000B 1000B

Interface type 1000Base-SX 1000Base-LX 1000Base-ZX

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



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

CWDM XFPs Optical Characteristics

CWDM SFP parameters APD CWDM PIN CWDM Unit

Addressed wavelength1471, 1491, 1511, 1531, 1551, 1571, 1591, 1611

in compliance with ITU-T G.694.2nm

Min. launched power 0 0 dBmMax. launched power +5 +5 dBmAllowed bit rates 0.002 -> 2.7 0.002 -> 2.7 GbpsMin. extinction ratio 8.2 8.2 dBMax. -20dB bandwidth 1.0 1.0 nmMinimum SMSR 30 30 dBMax. chromatic dispersion 1600 @ 1611 nm

1600 @ 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=1E-10 -28 -18 dBmStressed sensitivity -9.0 0 dBmMin. overload -1.0 0.5 dBmMax. optical path penalty 2.0 1.0 dBMax. receiver reflectance -27 -27 dBOptical connector / Fibre type LC / SMF LC / SMFAcronym SL-162C SS-162CInterface type APD - CWDM interface for

long haul (C8L1-1D2)PIN - CWDM interface for short

haul (C8S1-1D2)



4-21

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

B&W XFPs Optical Characteristics

10G XFPparameters

ETSI interface 10G Base-S I-64.1 / 10G Base-LUnit

ANSI interface 10G Base-S SR-1 OC192 / 10G Base-LDigital signal STM-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 dBmAllowed bit rates 9.95328; 10.3125 9.95328; 10.3125; 10.709225 GbpsMin. extinction ratio 3.0 6.0 dBSpectral width Max. -20dB bandwidth

See IEEE 802.3ae Triple Tradeoff Curves (TTC)

1.0 nm

Minimum SMSR - 30 dBMax. chromatic dispersion - 60 ps/nmMin. sensitivity, @ BER=1E-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 / Fibre type LC / MMF LC / SMFAcronym 10GB XI-641

10G XFP parameters

ETSI interface S-64.2b / 10G Base-E P1L1-2D2Unit

ANSI interface IR-2 OC192 / 10G Base-E LR2 OC192Digital signal STM-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; 10.709225 GbpsMin. extinction ratio 8.2 9.0 dBSpectral width Max. -20dB bandwidth 0.25 0.25 nmMinimum SMSR 30 30 dBMax. chromatic dispersion 800 1600 ps/nmMin. sensitivity, @ BER=1E-12 -14 -24 dBmMin. overload -1 -7 dBmMax. optical path penalty 2 2 dBMax. receiver reflectance -27 -27 dBOptical connector (Tx/Rx) / Fibre type LC / SMF LC / SMFAcronym XS-642 XP1L12D2

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



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

DWDM XFPs Optical Characteristics

10G XFP parameter APD DWDM XFP for long haul Unit

Addressed wavelengths1546.92 (193.8 THz) -> 1553.33 (193.0 THz) 100 GHz grid, compliant with ITU-T G.694.1

Min. launched power -2.0 dBm

Max. launched power +3.0 dBm

Maximum wavelength deviation EOL +/- 100 pm

Allowed bit rates 9.95328; 10.3125; 10.709; 11.095728 Gbps

Min. extinction ratio 9.0 dB

Max. -15dB bandwidth +/- 8 GHz

Minimum SMSR 30 dB

Max. chromatic dispersion 1600 ps/nm

Min. sensitivity @ BER=1E-4

w/o ASE noise-25 @ 1300 ps/nm-23 @ 1600 ps/nm)

dBm

Min. OSNR @ BER=1E–4 17 @ 1300 ps/nm19 @ 1600 ps/nm

dB/0.1 nm

Min. sensitivity @ BER=1E–12

up to 10.3125 Gbps -22 @ 1300 ps/nm dBm

Min. OSNR @ BER=1E–12

up to 10.3125 Gbps 25 @ 1600 ps/nm dB/0.1 nm

Min. overload -8 dBm

Max. receiver reflectance -27 dB

Optical connector (Tx/Rx) LC

Fiber type SMF

Acronym XL-642C

Interface typeAPD DWDM for long haul

(ITU-T G.698.2 - DW100U-2AXC)

EC100 card front viewConnections, configurations and characteristics


4-23

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

EC100 card front view

Figure 4-1 EC100 card (Equipment Controller) - front view

1

2 3

4

5

6

7

8

9

10

11

12

13 14

15 16

17 18

(1) BOARD STATUS MULTICOLOR LED: LED OFF: card inserted and not running AMBER BLINK: fpga download GREEN BLINK: GREEN: Card provisioned and running RED: card fail RED BLINK: card miss-configured or card mismatch

(2) EPS MULTICOLOR LED: GREEN: eps configured - card active AMBER: eps configured - card stand- byAMBER LINK: eps configured but not available OFF: 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 duplex

(6) YELLOW LED ON: link/active (no activity) YELLOW LED BLINK: link/active (with activity) YELLOW LED OFF: no link

(7) RS232 on USB DEBUG CONNECTOR - factory use only

(8) LOCAL CRAFT TERMINAL USB 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

sw boot/self test

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

MT100 card front viewConnections, configurations and characteristics


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

MT100 card front view

Figure 4-2 MT100 card (Universal Matrix) - front view

LEGENDA:

(1) EPS Multicolor LED:

(3) mUSB DEBUG connector - Factory use only

(4) RJ45 DEBUG connector - Factory use only

(10) 10/100 Mbps Q3 interface

(13) 10/100 Mbps redundant Q3 interface

GREEN: EPS configured - Card ActiveAMBER: EPS configured - Card Stand-byAMBER BLINK: EPS configured but not availableSWITCHED OFF: EPS not configured

(2) BOARD STATUS Multicolor LED:LED OFF: card not equipped or card equipped and not provisioned

AMBER BLINK: FPGA download

GREEN BLINK: SW boot/self testGREEN: card properly equipped, provisioned and in service

RED: card failRED BLINK: card misconfigured or card mismatch

(5) (8) (11) (14) GREEN LED ON: link/active (no activity) GREEN LED BLINK: link/active (with activity) GREEN LED OFF: no link

(6) (9) (12) (15) YELLOW LED ON: full duplex YELLOW LED OFF: half duplex YELLOW LED BLINKING: coll ision

(16) (19) ETH/FETH/GETH interface for Drop Shelf connection

(17) (20) Multicolor LED:

LED OFF: no link

GREEN LED BLINK: 10/100 Mbps link active (with activity)ORANGE LED ON: 1000 Mbps link active (no activity)ORANGE LED BLINK: 1000 Mbps link active (with activity)

GREEN LED ON: 10/100 Mbps link active (no activity)

(18) (21) YELLOW LED ON: full duplexYELLOW LED OFF: half duplexYELLOW LED BLINKING: collision

(7) Local Craft Terminal connector (RS232 F interface)

AMBER: at least 1 port carrying service is alarmed

1

2

3

46

5

7

10

13

16

98

1211

1514

21201817

19


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

5 Alcatel-Lucent 1850 Transport Service Switch (1850 TSS-100) test report Sheet modules

EQUIPMENT ACCEPTANCE SHEETCONTRACT N.

SITE

RING

EQUIPMENT LOCATIONRow / 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

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

Alcatel-Lucent 1850 Transport Service Switch (1850 TSS-100) test report Sheet modules


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

ON-SITE ALCATEL-LUCENT 1850 TSS-100 FINAL TESTUNIT TYPE SERIAL NUMBER

SHELF SERIAL NUMBERSLOT 1SLOT 2SLOT 3SLOT 4SLOT 5SLOT 6SLOT 7SLOT 8SLOT 9

SLOT 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



5-3

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

ON-SITE ALCATEL-LUCENT 1850 TSS-100 FINAL TEST: SDH/SONET LOCAL MEASUREMENTS

Measure Expected Value and ToleranceMeasuredValue

U.M.

Free-running frequency check 2048 +-4.6 ppm KHz

SDH Optical ports test Port N. Port type/ slot

Interf. type

PTx power test

1

see “SFP and XFP modules optical characteristics” (p. 4-16)

dBm

A.L.S. check Check

Test error-free data transit 0 errors errors

PTx power test

2


dBm

A.L.S. check Check


PTx power test

3


dBm

A.L.S. check Check


PTx power test

4


dBm

A.L.S. check Check


PTx power test

5


dBm

A.L.S. check Check


PTx power test

6


dBm

A.L.S. check Check


PTx power test

7


dBm

A.L.S. check Check


PTx power test

8


dBm

A.L.S. check Check


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



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

ON-SITE ALCATEL-LUCENT 1850 TSS-100 FINAL TEST : DATA UNIT LOCAL MEASUREMENTS

Measure Expected Value and ToleranceMeasuredValue

U.M.

DATA Optical ports test Port N. Port type/ slot

Interf. type

PTx power test

1


dBm

A.L.S. check Check


PTx power test

2


dBm

A.L.S. check Check


PTx power test

3


dBm

A.L.S. check Check


PTx power test

4


dBm

A.L.S. check Check


PTx power test

5


dBm

A.L.S. check Check


PTx power test

6


dBm

A.L.S. check Check


PTx power test

7


dBm

A.L.S. check Check


PTx power test

8


dBm

A.L.S. check Check




5-5

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

ON-SITE MULTISERVICE NODE FINAL TEST : LOCAL MEASUREMENTS

Measure Expected Value and Tolerance Measured Value U.M.

Matrix check

Check

Quantity of matrix units N

0 errors errors

SNCP protection check (Line posts) Check

Matrix/CRU EPS protections check Check

Synchronism priority and Holdover Check

Alarm check (if connected) Check

Primary power supply alarms check Check

ON-SITE MULTISERVICE NODE FINAL TEST: LOCAL MEASUREMENTS

Measure Expected Value and Tolerance Measured Value U.M.

Housekeeping alarms check

CPI 1 (HK-IN 1) Check








CPO 1 (HK-OUT 1) Check




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



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

ON-SITE MULTISERVICE NODE FINAL TEST: POINT-TO-POINT MEASURES

SITE 1SITE 2EQUIPMENT TYPEEQUIPMENT RELEASE

Measure Expected value and toleranceMeasured value U.M.

Rx optical "line port" power check

PORT N° TYPEExpected value = Remote PTx - Theoretical line attenuation based on customer data

dBm



dBm



dBm



dBm


PORT N° TYPEMargin level must be min. 4 dB better than the values reported in “SFP and XFP modules optical characteristics” (p. 4-16)

dBm



dBm



dBm



dBm

E O W checkPoint-to-point error monitoring check 0 Errors errors


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6 Abbreviations

Table of abbreviations

ABBREVIATION MEANINGABN Abnormal

ADM Add/Drop Multiplexer

AIS Alarm indication Signal

ALS Automatic Laser Shutdown

APS Automatic Protection Switching

AND Alarm on both station batteries

ANSI American National Standards International

APS Automatic Protection Switching

ARP Address Resolution Protocol

ASAP Alarm Severity Assignment Profile

ASIC Application Specific Integrated Circuit

ATTD Attended (alarm storing)

AU Administrative Unit

AUG Administrative Unit Group

AUOH AU Pointer

AUX Auxiliary

AU4 Administrative unit - level 4

B&W Black and White

BATT Battery

BE Best Effort

BER Bit Error Rate

BIP Bit Interleaved Parity

BNC Bayonet Not Coupling

BOL Beginning Of Life

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

Table of abbreviationsAbbreviations


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

BW BandWidth

CBR Constant Bit Rate

CD Chromatic Dispersion

CD-ROM Compact Disc Read Only Memory

CE European Conformity

Ch Channel

CIR Committed Information Rate

CO Central Office

CoS Class of Service

CPE Customer premises equipment

CPI Incoming parallel contacts

CPO Outgoing parallel contacts

CPU Central Processing Unit (referred to Controller equipment unit or Microprocessor)

CT Craft Terminal

CWDM Coarse Wavelength Division Multiplexing

DC Direct Current

DCC Data Communication Channel

DCM Dispersion Compensation Module

DCN Data Communication Network

DDM Digital Diagnostic Monitoring

DEMUX Demultiplexer

DHCP Dynamic Host Configuration Protocol

DPLL Digital Phase Locked Loop

DWDM Dense Wavelength Division Multiplexing

EC Equipment Controller

ECC Embedded Communication Channel

ECT Equipment Craft Terminal

EFEC Enhanced FEC algorithm

EMC Electromagnetic compatibility

EMI Electromagnetic interference

EOL End Of Life

EOW Engineering Order Wire

EPS Equipment Protection Switching

ESD Electrostatic discharges

E-SNCP Electrical Sub-Network Connection Protection

ETB Ethernet Bridge

ABBREVIATION MEANING



6-3

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

ETS Ethernet Transparent Service (or Ethernet Transport Service)

ETSI European Telecommunication Standards Institute

E2PROM Electrically erasable programmable read only memory

F Interface F (for Craft Terminal) or Fuse

FCS Frame Check-Sum

FE Fast Ethernet

FEC Forward Error Correction

FEC Forwarding Equivalence Class

FERF Far End Receive Failure

FLC First Level Controller

FOADM Fixed Optical Add/Drop Multiplexer

FPGA Field Programmable Gate Array

GA Gate Array

GCC General Communication Channel

GE Gigabit Ethernet

GFP Generic Framing Procedure

GND Ground

GUI Graphical User Interface

HDBK document

HDB3 High Density Bipolar Code

HDLC High-level Data Link Control

HK Housekeeping

HO Higher Order

HOA High Order Adaptation

HOI High Order Interface

HPA High order Path Adaptation

HPC High order Path Connection

HW Hardware

ICS Item Change Status

ID Identification signals

IF InFlow

I/F Interface

ICS Item Change Status

IEC International Electrotechnical Committee

IEEE Institute of Electrical and Electronic Engineering

IGMP Internet Group Management Protocol

ILOS Input Loss Of Signal


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



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

IN Input

IND Indicative alarm

I/O Input/Output

IP Internet Protocol

ISA Integrated Service Adapter (or IP, SDH, ATM)

ISDN Integrated Services Digital Network

IPD An optical power tap with an Integrated Photo Detector

ISO International Organism for standardization

ITU-T (*) International Telecommunication Union-Telecommunication Sector

LAG Link Aggregation Group

LAN Local Area Network

LCAS Link Capacity Adjustment Scheme

LDT Link Description Table

LED Light emitting diode

LO Lower Order

LOA Lower Order Assembler

LOF Loss of alignment

LOI Low Order Interface

LOS Loss of signal

LSP Label Switched Path

LT Line Terminal

M Tagblock or Alarm storing

MAC Media Acces Control

MAU Medium Access Unit

MCF Message Communication Function

MEF Metro Ethernet Forum

MEN Metro Ethernet Network

MIB Management Information Base

MMF Multi Mode Fibre

mp2mp multipoint-to-multipoint

MPLS MultiProtocol label Switching

MS Multiplex Section

MSA Multiplex section adaptation or Multi-Source Agreement (transceiver)

MSP Multiplex section protection

MSPP Multi Service Provisionable Platform

MTU Maximum Transmit Unit

MUX Multiplexer




6-5

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

NE Network Element

NES Network Element Synthesis

NIM Non Intrusive Monitoring

NML Network Management Layer

NMS Network Management System

NNI Network to Network Interface

NRZ No return to zero

NURG Not urgent alarm

OADM Optical Add and Drop Multiplexer

OAM Operation, Administration and Maintenance

OBPS On Board Power Supply

ODUk Optical channel Data Unit, capacity k=1, 2, 3

O-E-O Optical to Electrical to Optical

OH Overhead

OMSN Optical Multi Service Node

OOF Out Of Frame

OR Logic sum/Loss of only one station battery

OS Operation System

OSC Optical Supervisory Channel

O-SNCP Optical - Sub-Network Connection Protection

OSNR Optical Signal to Noise Ratio

OTH Optical Transport Hierarchy

OTN Optical channel Transport Network

OTS Optical Transmission Section

OTUk Optical Channel Transport Unit, capacity k=1, 2, 3

OUT Output

P2MP Point To Multi-Point

P2P Point To Point

PC Personal Computer

PDH Plesiochronous Digital Hierarchy

PDU Protocol Data Unit

PE Provider Edge

PI Physical interface

PIR Peak Information Rate

PLL Phase Locked Loop

PPI Plesiochronous Physical interface

POH Path Overhead


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



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

PM Performance Monitoring

PMA Physical Medium Attachment

PMD Physical Medium Dependent

PMMF Physical Machine Management Function

POH Path Overhead

POS Packet Over Sonet/SDH

PPI Plesiochronous Physical interface

PPP Point to Point Protocol

PPS Path Protection Switching

PRBS Pseudo Random Binary Signal

Q2/QB2 TMN Interface with B2 protocol. Interface towards plesiochronous equipment

Q3/QB3 TMN Interface with B3 protocol. Interface towards TMN

QoS Quality of Service

R Reset command /General alarm

RAI Remote Alarm Indication

RAM Random Access Memory

RDI Remote Defect Indication

RECC Recommendation

RED Random Early Discarding

REF Reference

REI Remote Error Indication

REL Release

RI Remote Inventory

RNURG Not urgent Alarm command. Lights up the relative rack red LED

RPR Resilient Packet Ring

RS FEC Reed-Solomon Forward Error Correction

RSOH Regenerator Section Overhead

RST Regenerator Section Termination

RSTP Rapid Spanning Tree Protocol

RURG Urgent Alarm command. Lights up the relative rack red LED

Rx Reception

SC Shelf Controller

SD Signal Degrade

SDH Synchronous Digital Hierarchy

SF Signal Fail

SFI SERDES Framer Interface

SFP Small Form Factor Pluggable module




6-7

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

SLA Service Level Agreement

SLC Second Level Controller

SMF Single Mode Fibre

SNCP Sub-Network Connection Protection

SNCP/I Sub-Network Connection Protection Inherent

SOH Section Overhead

SONET Sinchronous Optical Network

SPI Synchronous Physical Interface

SPI Serial Peripheral Interface

SSF Server Signal Fail

STM-n Synchronous Transport Module, level n

STP Spanning Tree Protocol

SVID Stacked Virtual LAN Identifier

STS-nc Synchronous Transport Signal level n concatenation

SVLAN Stacked VLAN

SW Software

TANC Remote alarm due to failure of all power supply units

TBD To Be Defined

TCA Threshold Crossing Alarm

TCP/IP Transmission Control Protocol / Internet Protocol

TDM Time Division Multiplexing

TIM Trace Identifier Mismatch

TL1 Translation Language level 1

TM Traffic Manager

TMN Telecommunication Management Network

TOR Remote alarm indicating loss of one of the station batteries

TORC Remote alarm due to a faulty/missing power supply unit

TPD Transponder

TRU Top Rack Unit

TRX Transceiver

TSD Trail Signal Degrade

TSF Trail Signal Fail

TSS Transport Service Switch

TTF Transport Terminal Function

TTL Time To Live

TU Tributary Unit

TUG2/3 Tributary unit group, level 2,3


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



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

TUP/UP Equipment Controller remote alarm

TU12/TU3 Tributary unit level 12, 3

TX Transmission

UNI User to Network Interface

URG Urgent

VC Virtual Container

VCAT Virtual Concatenation

VCG Virtual Concatenation Group

VC12/VC3/VC4 Virtual Container, levels 12,3,4

VLAN Virtual LAN

VMMF Virtual Machine Management Function

VOA Variable Optical Attenuator

VoIP Voice over IP

VPN Virtual Private Network

WAN Wide Area Network

WC-WFQ Work-Conservative WFQ

WDM Wavelength Division Multiplexing

WEEE Waste Electric and Electronic Equipment

WFQ Weighed Fair Queuing

WNC-WFQ Work-Non-Conservative WFQ

W-RED Weighed - Random Early Discarding

XC Cross-Connection

XFP 10 Gigabit Small Form Factor Pluggable module


I N - 18DG 25697 KAAAIssue 2 January 2009

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Index

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

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

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

O OADM, 6-5

P product disposal, xv

product take-back, xv

R recycle, xv

I N - 2 8DG 25697 KAAAIssue 2 January 2009

Index

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