hit_7035_itmn

© Nokia Siemens Networks

1 (184)

SURPASS hiT 7035 4.3

Installation and Test Manual (ITMN)

A42022-L5975-B052-02-7630


A42022-L5975-B052-02-7630 Issue 2 Issue Date June 2009


2 (184)

The information in this document is subject to change without notice and describes only the product defined in the introduction of this documentation. This documentation is intended for the use of Nokia Siemens Networks customers only for the purposes of the agreement under which the document is submitted, and no part of it may be used, reproduced, modified or transmitted in any form or means without the prior written permission of Nokia Siemens Networks. The documentation has been prepared to be used by professional and properly trained personnel, and the customer assumes full responsibility when using it. Nokia Siemens Networks welcomes customer comments as part of the process of continuous development and improvement of the documentation. The information or statements given in this documentation concerning the suitability, capacity, or performance of the mentioned hardware or software products are given “as is” and all liability arising in connection with such hardware or software products shall be defined conclusively and finally in a separate agreement between Nokia Siemens Networks and the customer. However, Nokia Siemens Networks has made all reasonable efforts to ensure that the instructions contained in the document are adequate and free of material errors and omissions. Nokia Siemens Networks will, if deemed necessary by Nokia Siemens Networks, explain issues which may not be covered by the document. Nokia Siemens Networks will correct errors in this documentation as soon as possible. IN NO EVENT WILL NOKIA SIEMENS NETWORKS BE LIABLE FOR ERRORS IN THIS DOCUMENTATION OR FOR ANY DAMAGES, INCLUDING BUT NOT LIMITED TO SPECIAL, DIRECT, INDIRECT, INCIDENTAL OR CONSEQUENTIAL OR ANY LOSSES, SUCH AS BUT NOT LIMITED TO LOSS OF PROFIT, REVENUE, BUSINESS INTERRUPTION, BUSINESS OPPORTUNITY OR DATA,THAT MAY ARISE FROM THE USE OF THIS DOCUMENT OR THE INFORMATION IN IT. This documentation and the product it describes are considered protected by copyrights and other intellectual property rights according to the applicable laws. The wave logo is a trademark of Nokia Siemens Networks Oy. Nokia is a registered trademark of Nokia Corporation. Siemens is a registered trademark of Siemens AG. Other product names mentioned in this document may be trademarks of their respective owners, and they are mentioned for identification purposes only. Copyright © Nokia Siemens Networks 2009. All rights reserved.

f Important Notice on Product Safety Elevated voltages are inevitably present at specific points in this electrical equipment.Some of the parts may also have elevated operating temperatures. Non-observance of these conditions and the safety instructions can result in personal injury or in property damage. Therefore, only trained and qualified personnel may install and maintain the system. The system complies with the standard EN 60950-1 / IEC 60950-1. All equipment connected has to comply with the applicable safety standards. The same text in German: Wichtiger Hinweis zur Produktsicherheit In elektrischen Anlagen stehen zwangsläufig bestimmte Teile der Geräte unter Spannung. Einige Teile können auch eine hohe Betriebstemperatur aufweisen. Eine Nichtbeachtung dieser Situation und der Warnungshinweise kann zu Körperverletzungen und Sachschäden führen. Deshalb wird vorausgesetzt, dass nur geschultes und qualifiziertes Personal die Anlagen installiert und wartet. Das System entspricht den Anforderungen der EN 60950-1 / IEC 60950-1. Angeschlossene Geräte müssen die zutreffenden Sicherheitsbestimmungen erfüllen.




3 (184)

Statements of compliance

CE statement

The CE conformity declaration for the product is fulfilled when the system is built and cabled in line with the information given in the manual and the documentation specified within it, such as installation instructions, cable lists or the like. Where necessary project-specific documentation should be taken into consideration. Deviations from the specifications or independent modifications to the layout, such as use of cable types with lower screening values for example, can lead to violation of the CE protection requirements. In such cases the conformity declaration is invalidated. The responsibility for any problems which subsequently arise rests with the party responsible for deviating from the installation specifications.




4 (184)

Contents

1 Notes on this documentation ............................................................... 9 1.1 Customer documentation ........................................................................ 9 1.2 Complementary documents................................................................... 10 1.3 Symbols used in the customer documentation...................................... 10 1.3.1 Symbols for warnings and cautions....................................................... 11 1.3.2 Symbols for notes.................................................................................. 11 1.3.3 Conventions used.................................................................................. 11 1.4 Notes on licensed software ................................................................... 12

2 Protective measures and handling / Schutzmaßnahmen und Handhabung ................................................................................. 13

2.1 Basic remarks / Grundsätzliche Hinweise ............................................. 13 2.2 Mechanical design / Mechanische Konstruktion.................................... 14 2.2.1 Front door of the device / Geräte-vordertür ........................................... 14 2.2.2 Card shieldings / Schirmungen der Baugruppen................................... 14 2.3 Weight / Gewicht ................................................................................... 15 2.4 Temperature / Temperatur .................................................................... 15 2.4.1 Device cooling / Gerätekühlung............................................................. 15 2.4.2 Components subject to high operating temperatures /

Komponenten mit hoher Betriebstemperatur......................................... 15 2.5 Air filter / Luftfilter................................................................................... 16 2.6 Grounding and potential balancing / Erdung und

Potenzialausgleich................................................................................. 16 2.7 Protection against excessive overvoltage on the -48/-60-Volt

power supply input / Schutz gegen Überspannungen beim -48/-60-Volt-stromversorgungseingang ........................................................ 17

2.8 Electrostatic sensitive components (ESD) / Elektrostatisch gefährdete Bauteile (EGB) .................................................................... 18

2.9 Fiber-optic cables and connectors / Lichtwellenleiter und Optische Steckverbinder ....................................................................... 19

2.10 Laser radiation / Laserstrahlung ............................................................ 20 2.10.1 Protection against extraneous laser light and protection of the

optical modules concerned / Schutz gegen austretendes Laserlicht und Schutz der betreffenden Optischen Baugruppen ........... 20

2.10.2 Laser safety circuit / Lasersicherheitsabschaltung ................................ 22 2.11 Emergency switching OFF / Notabschaltung ........................................ 22 2.12 Handling batteries / Handhabung von batterien .................................... 23 2.13 Replacement components / Ersatzteile ................................................. 24 2.14 Waste Electrical and Electronic Equipment (WEEE) /

Entsorgung von elektrischen und elektronischen Geräten .................... 25

3 Installation procedures and preparation........................................... 26 3.1 Declaration of CE conformity................................................................. 26 3.2 Personnel requirements ........................................................................ 26 3.3 Required tools and accessories ............................................................ 27




5 (184)

3.4 Checking for intactness..........................................................................27 3.5 Installation steps.....................................................................................28 3.6 Site preparation......................................................................................28 3.7 Unpacking shipping box .........................................................................29 3.8 Unpacking the individual card shipping cartons .....................................30 3.9 Unpacking the software shipping cartons...............................................30

4 Installing the hardware ........................................................................31 4.1 Installing the chassis ..............................................................................31 4.1.1 Standard racks .......................................................................................32 4.1.2 Adjusting the chassis installation position ..............................................34 4.1.3 Connecting the chassis to the grounding cable......................................35 4.2 Equipping the chassis ............................................................................39 4.2.1 Installing module cards...........................................................................39 4.2.2 Inserting CF card....................................................................................44 4.2.3 Installing SFP optical modules ...............................................................44 4.2.4 Replacing or adjusting fan unit ...............................................................47 4.2.5 Replacing air filter...................................................................................49 4.3 Connecting cables..................................................................................50 4.3.1 Cable list ................................................................................................50 4.3.2 Connecting power cables .......................................................................52 4.3.3 Connecting fiber jumpers .......................................................................56 4.3.4 Connecting E1 cables ............................................................................57 4.3.5 Connecting E3/DS3 cables ....................................................................63 4.3.6 Connecting STM-1E cables....................................................................64 4.3.7 Connecting administrative cables...........................................................65 4.3.8 Connecting timing cables .......................................................................67 4.3.9 Connecting Ethernet cables ...................................................................68 4.3.10 Connecting Ethernet splitter cables........................................................69 4.3.11 Complete cable layout............................................................................73

5 Connecting and configuring an operation terminal..........................75 5.1 PC requirements for use as an operating terminal.................................75 5.2 Connecting the operating terminal .........................................................75 5.3 Installing Element Manager Software (EMS) .........................................75 5.3.1 Installing the TNMS CT software package.............................................76

6 Starting up the SURPASS hiT 7035 ....................................................77 6.1 Initial startup of a new system................................................................77 6.1.1 Setting up a HyperTerminal connection .................................................78 6.1.2 Coping CF load/MIB to flash ..................................................................80 6.1.3 NE general configuration........................................................................83 6.2 Using the SURPASS hiT 7035 LCT .......................................................89

7 Configuring the SURPASS hiT 7035...................................................90 7.1 EMS installation .....................................................................................91 7.2 NE configuration and management........................................................91




6 (184)

7.2.1 Starting SURPASS hiT 7035 LCT via TNMS CT................................... 91 7.2.2 Chassis view.......................................................................................... 98 7.2.3 NE synchronization.............................................................................. 100 7.2.4 NE properties configuration ................................................................. 101 7.2.5 Shutting down NE................................................................................ 104 7.2.6 FTP settings ........................................................................................ 104 7.2.7 NE software management ................................................................... 106 7.2.8 MIB management ................................................................................ 108 7.2.9 NE timing setting ................................................................................. 113 7.2.10 NE trap destination configuration ........................................................ 115 7.2.11 Card configuration and management .................................................. 116 7.2.12 SDH port configuration and management ........................................... 118 7.2.13 Shutting down SUPRASS hiT 7035 LCT............................................. 121

8 Initial measurements and tests ........................................................ 122 8.1 Measurements and tests ..................................................................... 122 8.2 Local tests ........................................................................................... 122 8.2.1 Battery voltage test.............................................................................. 123 8.2.2 Management port test.......................................................................... 123 8.2.3 AUX port test ....................................................................................... 124 8.2.4 STM-16 optical interface...................................................................... 125 8.2.5 STM-4 optical interface........................................................................ 129 8.2.6 STM-1 optical interface........................................................................ 132 8.2.7 STM-1E port BER test ......................................................................... 136 8.2.8 PDH port test ....................................................................................... 137 8.2.9 Ethernet port........................................................................................ 139 8.2.10 GE port auto-negotiation test............................................................... 141 8.2.11 OA port test ......................................................................................... 142 8.2.12 Power 1 + 1 protection test.................................................................. 143 8.3 Network tests....................................................................................... 144 8.3.1 Bit error test on E1 (12 hours) ............................................................. 144 8.3.2 Bit error test on E3 (12 hours) ............................................................. 145 8.3.3 Bit error test on DS3 (12 hours)........................................................... 146 8.3.4 Bit error test on STM-1 (12 hours)....................................................... 147 8.3.5 Bit error test on STM-1E (12 hours) .................................................... 148 8.3.6 Bit error test on STM-4 (12 hours)....................................................... 149 8.3.7 Bit error test on STM-16 (12 hours)..................................................... 150 8.3.8 Packet loss test on 8 x FE/T Ethernet card (12 hours)........................ 151 8.3.9 Packet loss test on 8 x FE/L2 Ethernet card (12 hours) ...................... 152 8.3.10 Packet loss test on Gigabit Ethernet card (12 hours) .......................... 153 8.4 Field check lists and test report ........................................................... 154 8.4.1 Certificate of customer acceptance ..................................................... 155 8.4.2 Circuit pack list of SURPASS hiT 7035 ............................................... 156 8.4.3 Load number of SURPASS hiT 7035 and TNMS-CT .......................... 157 8.4.4 Tools and test equipment list............................................................... 157 8.4.5 Test result............................................................................................ 157

9 LED indications ................................................................................. 159




7 (184)

9.1 Enhanced System Controller card (SCE).............................................159 9.2 Cross-connect and timing card with STM-4/1 optical module

(CC + 1 x STM-4/1) or with STM-16/4 optical module (CC + 1 x STM-16/4) ............................................................................................160

9.3 Traffic interface cards...........................................................................161 9.3.1 PWR and Fault LEDs ...........................................................................161 9.3.2 Link LEDs.............................................................................................161 9.3.3 Fast Ethernet connector LEDs .............................................................162 9.4 Power card ...........................................................................................162

10 Pin assignments.................................................................................163 10.1 DC power supply cable ........................................................................163 10.2 E1 cable ...............................................................................................164 10.3 SIPAC connector panel ........................................................................171 10.4 Ethernet cable ......................................................................................174 10.5 Management cable...............................................................................176 10.6 Timing, STM-1E, and E3/DS3 cables...................................................177 10.7 Station alarm cables.............................................................................177 10.8 MDI cables ...........................................................................................178 10.9 MDO cables..........................................................................................179 10.10 EOW cable ...........................................................................................179 10.11 Console cable ......................................................................................180

Abbreviations......................................................................................................181

Index . ...........................................................................................................183

Summary of changes



8 (184)

Summary of changes

Issue Issue date Remarks

1 September 2008 Initial version

2 June 2009 Minor update on supported racks and a note on inter-working in Chapter 6.1.3

Notes on this documentation



9 (184)

1 Notes on this documentation This chapter gives an overall introduction of the Nokia Siemens Networks SURPASS hiT 7035 series documentation sets, an overview of important symbols in the document, and notes on licensed software.

1.1 Customer documentation

The Customer Documentation of the SURPASS hiT 7035 comprises the following description and manuals:

• SURPASS hiT 7035 Product Description (PD) The Product Description gives an overview of the application, performance features, interfaces, and functions of the SURPASS hiT 7035. It also contains the most important technical data.

ii Note The Product Description does not contain any instructions for using the system.

• SURPASS hiT 7035 Installation and Test Manual (ITMN)

The Installation and Test Manual contains instructions on mounting, connecting, and commissioning the SURPASS hiT 7035, as well as connecting and commissioning the LCT operating terminals.

• SURPASS hiT 7035 Troubleshooting Manual (TSMN) The Troubleshooting Manual provides information about the supported alarm list and troubleshooting procedures for SURPASS hiT 7035.

• SURPASS hiT 7035 LCT User Manual (LCT UMN) The Local Craft Terminals (LCT) User Manual provides information about the SURPASS hiT 7035 LCT (features, configuration, installation,




10 (184)

etc.) and how to operate, monitor, and maintain the SURPASS hiT 7035 using the Element Manager software running on the LCT.

ii Note Throughout the document, the term SURPASS hiT 7035 LCT is used to refer to the TNMS CT system configured for LCT mode.

ii Note Besides the LCT User Manual, the Online Help of the SURPASS hiT 7035 software is an extremely useful reference tool for the operator.

1.2 Complementary documents

In addition to the SURPASS hiT 7035 customer documentation listed in Chapter 1.1, there is further documentation:

• SURPASS hiT 7035 Release Note This document identifies the specific version of the SURPASS hiT 7035 and provides information on hardware, software, LCT components, and the limitations of the release as well as important notes concerning the customer documentation.

• TNMS CT User Manual This manual provides information about the TNMS CT software, integrating description, installation, operation, and a graphical user interface explanation.

1.3 Symbols used in the customer documentation

Following paragraphs describe the symbols used in this document.




11 (184)

1.3.1 Symbols for warnings and cautions

!! WARNING This warning symbol means danger. There is a situation that could cause bodily injury. Before working on any equipment, be aware of the hazards involved with electrical circuitry and be familiar with standard practices for preventing accidents.

!! CAUTION Means that the reader should be careful. In this situation, he might do something that could result in equipment damage or loss of data.

1.3.2 Symbols for notes

ii Note Used for notes, tips, or additional information.

Cross reference to other chapters in this manual or reference to other manuals.

Help Reference to the online help system of the Element Manager software.

1.3.3 Conventions used

Representation Meaning

“Inverted commas” Window or wizard titles are represented in “inverted commas”.

Example: Open the “Help and Support Center” window. The “New Connection” wizard is displayed.

Bold Any field or text in the GUI is represented in bold type.

Example: Click Shutdown and then click OK to turn off the computer.

Italic Variables and file extensions are represented in italic.

Example: Enter 192.168.0.1 in the IP address field. Click OK to produce a .pdf rendition.

Courier Commands, screen output, file names, and paths are represented in courier.

Example: # ping -t 192.168.0.1

<Angle brackets> Used for keyboard actions or place holders for concrete names or values are




12 (184)

Representation Meaning represented in <angle brackets>. If used for a filename the courier font must be used also.

Example: The naming convention for the log files is <NEname>.txt, where <NEName> is the name of the NE sending the messages. Press <CTRL> + <ALT><DEL> to open the task manager.

> Used for menu sequences.

Example: Click File > Print… to print the document.

Tab. 1.1 List of used conventions

1.4 Notes on licensed software

This documentation may refer to various third-party software products which are integrated into the product under a license agreement between Nokia Siemens Networks and the software manufacturer. In case of problems with such software, please contact Nokia Siemens Networks.

ii Note All IPs, release, build, and other information in the pictures are used as an example only and not to be taken literally unless specified as such.

Protective measures and handling / Schutzmaßnahmen und Handhabung



13 (184)

2 Protective measures and handling / Schutzmaßnahmen und Handhabung

2.1 Basic remarks / Grundsätzliche Hinweise

!!

If the following rules are not observed, and if equipment damages or personnel injuries are the result, the manufacturer assumes no liability, and the warranty will expire!

Bei Nichtbeachtung der nachfolgenden Vorschriften und daraus resultieren- den Personen- oder Sachschäden wird keine Haftung seitens des Herstellers übernommen, und die Gewährleistung erlischt!

!!

If the user wants to replace any parts of devices or cables, the user must only use original spare parts or parts which are explicitly licensed by the manufacturer.

Falls Sie an den Geräten oder an der Ver- kabelung irgendwelche Teile ersetzen, dann dürfen Sie nur Original-Ersatzteile oder solche Teile verwenden, die vom Hersteller ausdrücklich zugelassen sind.

!!

Changes or modifications not expressly approved by the manufacturer could void the user’s authority to operate the equipment.

Änderungen oder Modifikationen, die vom Hersteller nicht ausdrücklich zugelassen wurden, können zum Erlöschen der allgemeinen Betriebsgenehmigung für das Gerät führen.

If necessary, safety signs and markings according to IEC 61310-1 are fixed to the devices.

Soweit notwendig, sind an den Geräten Sicherheitssymbole und Kennzeichnungen nach IEC 61310-1 angebracht.

ii

Important note:

If no date is specified, the norms mentioned in the following (EN, IEC, UL, etc.) refer to the latest issue of the respective norm in each case.

Wichtiger hinweis:

Wenn kein Datum angegeben ist, beziehen sich die Normen (EN, IEC, UL usw.), die im Folgenden erwähnt werden, auf die jeweils neueste Ausgabe der entsprechenden Norm.




14 (184)

Additional (more specific) safety remarks may also be included in the following main chapters of this.

Zusätzliche (speziellere) Sicherheitshinweise können auch in den nachfolgenden Hauptkapiteln dieses Handbuches enthalten sein.

2.2 Mechanical design / Mechanische Konstruktion

2.2.1 Front door of the device / Geräte-vordertür

!!

A subrack being fitted with a front door must only be operated with this door closed. There is danger of personal injury, if the door of the subrack is open.

Baugruppenträger, die eine Vordertür haben, dürfen nur betrieben werden, wenn diese Tür geschlossen ist. Bei geöffneter Vordertür des Baugruppenträgers besteht Verletzungsgefahr.

For this reason, before working on the subrack, open the front door, raise it and then remove it.

Öffnen Sie deshalb, bevor Sie am Baugruppenträger arbeiten, dessen Vordertür, heben Sie sie an und nehmen Sie sie ab.

Once the work has been completed, refit the door belonging to this subrack and close it.

Bringen Sie nach Beendigung der Arbeiten die zu diesem Baugruppenträger gehörende Vordertür wieder an und schließen Sie sie.

!!

When the front door is open especially when additional covers have been removed

-components with high operating temperatures may also become accessible.

Bei geöffneter Vordertür insbesondere nach dem Öffnen von zusätzlichen Abdeckungen können auch Teile mit hoher Betriebstemperatur zugänglich sein.

2.2.2 Card shieldings / Schirmungen der Baugruppen

Do not touch the contact springs of the card shieldings with the fingers or with the hand.

Berühren Sie die Kontaktfedern der Baugruppen-schirmungen nicht mit den Fingern oder mit der Hand.




15 (184)

2.3 Weight / Gewicht

Warning labels

at the subrack in case of heavy weight.

Warnschilder

am Baugruppenträger bei hohem Gewicht.

The maximum weight to be lifted by one person should not exceed 18 kg!

Das maximale Hebegewicht für eine Person ist auf 18 kg festgelegt!

2.4 Temperature / Temperatur

2.4.1 Device cooling / Gerätekühlung

!!

The built-in ventilation installations must not be modified, and there must be sufficient air flow!

Vorhandene Lüftungseinrichtungen dürfen nicht verändert werden, und die ausreichende Luftzirkulation darf nicht behindert sein!

!!

Attention! Air condition devices have rotating items!

Achtung! Lüfterbaugruppen haben rotierende Teile!

2.4.2 Components subject to high operating temperatures / Komponenten mit hoher Betriebstemperatur

Warning label

For equipment components (e. g. heat sinks) which may attain high operating temperatures.

Touching these components is liable to result in personal injury!

Warnschilder

für Geräteteile (z. B. Kühlkörper), die hohe Betriebstemperaturen erreichen können.

Beim Berühren solcher Teile besteht Verletzungsgefahr!




16 (184)

2.5 Air filter / Luftfilter

!!

Each fan unit can be equipped with a dust filter that cleans dust particles from the cooling air.

Jede Lüftereinheit kann mit einem Luftfilter ausgestattet werden, welches die Kühlluft von Staubpartikeln reinigt.

Provided that the environmental conditions (defined in ETS 300 019 class 3.1E) are fulfilled, replace the dust filter every three months.

In addition, pay attention to possible notes from the filter manufacturer.

Vorausgesetzt, dass die Umweltbedingungen (entsprechend ETS 300 019 class 3.1E) erfüllt sind, ist das Staubfilter alle drei Monate auszuwechseln.

Außerdem sind gegebenenfalls die Hinweise des Filterherstellers zu beachten.

!!

Risk of fire

In case of excessive heat fire could flash over!

The air filter is part of the fire enclosure. Therefore it is forbidden to run the network element without this air filter.

For replacement only original spare parts have to be used or replacement material must be rated HF-1 or better in accordance to IEC 60959-1.

Brandrisiko

Im Falle von Überhitzung könnte Feuer übergreifen!

Das Luftfilter ist Teil des Feuerschutzes. Daher ist es verboten, das Gerät ohne Luftfilter zu betreiben.

Als Ersatz dürfen nur Originalteile verwendet werden oder Materialien, die gemäß IEC 60950-1 als HF-1 oder besser eingestuft sind.

2.6 Grounding and potential balancing / Erdung und Potenzialausgleich

!!

Especially when running a combination of different communication equipment, it is important to establish correct grounding and potential balancing between them depending on the local grounding measures.

Insbesondere bei gemeinsamer Verwendung verschiedener Kommunikationsgeräte ist es wichtig, abhängig von den örtlichen Erdungsmaßnahmen auf korrekten Erdungs- und Potenzialausgleich zu achten.

After mounting the system into the rack, before attaching the connecting cables, and before commissioning, first check the grounding and potential balancing connections to agree with EN50310 and ETSI EN 300 253.

Nach dem Einbau der Systeme in das Gestell sind – vor dem Anschluss der Verbindungskabel und vor der Inbetriebnahme – die Erdungs- und Potenzialausgleichsverbindungen gemäß EN50310 und ETSI EN 300 253 zu überprüfen.




17 (184)

The grounding must be effective as long as external cables are connected to the equipment.

Wenn die Baugruppenträger bzw. Einsätze nicht in einem Systemgestell montiert werden, müssen Sie auf andere Weise für geeignete Erdung sorgen (gemäß ETSI EN 300 253).

ii

If a subrack is not installed in a system rack, the user must ensure that it is properly grounded in some other way (according to ETSI EN 300 253).

Wenn die Baugruppenträger bzw. Einsätze nicht in einem Systemgestell montiert werden, müssen Sie auf andere Weise für geeignete Erdung sorgen (gemäß ETSI EN 300 253).

Grounding or potential balancing points are normally labelled with one of the signs shown below.

Erdungs- oder Potenzialausgleichspunkte sind normalerweise mit einem der nachfolgend dargestellten Zeichen gekennzezeichnet.

Protective earth (PE)

Schutzerde (PE)

Ground (GND)

Erde (E)

In both rack and wall mounting applications, the subrack Protective Earthing must be assured by connecting a PE cable as depicted in the Cabling Plan document.

The PE cable must be connected before each other cable connection, and disconnected last.

Sowohl bei Gestellmontage als auch bei Wandmontage des Baugruppenträgers muss die Schutzerdung dadurch sichergestellt sein, dass ein Schutzerdungskabel entsprechend dem Kabelführungsplan angeschlossen ist.

Das Schutzerdungskabel muss als erste Verbindung (vor jeder anderen) angeschlossen und als letzte Verbindung getrennt werden.

2.7 Protection against excessive overvoltage on the -48/-60-Volt power supply input / Schutz gegen Überspannungen beim -48/-60-Volt-stromversorgungseingang

!!

A protection against excessive voltage is built in on the -48/-60 Volts power supply input.

Ein Schutz gegen Überspannung auf der Stromversorgungs-Eingangsseite -48/-60 V ist eingebaut.




18 (184)

The equipment must only be operated at a -48 /-60 V DC battery-based supply voltage, grounded at its positive pole and corresponding to ETSI EN 300 132-2 and EN60950-1!

Das Gerät darf nur an einer batteriegestützten, mit positivem Pol geerdeten -48/-60 V-Versorgungs-Gleichspannung entsprechend ETSI EN 300 132-2 und EN60950-1 betrieben werden!

Observe the above note especially before connecting other equipment to the user/customer interfaces!

Beachten Sie den obigen Warnhinweis insbesondere, bevor Sie andere Geräte an die Anwender /Kunden-Schnittstellen anschließen!

The user must observe without failing the protective earthing measures given in Chapter 2.6!

Beachten Sie unbedingt die Schutzerdungsmaßnahmen entsprechend Kapitel 2.6!

!!

The subrack interfaces for alarms and TIF contacts are supplied by external power. The maximum allowable voltage must correspond to the SELV voltage limits (≤ |-72| V DC) respectively to the -48 V/-60 V DC battery-based supply voltage according to ETSI EN 300 132-2!

Die Baugruppenträger-Schnittstellen für Alarme und TIF-Kontakte werden extern versorgt. Die maximal zulässige Spannung muss den SELV-Spannungsgrenzen entsprechen (≤ 72 V Gleichspannung) bzw. den Spannungsgrenzen der batteriegestützten -48 V/-60 V- Versorgungs-Gleichspannung gemäß ETSI EN 300 132-2!

2.8 Electrostatic sensitive components (ESD) / Elektrostatisch gefährdete Bauteile (EGB)

ESD symbol

Modules displaying this label contain electrostatically-sensitive components, i.e. they must be handled in accordance with the necessary safety measures.

EGB/ESD-Symbol

Baugruppen, die dieses Zeichen tragen, sind mit elektrostatisch gefährdeten Bauteilen bestückt, d.h. beim Umgang damit müssen die erforderlichen Sicherheitsmaßnahmen eingehalten werden.

!!

The user must always wear a grounding bracelet that is connected properly when packing, unpacking, touching, pulling, or inserting modules displaying the ESD symbol. This will ensure these modules not to be damaged by electrostatic discharges.

Jeder, der Baugruppen mit EGB- / ESD-Symbol aus- oder einpackt, berührt, zieht oder steckt, muss stets ein vorschriftsmäßig angeschlossenes Erdungsarmband tragen. Dadurch ist sichergestellt, dass diese Baugruppen nicht durch elektrostatische Entladungen beschädigt werden.




19 (184)

Every printed circuit board has a grounding outer edge, which is connected to the ground terminal of the module. The board is only allowed to be touched or handled at this grounding edge - even if the user is properly grounded.

Jede Leiterplatte hat einen Erdungsaußenrand, der mit dem Masseanschluss der Baugruppe verbunden ist. Die Leiterplatte darf-auch bei vorschriftsmäßiger Körpererdung-nur am Erdungsaußenrand angefasst werden.

When pulling and inserting modules only use the integral plug and pull aids.

Verwenden Sie beim Ziehen und Stecken von Baugruppen nur die daran angebrachten Zieh- und Steckhilfen.

Modules which are located in a screened, unopened housing are protected at any rate against electrostatic discharges.

Baugruppen, die sich in einem abgeschirmten, ungeöffneten Gehäuse befinden, sind in jedem Fall vor elektrostatischen Entladungen geschützt.

The European Standards EN 61340-5-1 and -2 contain additional instructions on how to handle electrostatically sensitive devices properly.

Die Europa-Normen EN 61340-5-1 und -2 geben zusätzliche Anleitungen zum sachgemäßen Umgang mit elektrostatisch gefährdeten Bauelementen.

2.9 Fiber-optic cables and connectors / Lichtwellenleiter und Optische Steckverbinder

For laser safety remarks, see Chapter 2.10.

Laser-Sicherheitshinweise siehe Kapitel 2.10.

Optical connectors are precisionmade components and must be handled accordingly. To ensure faultless functioning, the following points must be observed.

Optische Steckverbindungen sind Präzisionsteile und müssen dementsprechend behandelt werden. Eine einwandfreie Funktion ist nur dann sichergestellt, wenn nachfolgende Punkte berücksichtigt werden.

The minimum bending radius for optical fibers is 30 mm!

Für LWL-Leitungen darf ein Biegeradius von 30 mm nicht unterschritten werden!

Mechanical damage to the surfaces of optical connectors impairs transmission quality by higher attenuation.

Mechanische Beschädigungen der Stirnflächen von optischen Steckverbindungen erhöhen die Dämpfung und mindern deshalb die Übertragungsqualität.

For this reason, do not expose the connectors to impact.

Vermeiden Sie deshalb Stoßbeanspruchungen der Steckverbinder.




20 (184)

Always fit optical fiber connectors with protective caps to guard them against mechanical damage and contamination. The protective dust caps should only be removed immediately prior to installation.

Schützen Sie LWL-Steckverbinder grundsätzlich mit einer Schutzkappe vor mechanischen Beschädigungen und Verschmutzungen. Die Staubschutzkappe soll erst unmittelbar vor dem Einbau entfernt werden.

Once the protective dust caps have been removed, the user must check the surfaces of the optical fiber connectors to ensure that they are clean, and clean them if necessary.

Prüfen Sie nach Entfernen der Staubschutzkappen die Stirnflächen der LWL- Stecker auf Sauberkeit und reinigen Sie sie gegebenenfalls.

For cleaning, a special optical fiber cleaning tool, or a clean, lint-free cellulose cloth or a chamois leather is suitable. Freon TF, isopropyl alcohol (99%), or white spirit can be used as cleaning fluids.

Zum Reinigen kann ein spezielles LWLReinigungswerkzeug oder ein einwandfrei sauberes, fusselfreies Zellstofftuch oder Fensterleder verwendet werden. Als Reinigungsflüssigkeit kann Freon TF, Isopropylalkohol (99%) oder Spiritus verwendet werden.

2.10 Laser radiation / Laserstrahlung

2.10.1 Protection against extraneous laser light and protection of the optical modules concerned / Schutz gegen austretendes Laserlicht und Schutz der betreffenden Optischen Baugruppen

!!

Depending on the device type, the laser radiation may also be invisible for the human eye!

Je nach Gerätetyp kann die Laserstrahlung für das menschliche Auge auch unsichtbar sein!

!!

Devices and modules displaying either of the following warning labels contain laser devices.

Geräte und Baugruppen, die eines der folgenden Warnzeichen tragen, enthalten Laser-Einrichtungen.

Warning label

according to the

EN 60825-1 / IEC 60825-1.

Warnschild

nach

EN 60825-1 / IEC 60825-1.

Warning label

for laser equipment as per EN 60825-1 / IEC 60825-1.

LASER CLASS 1

Warnschild

für Laser-Einrichtungen entsprechend EN 60825-1 / IEC 60825-1.




21 (184)

When operated in a closed system, the laser equipment of the device conforms to class 1 safety level.

Bei Betrieb im geschlossenen System entsprechen die Laser-Einrichtungen des Gerätes der Gefährdungsklasse 1.

Nevertheless, in view of possible malfunctions, transmission systems which are fitted with optical fiber amplifier modules are classified as hazard level 1M. This hazard level is also applicable if the device is opened.

Unter Berücksichtigung von vorhersehbaren Fehlerfällen sind mit optischen Lichtwellenleiter-Verstärkerbaugruppen bestückte Übertragungssysteme jedoch der Gefährdungsklasse 1M zugeordnet. Diese Gefährdungsklasse gilt auch bei geöffnetem Gerät.

This hazard level is labelled as follows: Die Gefährdungsklasse ist folgendermaßen beschildert:

Warning label

According to

EN 60825-2:2004 /

IEC 60825-2:2004.

Warnschild

nach

EN 60825-2:2004 /

IEC 60825-2:2004.

To ensure safe operation of the entire optical path, the laser safety shutdown must be activated, see Chapter 2.10.2.

Für den sicheren Betrieb der gesamten optischen Strecke muss die Lasersicherheitsabschaltung aktiviert sein, siehe Kapitel 2.10.2.

Commissioning should be performed with fuse protection in the closed system.

Die Inbetriebnahme soll abgesichert im geschlossenen System erfolgen.

To avoid damage to health, the user must observe the regulations regarding protection against radiation from laser devices (EN 60825-1/ IEC 60825-1).

Zur Vermeidung gesundheitlicher Schäden müssen Sie die Vorschriften zur Strahlungssicherheit von Lasereinrichtungen (EN 60825-1 / IEC 60825-1) beachten.

!!

If it cannot be avoided in an exceptional case to apply the hazard level 1 M regulation (see above), the user always must use dedicated laser-protective goggles.

Falls die Gefährdungsklasse 1M im Ausnahmefall nicht vermieden werden kann (siehe oben), müssen Sie stets eine Laser-Schutzbrille tragen.




22 (184)

2.10.2 Laser safety circuit / Lasersicherheitsabschaltung

Under normal operating conditions, the maximum transmit levels of the optical interface units stay below the limit values defined in EN 60825-1 / IEC 60825-1, Laser Class 1.

Unter normalen Betriebsbedingungen bleiben die maximalen Übertragungspegel der optischen Anschlussbaugruppen unterhalb der Grenzen, die nach EN 60825-1 / IEC 60825-1, Laser-Klasse 1, erlaubt sind.

However, all optical transmitters (except at the Ethernet interfaces) are fitted with automatic laser shutdown circuits to safeguard against any possible hazard. This shutdown circuit can be configured and is active in the basic state. It trips, if no input signal is received by the optical receiver, i.e. if there is a break in the link. This prevents any uncontrolled laser emission if a fiber-optic connector is faulty or not connected.

Als Schutz gegen eventuelle Gefährdungen sind alle optischen Sender (außer an den Ethernet-Schnittstellen) mit einer automatischen Laserabschaltung ausgestattet. Diese Abschaltung kann konfiguriert werden und ist grundsätzlich aktiv. Sie löst aus, wenn ein Eingangssignal am zugehörigen optischen Empfänger fehlt, z. B. bei unterbrochener Verbindung. Dies verhindert jede unkontrollierte Laserabstrahlung, wenn der optische Steckverbinder fehlerhaft oder nicht angeschlossen ist.

To ensure safe operation of the entire optical path, the laser safety shutdown must be activated.

Für den sicheren Betrieb der gesamten optischen Strecke muss die Laser-Sicherheitsabschaltung aktiviert sein.

!!

Even with this safeguard, fiber-optic cables which are open at one end should always be considered to be “live”.

Auch unter Beachtung dieser Vorsichtsmaßnahmen sollen Glasfaserkabel, die an einem Ende offen sind, immer so behandelt werden, als würden sie ständig Laserlicht führen.

Never look into open fiber-optic cable ends, as this may damage human eyes.

Nie direkt in die Enden sehen, da sonst die Augen geschädigt werden können!

!!

In case of doubt always use dedicated laser-protective goggles!

Tragen Sie im Zweifelsfall stets eine Laserschutzbrille!

2.11 Emergency switching OFF / Notabschaltung

Especially if smoke or fire escapes from the device (or in other emergency situations), switch OFF the device immediately – by all relevant circuit breakers in the connector panel of the rack.

Insbesondere falls Rauch oder Feuer aus dem Gerät austritt (oder in anderen Notsituationen), schalten Sie das Gerät sofort aus – mit allen zugehörigen Sicherungsautomaten im Gestell-Anschlussfeld.




23 (184)

If possible, first switch OFF the protection power supply and then the working power supply.

Schalten Sie möglichst zuerst die Ersatz-Stromversorgung aus, dann die Betriebs-Stromversorgung.

!!

However, consider that such an emergency shut-down can disconnect important communication lines which may be required just in the case of emergency.

Bedenken Sie jedoch, dass durch solch eine Notabschaltung wichtige Kommunikationsleitungen unterbrochen werden können, die gerade im Notfall eventuell dringend benötigt werden.

For this reason, shut down the device only if it is inevitable. Otherwise perform the normal switch-off procedure.

Nehmen Sie deshalb nur dann eine Notabschaltung vor, wenn es unumgänglich ist. Verfahren Sie sonst entsprechend der normalen Abschaltprozedur.

After the emergency shut-down, and if it does not pose any personal danger, check if the device is dead - either by using a measuring device or by the LED display of the device, if applicable.

Falls dies ohne Gefahr möglich ist, überprüfen Sie nach dem Notabschalten, ob das Gerät spannungsfrei ist - entweder mit einem Messgerät oder gegebenenfalls durch eine LED-Anzeige am Gerät.

2.12 Handling batteries / Handhabung von batterien

!!

Some equipment may contain accumulators or batteries of different technologies, e.g. lithium batteries or others.

Bestimmte Geräte können Akkumulatoren oder Batterien verschiedener z. B. Lithium-Batterien oder andere. Technologien enthalten.

Observe the following international standards, if applicable:

IEC 60130-17 (device interconnections)

IEC 61429 (recycling symbol)

IEC 61438 (safety and health hazards)

IEC 60086-4 (handling lithium batteries)

Beachten Sie gegebenenfalls auch folgende internationale Normen:

IEC 60130-17 (Geräteverbindungen)

IEC 61429 (Recyclingsymbol)

IEC 61438 (Sicherheits- und Gesundheitsrisiken)

IEC 60086-4 (Umgang mit Lithium-Batterien)

Pay attention to error messages referring to the accumulator or the battery.

Achten Sie auf Fehlermeldungen, die sich auf den Akkumulator bzw. die Batterie beziehen.




24 (184)

Accumulators or batteries which are integrated in the device should only be replaced by the equipment manufacturer.

Ins Gerät eingebaute Akkumulatoren oder Batterien sollen nur beim Gerätehersteller ausgetauscht werden.

If replacement is necessary, do not remove the accumulator or the battery from the device, but send in the complete device / the module (card) or the removable battery pack.

Wenn ein Austausch erforderlich ist, dann bauen Sie nicht den Akkumulator oder die Batterie aus dem Gerät aus, sondern schicken Sie das komplette Gerät / die Baugruppe oder das herausnehmbare Batteriepack ein.

In order to prevent loss of data, the battery should only be replaced by the equipment manufacturer.

Zur Vermeidung von Datenverlust soll die Batterie nur durch den Gerätehersteller ausgetauscht werden.

!!

There is risk of explosion if the battery is not replaced correctly!

Wenn die Batterie nicht ordnungsgemäß ausgetauscht wird, besteht Explosionsgefahr!

!!

Never short circuit batteries directly without using a discharging resistor! Without a resistor very high current will flow causing a risk of explosion!

Schließen Sie niemals Batterien direkt ohne Entladewiderstand kurz! Ohne Widerstand können so hohe Ströme fließen, dass Explosionsgefahr besteht.

If the user depollutes batteries, must observe the local regulations applicable to hazardous waste.

Beim Entsorgen von Batterien müssen die örtlichen Vorschriften über Beseitigung von Sondermüll eingehalten werden.

2.13 Replacement components / Ersatzteile

When replacing any component, including ancillary parts such as electrical cables, fuses, fiber cables, conduit, mounting hardware, etc, use only original spare parts as provided by Nokia Siemens Networks or parts that are explicitly approved by Nokia Siemens Networks for use with SURPASS hiT 70xx series equipment.

Falls Sie an den Geräten oder an der Verkabelung irgendwelche Teile ersetzen, so dürfen Sie nur Original-Ersatzteile oder solche Teile verwenden, die vom Hersteller ausdrücklich zugelassen sind.




25 (184)

2.14 Waste Electrical and Electronic Equipment (WEEE) / Entsorgung von elektrischen und elektronischen Geräten

WEEE symbol

All waste electrical and electronic products must be disposed of separately from the municipal waste stream via designated collection facilities appointed by the government or the local authorities. The label shown is applied to all such devices.

WEEE-Symbol

Alle Elektro- und Elektronikgeräte sind getrennt vom allgemeinen Hausmüll über dafür staatlich vorgesehene Stellen zu entsorgen.

The correct disposal and separate collection of waste equipment will help prevent potential negative consequences for the environment and human health. It is a precondition for reuse and recycling of used electrical and electronic equipment.

Die sachgemäße Entsorgung und die getrennte Sammlung von Altgeräten dient der Vorbeugung von potentiellen Umweltund Gesundheitsschäden. Sie sind eine Voraussetzung für die Wiederverwendung und das Recycling gebrauchter Elektround Elektronikgeräte.

For more detailed information about disposal of such equipment, please contact Nokia Siemens Networks.

Ausführliche Informationen zur Entsorgung Ihrer Altgeräte erhalten Sie bei ihrem Nokia Siemens Networks Partner.

The above statements are fully valid only for equipment installed in the countries of the European Union and is covered by the directive 2002/96/EC. Countries outside the European Union may have other regulations regarding the disposal of electrical and electronic equipment.

Diese Aussagen sind nur gültig für Geräte, die in den Ländern der Europäischen Union installiert und verkauft werden und die der Europäischen Richtlinie 2002/96/EC unterliegen. In Ländern außerhalb der Europäischen Union können davon abweichende Bestimmungen für die Entsorgung von Elektro- und Elektronikgeräten gelten.

Installation procedures and preparation



26 (184)

3 Installation procedures and preparation This chapter provides the overall installation guide and describes the detailed preparation before installation. The preparation includes personnel requirements, required tools and accessories, site preparation, and unpacking and verifying contents.

3.1 Declaration of CE conformity

!! CAUTION

The CE declaration of conformity for the product will be fulfilled if the construction and cabling is undertaken in accordance with the manual and the documents listed therein, e.g., mounting instructions, cable lists. Where necessary account should be taken of project-specific documents. Deviations from the specifications or unstipulated changes during construction, e.g., the use of cable types with lower screening values, can lead to violation of the CE requirements. In such cases the conformity declaration is invalidated and the responsibility passes to those who have caused the deviations.

3.2 Personnel requirements

The personnel responsible for the installation of the equipment must meet the following requirements:

• Training as service technician or equivalent training in telecommunications;

• Sound basic knowledge of transmission technology and the construction of exchanges;




27 (184)

• Relevant, practical training by the equipment manufacturer, including knowledge acquisition of the equipment and systems required for the planned activity;

• PC knowledge, basic familiarity with the operation of MS-Windows;

• Basic knowledge of test engineering, familiarity with the operation of test equipment;

• Familiarity with handling electrostatic-sensitive components;

• Familiarity with handling optical fibers and laser sources;

• Familiarity with handling high temperature electronic modules having heat-sinks and components conducting heat above 45 degrees Celsius (113 degrees Fahrenheit).

3.3 Required tools and accessories

• ESD grounding bracelet

• Isopropanol 99% and lint-free cloth for cleaning optical connectors

• Cleaning device for SFP modules (e.g., CLETOP stick from ExceLight Communications, Inc.)

• Special cotton gloves for touching high temperature equipment between 45 and 85 degrees Celsius (113 to 185 degrees Fahrenheit)

3.4 Checking for intactness

Prior to commissioning and starting up the SURPASS hiT 7035, it is advisable to check the delivered equipment, including provided accessories, to ensure that:

• The correct items have been delivered with assembled customized hardware;

• The delivered items correspond to the information on the delivery documents; and

• None of the items are visibly damaged.

!!

CAUTION Particular attention should be paid to the connector pins at the cards, to ensure that they are not damaged or bent.




28 (184)

3.5 Installation steps

Tab. 3.1 lists the major steps in the SURPASS hiT 7035 system installation process.

Step 1 Site preparation

Step 2 Installing the chassis

Step 3 Installing power supply module, and connecting to the power supply

Step 4 Installing cards, SFP lasers, and connecting fibers and cables

Step 5 Connecting system management interfaces

Tab. 3.1 SURPASS hiT 7035 installation process

3.6 Site preparation

This section provides instructions for preparing the location where the SURPASS hiT 7035 system and components are to be installed.

Before choosing a set-up location for the SURPASS hiT 7035, read and consider the safety precautions provided in Chapter 2.

Upon arrival of the equipment, inspect the condition of the received cartons and compare all items to the packing list attached to the carton.

Select the installation location carefully based on the overall specifications. The primary considerations for selecting an installation site include:

• Proximity of associated equipment such as optical multiplexers

• Reach of DC power supply

• Adequate rack space

• Proper ventilation

• Adequate space for cable routing

In addition to the items provided in the accessory kits, the recommended tools and equipment for the successful installation, operation, and maintenance of the system and optical fibers are:

• #1 Phillips screwdrivers (5 inch)

• Straight blade screwdriver (4 mm)

• Nut driver (10 mm) or deep socket wrench




29 (184)

Additionally, it may be helpful to use the following optional tools or accessories:

• Optical power meter

• SONET/SDH transmission analyzer

• Fiber optic cleaning kit and absolute alcohol

• Absorbent cotton or lens cleaning tissue

• Pressurized dry-air duster

• Fiber inspection scope

ii Note Be careful not to over-tighten any thumbscrews on the SURPASS hiT 7035 chassis and applicable components. To properly tighten a thumbscrew, torque the thumbscrew to 0.68 N.M using a torque screwdriver fitted with a #1 Phillips bit, or an equivalent torque wrench. If a torque screwdriver/wrench is not available, hand-tighten the thumbscrew, and then use a #1 Phillips screwdriverto gently tighten it further until it is snug.

3.7 Unpacking shipping box

SURPASS hiT 7035 shipment includes:

• One chassis enclosed in a protective shipping carton, which can be reused if the unit requires future shipment.

• A chassis accessory kit, as applicable. (See Tab. 3.2)

• The shipping chassis will contain SURPASS hiT 7035 cards ordered as part of this installation.

• The shipping chassis will also contain power modules.

Follow the procedures in the following sections to verify the shipment and unpack the shipping cartons.

!!

WARNING Check the contents of the accessory kits that are included in the shipment against the items listed on the packing lists. Verify that the shipment is complete. A fully configured system can weigh up to 50 Kg. To minimize the risk of personal or mechanical injury, exercise caution.




30 (184)

Items Quantity

Anti-static strap 1

DC power 48 V cable assembly, 3 m 2

Grounding cable assembly, 2.5 m 1

Screw, PHMS M5 0.8 x 8 LG (POZI), SST 1

Installation bolts and nuts, 8 2

Serial line for CLI interface, 2 M, 9 pin, F-F (1 to 1) 1

GB/T 859-1987 9.2 OD x 5.4 ID x 1.2 THK, SST (lock washer for M5 screw) 1

GB/T97 1-2002 10.0 OD x 5.3 ID x 1.0 THK, SST (washer for M5 screw) 1

6 mm2 ring terminal 4

Tab. 3.2 List of accessories

!! CAUTION Do not attempt to repair or modify the fan unit assemblies. Although the fan unit assemblies are field replaceable, there are no user-serviceable parts inside the fan unit assemblies.

3.8 Unpacking the individual card shipping cartons

Carefully remove each card from its individual shipping carton, but do not remove it from its ESD-protective packaging until ready to insert it into the chassis.

3.9 Unpacking the software shipping cartons

The CF card goes with the software files. Check the software load version as P42022-P5143-D1.

Now that the user has completed the installation-preparation steps and has verified the factory-installed hardware components. The next step is to install the chassis into the equipment rack and then connect it to a frame ground.

Installing the hardware



31 (184)

4 Installing the hardware Please read this whole chapter carefully before starting the installation process. This chapter describes the detailed procedures for installing and initializing the SURPASS hiT 7035 including installation of the chassis, connecting cables, connecting administrative links, and powering the system.

!!

CAUTION The equipment should be used within restricted access areas.

4.1 Installing the chassis

This chapter guides the user to successfully install the SURPASS hiT 7035 chassis on a standard rack.

!! WARNING Before installing modules or connecting power to the system, connect the system to a dedicated Frame Ground (earth ground) and ensure that the grounding cable is connected to an external earth or building ground. Failure to do so before connecting power may damage the equipment.

!! WARNING Static electricity can damage the equipment. Wear a properly grounded antistatic strap when handling any of the hardware components.

ii Note For ease of installation and to ensure safe lifting and handling of equipment, it is recommended that two people work together on the mounting installation.




32 (184)

Follow these guidelines to prevent Electrostatic Discharge (ESD): • Before installing the chassis into the equipment rack, make sure the

equipment rack is properly grounded.

• When handling any of the hardware components, be sure to wear the antistatic wrist strap (provided in the accessory kit).

• Insert the antistatic strap cable pin into the ESD grounding jack on the chassis.

Fig. 4.1 ESD grounding jack

4.1.1 Standard racks

SURPASS hiT 7035 chassis dimensions are 400 mm (width) × 468 mm (height) × 300 mm (depth). The chassis can be front mounted in the following two racks:

• EIA 310 19” rack (see Fig. 4.2)

• ETSI 21” rack (see Fig. 4.3)

• Nokia Siemens Networks 7300 rack (see Fig. 4.4)

ii Note Nokia Siemens Networks 7300 rack is also termed Nokia Siemens Networks ETSI rack S42022-L5020-A11.




33 (184)

Procedures in this manual assume the SURPASS hiT 7035 chassis is mounted in Nokia Siemens Networks 7300 rack. If installing the SURPASS hiT 7035 chassis in other type of racks, different mounting kits are needed.

Fig. 4.2 Mounting bracket for 19” rack

Fig. 4.3 Mounting bracket for ETSI 21” rack




34 (184)

Fig. 4.4 Mounting bracket for Nokia Siemens Networks 7300 rack

4.1.2 Adjusting the chassis installation position

Before mounting the chassis in a rack, please do arrange the position of equipment and accessories (such as chassis, Ethernet splitter panel) in the whole rack. Otherwise, the user may not be able to finish the mounting and cabling.

A maximum of three (3) sets of SURPASS hiT 7035 chassis can be mounted in a rack. 3 U (about 133 mm) space is required for heat dissipations.

If the SURPASS hiT 7035 is fully mounted with E1 cables, a maximum of two (2) sets of SURPASS hiT 7035 chassis can be mounted in a rack.

ii Note If two (2) sets of SURPASS hiT 7035 chassis are mounted in a rack, E1 cables can be routed towards the top or bottom of the rack.

If three (3) sets of SURPASS hiT 7035 chassis are mounted in a rack, E1 cables should be routed towards the bottom of the rack.

The position of the channel mounting in the rack is shown in Fig. 4.5.




35 (184)

Fig. 4.5 Channel mounting position

4.1.3 Connecting the chassis to the grounding cable

The earth grounding cable should be the same gauge as the power feed cable (minimum requirement). Connect the grounding cable to the grounding point on the right side of the chassis, as shown in Fig. 4.6.




36 (184)

Fig. 4.6 Grounding point

!!

CAUTION Before mounting the chassis, place the cage nuts in the designed positions on the channel mounting vertical frame, and the recommended chassis positions in the rack. (See to Fig. 4.7 and Fig. 4.8)

ii Note The chassis positions on an ETSI 21” rack and an Nokia Siemens Networks 7300 rack are the same.




37 (184)

Fig. 4.7 Recommended chassis position in Nokia Siemens Networks 7300 rack (2 sets)




38 (184)

Fig. 4.8 Recommended chassis position in Nokia Siemens Networks 7300 rack (3 sets)




39 (184)

4.2 Equipping the chassis

Required tools:

• Anti-static strap

• #1 Phillips screwdrivers (5 inch)

• Straight blade screwdriver (4 mm)

• Nut driver (10 mm) or deep socket wrench

• Cross screwdriver (Φ 5 x 150 mm)

4.2.1 Installing module cards

The SURPASS hiT 7035 includes one subrack and twenty-five (25) slots that can be configured with different modules as follows:

• 1 Enhanced System Controller (SCE) slot

• 2 power slots

• 1 fan unit slot

• 2 Cross-Connect (CC) slots (long card slots)

• 1 SI slot

• 11 traffic slots

• 7 I/O slots (which can be flexibly configured for interface cards.)

The slots designation is shown in Fig. 4.9.




40 (184)

29 – (FAN)

21 –(SCE)

20 –(CC2) /

31 –(CC2 –

LC)

19 –(CC1) / 30 –

(CC1 –LC)

5 –(LC5)

4 –(LC4)

3 –(LC3)

2 –(LC2)

1 –(LC1)

15 –(IO4)

14 –(IO3)

13 –(IO2)

12 –(IO1)

23 –(PWR2)

22 –(PWR1)

11 –(LC11)

10 –(LC10)

9 –(LC9)

8 –(LC8)

7 –(LC7)

6 -(LC6)

18 –(IO7)

17 –(IO6)

16 –(IO5)

28 –(SI)

Fig. 4.9 Arrangement of chassis slots and slots designation

In each slot of SURPASS hiT 7035 chassis, the allowable cards are described in Tab. 4.1.




41 (184)

Slot name1

Interface

SCE CC1

and

CC2

LC1

to

LC4

LC5 LC6

to

LC9

LC10

to

LC11

IO1

and

IO3

IO2

and

IO4

IO5 IO6

and

IO7

SI PWR1

to

PWR2

FAN Max. #

of cards

SCE √ 1

PWR √ 2

FAN √ 1

CC + 1 x STM-16/4 √ 2

CC + 1 x STM-4/1 √ 2

ST-CLK √ 1

1 x STM-4 √ 4

2 x STM-1 √ 4

4 x STM-1 √ 4

1 x GE/T √ 4

8 x FE/T √ 4

8 x FE/L2 √ 4

IMA (W/P) 2 √ 4 (1 + 1)

2 x STM-1 ATM IO 3 √ 2

63 x E1 (W/P) √ √ 5 (1 : N, N <= 4)

63 x E1 IO √ √ 4

3 x E3/DS3(W/P) √ 4 (1 : N, N <= 3)

3 × E3/DS3 IO √ √ 3

2 × STM-1E(W/P) √ 4 (1 + 1)

2 × STM-1E IO √ 2

OA √ √ 6

Tab. 4.1 Subrack slot arrangement and card options

1 For complete slot naming please refer to Fig. 4.9.

2 The IMA cards are only available when NE is equipped with CC + 1 x STM-16/4 cards.

3 The 2 x STM-1 ATM IO cards are only available when NE is equipped with CC + 1 x STM-16/4 cards.




42 (184)

!!

CAUTION Only the Enhanced System Controller (SCE) card is supported in SCE slot. If a predecessor System Controller (SC) card is installed with hiT 7035 R4.3 software load, the software program will halt.

ii Note Optical and electrical interfaces are both accessed from the front of the shelf. Card faceplates are provided for each card and contain information on card type, LED description, and a label with the unique serial number for that card. Dummy cards are available for empty slots.

!!

CAUTION A dummy faceplate must be installed if any slot is unequipped with a card.

Inserting module cards To install a module card, identify the correct slot location in the shelf and then follow the steps below:

1. Open the latches on both ends of the card. (See Fig. 4.10)

2. Carefully slide-in the module card, and make sure the card mates properly with its backplane connector.

3. Carefully close both latches at the same time, and ensure that the latches are secure.

4. To fix the card position mechanically and to ensure ESD shielding, use the appropriate cross-tip screwdriver to tighten the captive crosshead screws on the upper and lower end of the faceplate.




43 (184)

Fig. 4.10 Inserting a module card

ii Note To remove a module card, reverse the steps of inserting a module card.

!! CAUTION If SCE latch state is changed to open, Ethernet traffic using MSTP, GVRP, LACP, and/or IGMP-Snooping protocols will be disrupted until the SCE card is warm rebooted or removed and re-inserted into the slot.

!! CAUTION Do not remove any card during its initialization process.

ii Note If the NE is equipped with several cards and at least one 8 x FE/L2 card, insert or remove cards one by one quickly from LC1 to LC8, because the port mode on 8 x FE/L2 may change from “auto” to “monitor”.




44 (184)

4.2.2 Inserting CF card

The CF card should be inserted in the SCE card before the SCE card is inserted in the chassis.

!!

CAUTION CF cards should be validated and provided by Nokia Siemens Networks. Any CF card from other supply channels is forbidden and might cause system failure.

!!

CAUTION Make sure the release latch beside the CF slot is depressed. (See Fig. 4.11)

Fig. 4.11 Inserting CF card

4.2.3 Installing SFP optical modules

!!

CAUTION Before installing 2.5 Gbps DWDM SFP into a CC + 1 x STM-16/4 card, make sure the heat sink has been installed in the SFP cage (see Fig. 4.12and Fig. 4.13).




45 (184)

Fig. 4.12 SFP cage without heat sink

Fig. 4.13 SFP cage with heat sink installed

To install the heat sink, place the heat sink onto the SFP cage and secure the cage assembly with a clip. After the heat sink and clip are installed, the following requirements must be applied (see Fig. 4.14).

• The perimeter of the heat sink must be flush with the top of the frame of the cage assembly.

• The raised boss must be centered in the cavity of the cage assembly.




46 (184)

• The clip locking windows must be fully latched onto the attachment latches of the cage assembly.

Any heat sink used must be flush with and securely attached to the cage assembly.

Fig. 4.14 Heat sink installation

SFP laser plug-in modules can be installed in the card either before or after the card is inserted in the chassis. However, inserting SFP modules after the card has been placed in the chassis is recommended.

SFP laser modules must be gently inserted into the SFP slots on the faceplate of the card. They seat with a slight click.

ii Note To remove an SFP laser module, first lift it upward a bit, and then pull it out gently.




47 (184)

Fig. 4.15 SFP optical module

ii Note When inserting or removing an SFP, a one second interval is required before continuing to the next operation. The system is designed using a POLLING mechanism to detect the SFP insertion or removal. If an SFP insertion is followed immediately by the SFP removal or vice versa, the system may not be able to detect the operation.

4.2.4 Replacing or adjusting fan unit

To replace or adjust the fan unit located at the bottom of the chassis, follow the procedure below:

1. Removing the fan unit (see Fig. 4.16) First open the paddle latch by hand until the faceplate of fan unit assembly has been pulled away from the chassis frame, and then remove the fan unit smoothly.




48 (184)

Fig. 4.16 Removing the fan unit

2. Inserting the fan unit smoothly (see Fig. 4.17) First open the paddle latch, and then smoothly push the faceplate of the fan unit assembly until it mates with the chassis frame. An improperly mated fan unit will extend out the front of the chassis about 1 mm or 2 mm.

Fig. 4.17 Inserting the fan unit




49 (184)

4.2.5 Replacing air filter

Due to high air flow rate, air filter is required to protect the main shelf from environmental dust and other contaminants.

!! CAUTION An excessively dirty air filter will reduce cooling airflow.

ii Note The user should clear the filter and fan regularly as routine work for maintenance. It is recommended that the air filter should be replaced every 3 months or more frequently if environmental conditions warrant. The action of the air replacement must be finished within 10 minutes.

!! CAUTION For replacement only original spare parts have to be used or replacement material must be rated HF-1 or better in accordance to IEC/EN 60950-1.

!! CAUTION The air filter is part of the fire enclosure. Therefore It is forbidden to run the network element without the air filter.

To remove the air filter, grab the two handles on its faceplate, and then pull it out smoothly. (See Fig. 4.18)




50 (184)

Fig. 4.18 Removing the air filter (top view)

4.3 Connecting cables

This section describes the categories of cables used in the system and the proper cable connection procedures.

4.3.1 Cable list

Fig. 4.19 below identifies the location of the different kinds of cables. The description of each cable is provided in Tab. 4.2.




51 (184)

Fig. 4.19 Cable locations




52 (184)

Number Cable name SURPASS hiT 7035 NE

connector and cable type

1 Fiber LC, Fiber

2 E1 cable 7 x E1 2-mm connector, coaxial cable assembly (75 Ohm) /twin-axial cable assembly (120 Ohm)

21 x E1 2-mm connector, coaxial cable assembly (75 Ohm) /twin-axial cable assembly (120 Ohm)

3 Management cable RJ 45, CAT 6

4 Auxiliary cable RJ 45, Ethernet cross-over cable

5 EOW cable RJ 45, CAT 6

6 Console cable RS 232, coaxial cable

7 MDI/MDO/Station alarm cable RJ 45, CAT 6

8 Timing cable CC 4-1.0, coaxial cable

9 STM-1E cable CC 4-1.0, coaxial cable

10 E3/DS3 cable CC 4-1.0, coaxial cable

11 Ethernet cable RJ 45, CAT 6

12 Power cable 3-pin D type

13 Grounding cable 10 mm2, both ends with ring terminals

Tab. 4.2 List of SURPASS hiT 7035 required cables

4.3.2 Connecting power cables

The SURPASS hiT 7035 chassis has two -48 V DC power module cards (see Fig. 4.20). The SURPASS hiT 7035 chassis requires at least -48 V DC power module, however two DC power modules is recommended.

When the system is equipped with two DC power inputs, the two DC power input feeds 1 and 2 share the load. The chassis can run indefinitely off the power from either input. The power input with the higher voltage will carry substantially the entire system load. However, Nokia Siemens Networks recommends that two separate -48 V DC power feeds be used at all times.




53 (184)

Fig. 4.20 DC power module

!! CAUTION Each power source must be externally (over-current) fused or circuit breaker protected.

ii Note It is highly recommended to remove the power cables before removing the power modules. It is also mandatory to insert the power modules before connecting the power cables.

It is recommend to route the two DC power cables on the right side of the chasiss first, and then tie it; thus they can be routed to the power source (fuse panel) conveniently (see Fig. 4.21).

Fig. 4.21 DC power connection and routing




54 (184)

!! CAUTION For site planning and preparation, consider separate power requirements from thermal/cooling requirements. Power requirements vary with the system configuration. Each station circuit or power feed source should be sized to allow for future configuration changes and for operation at lower input voltages from batteries during an AC power outage. Actual power usage should be estimated from the operating power for all system elements to be installed. These estimates can then be used to plan the cooling system load and the cost of power used.

!! CAUTION Station circuit size and current rating should be based on the maximum expected power usage, up to the design capacity of the chassis. This ensures that future configurations can be supported without changing the circuit breaker or wiring.

ii Note To compensate for voltage drop in the chassis wiring, lower battery feed voltages, and future configuration changes, consider using a higher rated station circuit breaker.

The recommended value for the circuit breaker of the rack is 10 A.

!! CAUTION The appropriate wire gauge requirement for the SURPASS hiT 7035 power station circuit depends on several factors:

• Distance from the power source

• Applicable wiring codes, including local electrical safety and fire prevention codes

• Other standards applicable to the installation such as local practices

• Voltage range at the power source or station panel

• Station circuit breaker rating

!! CAUTION When estimating wire resistance, include the round-trip distance between the power source panel and the chassis. Also consider wire temperature-rise guidelines for the installation as part of the selection for the correct wire size. The wiring design must meet all applicable local and national wiring codes.




55 (184)

Connecting the DC power supply cable The SURPASS hiT 7035 uses 3-pin D power connectors. The power supply cable connection procedure is as follows:

1. Put on the antistatic strap and connect one end to the ESD grounding jack.

2. Ensure the chassis is connected to an earth frame ground, if needed follow the instructions in Chapter 4.1.3.

3. Verify that the power source is either -48 V DC or -60 V DC (nominal).

4. Disable the power source that will power the chassis by switching the appropriate circuit breaker on the Battery Distribution Fuse Block (BDFB) or power distribution panel to the “Off” position.

5. Connect the un-connected ends of the power cable to the two -48 V power sources (see Fig. 4.22).

6. Connect the 3-pin D power connector ends of the power cables to the corresponding power cards inputs.

7. Turn on the power source used to power the chassis.

Fig. 4.22 -48 V DC power source panel




56 (184)

4.3.3 Connecting fiber jumpers

All optical connectors in the SURPASS hiT 7035 use LC connectors. Before connecting optical fibers, check and clean the fiber connectors first.

ii Note It is suggested to route all optical jumpers straight down the chassis. All fibers should be inserted and collected in the fiber tray (see Fig. 4.23).

Fig. 4.23 Fiber jumpers routing

ii Note Use fiber protection wiring to surround whole fiber routed in the rack (see Fig. 4.24).




57 (184)

Fiber Protection Wiring

Fig. 4.24 Fiber protection wiring

4.3.4 Connecting E1 cables

SURPASS hiT 7035 provides two types of 63 x E1 IO cards, one is with cable bracket (see Fig. 4.25) on the faceplate and the other is without cable bracket.




58 (184)

Fig. 4.25 E1 cable bracket

Different connectors are used in the two different cards. The card with cable bracket uses a 7 x E1 2-mm connector which supports 7 x E1 signal (see Fig. 4.26), and the other one uses a 21 x E1 2-mm connector which consists of three 7 x E1 2-mm connectors (see Fig. 4.27).

Fig. 4.26 7 x E1 2-mm connector




59 (184)


Nokia Siemens Networks offers E1 cable with a 7 x E1 2-mm connector or a 21 x E1 2-mm connector at one end, and the other end is free and can be customized to adapter the DDF.

For E1 cable with a 7 x E1 2-mm connector, the connection procedure is as follows (see Fig. 4.28):


2. Connect the 7 x E1 2-mm connector end of E1 cable to the E1 card.

3. Connect the other end of the E1 cable to the customer equipment.




60 (184)

Fig. 4.28 Connecting E1 cable with 7 x E1 2-mm connector

ii Note There is a triangle label on both E1 card and the connector of E1 cable. When plugging in the E1 cable, make sure the triangle label is on the top side. For the 120 Ohm E1 cable, it is not necessary to use the ferrite ring.




61 (184)

For E1 cable with a 21 x E1 2-mm connector, the connection procedure is as follows (see Fig. 4.29):


2. Connect the 21 x E1 2-mm connector end of E1 cable to the E1 card.

3. Connect the other end of the E1 cable to the customer equipment.

Fig. 4.29 Connecting E1 cable with 21 x E1 2-mm connector




62 (184)

ii Note The E1 cables should be grounded at the user side (DDF).

SIPAC connector panel

Nokia Siemens Networks offers a SIPAC connector panel to protect customer investment when the customer upgrades their legacy equipment. The panel is used as an adapter between SCSI 100 connector and SIPAC connector. Up to 126 x E1 can be connected for each panel. The SIPAC connector panel can be installed in the ETSI 21” rack and Nokia Siemens Networks 7300 rack.

Fig. 4.30 shows the SIPAC adapter bridges of the 2 Mbps ports. There are two interface blocks in an SIPAC panel. Each block consists of three SIPAC adapter bridges and supports 63 x E1 signal.

Fig. 4.30 SIPAC connector panel

SIPAC connector panel cable connection procedure:


2. Connect the 2-mm connector end of an E1 cable to the E1 card.




63 (184)

3. Connect the other end of the E1 cable (in step 2) to the SCSI 100 connector on the right side of SIPAC panel.

4. Connect another E1 cable with SIPAC connector to the SIPAC connector on the left side of SIPAC Panel. Be sure that the SIPAC slot number is the same as the SISI 100 slot number connected in step 2.

5. Connect the other end of the E1 cable (in step 4) to the customer equipment.

Fore more information on SIPAC slot numbering, please refer to Chapter 10.3.

4.3.5 Connecting E3/DS3 cables

The E3/DS3 interfaces on the SURPASS hiT 7035 3 x E3/DS3 card use CC 4-1.0 connectors. (See Fig. 4.31)

E3/DS3 cable connection procedure:


2. Connect the E3/DS3 cable CC 4-1.0 connector end to the E3/DS3 interface on the E3/DS3 card.

3. Connect the other end of the E3/DS3 cable to the customer equipment.




64 (184)

Fig. 4.31 E3/DS3 cabling

4.3.6 Connecting STM-1E cables

The STM-1E interfaces on the SURPASS hiT 7035 2 x STM-1E card also use CC 4-1.0 connectors (see Fig. 4.32).




65 (184)

Fig. 4.32 STM-1E cabling

The STM-1E cable connection procedure is the same as the E3/DS3 cable.

4.3.7 Connecting administrative cables

The SURPASS hiT 7035 system management interface is located on the Enhanced System Controller (SCE) card. It is shown in Fig. 4.33:

Fig. 4.33 SCE card faceplate

The interfaces from the left to the right are as follows:




66 (184)

• MDI interface (1 - 4) (RJ 45 connector)

• MDO interface (1 - 4) (RJ 45 connector)

• Alarm interface to the station alarm output (RJ 45 connector)

• Console interface (RS 232 interface, DB 9 connector)

• EOW interface (Channel 1 ~ 2, RJ 45 connector)

• AUX interface (RJ 45 connector)

• Network management interface (RJ 45 connector)

Administrative cables consist of:

• Console cable

• Auxiliary cable (Ethernet cross-over cable)

• Management cable

• MDI cable

• MDO cable

• Station alarm cable

• EOW cable

ii Note Auxiliary interface has a similar function to the console interface. The user can directly connect to the NE to do some local configuration using the AUX port. Pay attention that the Ethernet cross-over cable must be used and the auxiliary interface has a fixed IP address as 192.168.0.2.

For more information on MDI/MDO ports specification, please refer to the SURPASS hiT 7035 Product Description.

Administrative cables connection procedure is as below:


!!

CAUTION The voltage of MDI is -48 V. The MDI cable only can be inserted into the MDI interface. Inserting MDI cable into other interfaces may cause the SCE card damage.




67 (184)

2. Connect the administrative cables to the corresponding connectors on the SCE card.

3. Connect the other ends of the cables to the corresponding equipment.

Fig. 4.34 Administrative cables layout (console cable)

Fig. 4.35 Administrative cables layout

4.3.8 Connecting timing cables

The SURPASS hiT 7035 provides two timing input ports and two timing output ports. The external timing station is connected to the SURPASS hiT 7035 timing ports through timing cables.

The SURPASS hiT 7035 timing ports use CC 4-1.0 connectors. Nokia Siemens Networks offers a timing cable with a CC 4-1.0 connector at one end and the other end of the timing cable can be customized to match the external timing source connector.




68 (184)

Fig. 4.36 Timing cable connection

Timing cable connection procedure:


2. Connect a timing cable to the external timing source output.

3. Connect the CC 4-1.0 connector end of the timing cable to the SURPASS hiT 7035 timing input port.

4. Connect another timing cable to the external timing source input.

5. Connect the CC 4-1.0 connector end of the timing cable to the SURPASS hiT 7035 timing output port.

4.3.9 Connecting Ethernet cables

Ethernet cables are made of CAT 6 twisted-pair cables. If the transmission distance is less than 10 meters, any Ethernet cable can be used. If the transmission distance is over 10 meters, use the pin arrangement recommended in Chapter 10.4.

Ethernet cables should be routed toward the top of the chassis (see Fig. 4.37).




69 (184)

Fig. 4.37 Ethernet cabling

Ethernet cable connection procedure:


2. Insert the Ethernet cables to each FE port.

3. Connect the other end of the Ethernet cables to the Ethernet splitter panel.

4.3.10 Connecting Ethernet splitter cables

Please install the Ethernet splitter panel assembly strictly following procedure below.

1. Install the Ethernet splitter into the Ethernet splitter panel. There are up to 16 splitters for each panel (see Fig. 4.38). For each splitter, one side has one port called EQ port which is connected to SURPASS hiT 7035




70 (184)

FE port, and the other side has two ports, i.e., port A and port B, which are connected to customers’ equipment (see Fig. 4.39). EQ port should be put at the back side of the Ethernet splitter panel.

Fig. 4.38 Ethernet splitter panel view




71 (184)

Up Side View

Left Front View

Right Back View

Fig. 4.39 Ethernet splitter side view

2. Connect the RJ 45 interfaces from Ethernet interface card to the Ethernet splitter panel (EQ ports) with the Ethernet cables (see Fig. 4.40).

Fig. 4.40 Ethernet splitter panel back view

3. Connect the RJ 45 interfaces from the client signal connection to the front of the Ethernet splitter panel (A, B ports) with the Ethernet cables (see Fig. 4.41).




72 (184)

Fig. 4.41 Ethernet splitter panel front view

The complete Ethernet splitter cable layout (front and top view) is shown below (see Fig. 4.42 and Fig. 4.43).

Fig. 4.42 Ethernet splitter cables layout (front view)

Fig. 4.43 Ethernet splitter cables layout (back view)

Ethernet splitter cable connection procedure:




73 (184)


2. Connect the Ethernet cables from FE card ports to Ethernet splitter panel EQ ports.

3. Connect the Ethernet cables from Ethernet splitter panel A and B ports to Customer Premise Equipment (CPE).

4.3.11 Complete cable layout

The complete cable layout is shown in Fig. 4.44 below.




74 (184)

Fig. 4.44 Complete cable layout

Connecting and configuring an operation terminal



75 (184)

5 Connecting and configuring an operation terminal The SURPASS hiT 7035 LCT (using TMNS CT LCT mode) can be installed and configured on the PC connected to the SURPASS hiT 7035 for commissioning.

5.1 PC requirements for use as an operating terminal

The SURPASS hiT 7035 LCT software can run on the Microsoft Windows based operating system on a desktop or laptop PC.

ii Note For more information on detailed hardware requirements, please refer to the TNMS CT User Manual.

5.2 Connecting the operating terminal

It is recommended to begin the commissioning of the SURPASS hiT 7035 by connecting the operating terminal to the SURPASS hiT 7035 MGMT (Ethernet) port.

5.3 Installing Element Manager Software (EMS)

After selecting the SURPASS hiT 7035 product, technical support technicians from Nokia Siemens Networks will help to complete selecting and installing

Connecting and configuring an operation terminal



76 (184)

hardware and software based on requirements. A SURPASS hiT 7035 TNMS CT installation CD will be provided. Install the software package from the CD provided using the program’s wizard mode on any qualified operating system.

5.3.1 Installing the TNMS CT software package

For detailed information on how to install the TNMS CT software, please refer to the TNMS CT User Manual.

Starting up the SURPASS hiT 7035



77 (184)

6 Starting up the SURPASS hiT 7035

ii Note Before supplying power to the SURPASS hiT 7035, verify that the following tasks are completed:

• The antistatic procedures are in place.

• The chassis is securely installed in the equipment rack.

• The station circuit breaker is off.

• The user has reviewed the power specifications and warnings outlined in Chapter 2.

• The power supply source is correctly connected.

• Use multi-meter to measure the power source voltage. The DC voltage should be -48 V or within the -40 V ~ -72 V range.

• Running the system without a CC card is an abnormal operation, which should be prohibited. Please make sure that the CC module has been mounted properly before powering on the system.

• If the CC cards (both working and protection cards) have been removed under the normal status while the system is running, a cold reboot is mandatory to restore the system after the card has been replaced.

• The CF card has been inserted into the SCE card.

6.1 Initial startup of a new system

The first time to power on the SURPASS hiT 7035 unit, the user needs to use the HyperTerminal through console interface to provision the unit. This section describes the basic operation procedures to provision the SURPASS hiT 7035 unit.




78 (184)

ii Note Before the user begins:

• Make sure the hardware has been installed.

• Make sure the SURPASS hiT 7035 NE is connected to the DC voltage with the power off.

• Make sure the SURPASS hiT 7035 NE is connected to a local computer using the console port using an RS 232 cable.

6.1.1 Setting up a HyperTerminal connection

To initialize the system, the user needs to create a HyperTerminal connection to the console port using an RS 232 cable.

Naming the unit In the HyperTerminal window shown below, enter the unit name 7035, and click OK.

Fig. 6.1 HyperTerminal connection description window

Selecting a connection port Select COMX in the “Connect To” window and click OK. COMX means the physical COM port which the user uses.




79 (184)

Fig. 6.2 HyperTerminal COM port selection window

The “COMX Properties” window will be shown (see Fig. 6.3).

Port configuration:

Fig. 6.3 HyperTerminal COM port properties window




80 (184)

Configure the Port Settings as follows:

• Bits per second: 9600 • Data bits: 8 • Parity: None • Stop bits: 1 • Flow control: None Click OK.

6.1.2 Coping CF load/MIB to flash

Turn on the power to the SURPASS hiT 7035. The HyperTerminal window appears. (See Fig. 6.4)

Press <b> to stop the boot-up process.

Fig. 6.4 Stopping the boot-up process

“Boot mode” windows appears, press <p> for CF copy option (see Fig. 6.5 ).




81 (184)

Fig. 6.5 Boot mode window

The “CF Load/Mib copy to Flash” window appears (see Fig. 6.6).

Fig. 6.6 CF Load/MIB copy to flash window




82 (184)

Press <1>, and then press <y> to copy load from CF to flash. It takes about 5 minutes.

Press <2>, and then press <y>, to copy the MIB to flash. It takes about 1 minute.

ii Note Before updating the boot image, the Boot device in the “IP Configuration” prompt must be set as motfcc. See Fig. 6.7.

Fig. 6.7 Setting boot device in the boot mode of NE

Press <3>, and then press <y> to update the boot image. It takes about 1 minute.

ii Note Before rebooting the NE, make sure to set the Boot device as auto in the “IP Configuration” prompt.




83 (184)

Fig. 6.8 Setting boot device before rebooting NE

After finishing all the operations, press <x> to return to the boot mode. Press <r>, and then <y> to reboot the NE.

6.1.3 NE general configuration

Login After successfully booting the system, the “Login” window appears.

ii Note It takes about four (4) minutes for SURPASS hiT 7035 to complete the boot process.




84 (184)

Fig. 6.9 Login window

At the Username prompt, enter root as the user name.

At the Password prompt, press Enter. The “Main Menu” window appears. (See Fig. 6.10)




85 (184)

Fig. 6.10 HyperTerminal Main Menu window

ii Note When inter-working with the NE of SURPASS hiT 7070 or SURPASS hiT 7050, the IP address 192.168.0.0 and the mask 255.255.224.0 are preserved so they are forbidden to be used.

IP address settings Press <I> from main menu to configure the Node IP address, the Management Port IP Address, the Management Port Subnet Mask, and the Default Gateway for Management Port. The user can select options <1> to <4> to configure the IP address as required (see Fig. 6.11).




86 (184)

Fig. 6.11 IP Address Configuration window

ii Note Every NE should be configured with a Node IP. The Node IP should be unique within a network. Nokia Siemens Networks recommends that all nodes within the same ring share the same sub-network (network segment) for ease of future administration and expansion.

If the NE is directly connected to the SURPASS hiT 7035 LCT, this NE needs to set the Management Port IP Address which is the Ethernet address used to communicate with the Network Management System. Press <2> to set the Management Port IP Address of the NE and press <3> to set the Management Port Subnetwork Mask.

Click Start > Programs > Accessories > Command Prompt to open the “Command Prompt” window, and then use the command: route add <destination> <mask netmask> <gateway> -p

to enter the static route information. See an example in Fig. 6.12.




87 (184)

ii Note The user can use the command route/help to get more information about the route command.

Fig. 6.12 adding static IP route

If the Data Communication Network (DCN) uses Data Communications Channel (DCC) for the system management:

• Make sure that Ethernet address assigned to each NE is in a separate sub-network form each other.

• The PC with the LCT software installed on it must be assigned an Ethernet IP address that is in the same sub-network of the NE directly connected to it. This NE is the gateway of the DCN, and its Ethernet IP address is the gateway address of the DCN.

• When adding routes to cover all NE’s IP address, set the added NEs’ gateway IP address equal to the gateway address of the DCN.

Telnet login enable/disable Press <L> from the main menu to enable or disable the Telnet login functionality.




88 (184)

Fig. 6.13 Telnet Login window

DCC slot information Press <D> from the main menu to view the DCC information.




89 (184)

Fig. 6.14 DCC Slot Information window

6.2 Using the SURPASS hiT 7035 LCT

After the SURPASS hiT 7035 node is initialized, the user needs to use the SURPASS hiT 7035 LCT for system configuration, provisioning, and management.

For more information system configuration, please refer to Chapter 7.

For more information on how to use the SURPASS hiT 7035 LCT software, please refer to the SURPASS hiT 7035 LCT User Manual.

Configuring the SURPASS hiT 7035



90 (184)

7 Configuring the SURPASS hiT 7035 All hardware units are delivered to the customer in a fully configured state (i.e., with assembled customized hardware and installed software). Nevertheless, this chapter deals with the main software configuration for the SURPASS hiT 7035 as a basis for any subsequent customizations or extensions.

Help For more information on the menu and window structures of the SURPASS hiT 7035 LCT, please refer to the SURPASS hiT 7035 LCT User Manual and the SURPASS hiT 7035 Online Help.

!! WARNING When handling any hardware, the user must observe the protective measures given in Chapter 2.

!! CAUTION As a precondition for the software configuration procedures described below, the SURPASS hiT 7035 and the operating terminal must have been set up according to the preceding chapters, so that the communication between them is working properly.

!! CAUTION Each NE (such as SURPASS hiT 7035) must be configured and operated separately, since each one has its own communication interfaces and its own network address. For configuration purposes, the NEs must be connected in turn (one after the other) to the SURPASS hiT 7035 LCT.




91 (184)

7.1 EMS installation

For more information, please refer to Chapter 5.3.

7.2 NE configuration and management

After the LCT software installation has been completed, the user can start configuring the NE in LCT environment.

7.2.1 Starting SURPASS hiT 7035 LCT via TNMS CT

To establish connection for an NE via Telecommunication Network Management System (TNMS) Craft Terminal (CT), complete the following steps:

1. Starting the TNMS CT

For example, from the Windows taskbar select the Start > Programs > TNMS CT menu item to start the TNMS CT. The main “TNMS CT” window and the “Login” window are opened (see Fig. 7.1).




92 (184)

Fig. 7.1 TNMS CT login window

2. In the “Login” window, enter the User Name and Password to login the TNMS CT (see Fig. 7.2).




93 (184)

Fig. 7.2 TNMS CT main window

3. Click the button on the main tool bar. The “DCN Management” window is opened (see Fig. 7.3).




94 (184)

Fig. 7.3 DCN Management window

4. In the list of DCN Objects, select the TNMS-CT Server tree and click on the main tool bar. The “SNMP – Properties” window is opened (see Fig. 7.4).

In the General tab, enter an ID Name for a new DCN channel (e.g., SNMP) and click . The new SNMP item representing the DCN channel is displayed under the TNMS-CT Server icon.

Fig. 7.4 SNMP – Properties window




95 (184)

5. Select SNMP item and click on the main tool bar, the “Add Network Element” window is opened (see Fig. 7.5).

Fig. 7.5 Add Network Element window

6. Select Universal Snmpv3 NEC and click OK. The “Universal Snmpv3 NEC – Properties” window is opened (see Fig. 7.6).




96 (184)

Fig. 7.6 Universal Snmpv3 NEC – Properties window

7. In the General tab, modify the ID Name if necessary (e.g., SURPASS hiT 7035).

8. In the SNMP tab and enter the following settings (see Tab. 7.1). Click to confirm the settings and back to the “DCN Management” window.

Item Description

IP Address Enter the Internet Protocol (IP) address of the NE.

User Name Enter a string as the user name of the LCT. The default user name is Administrator.

Password Enter a string as the password of the LCT. The default password is NSN!e2eNet4u.

Telegram Timeout [sec] Enter an integer.

Telegram Retries Enter an integer.

Polling Interval [min] Enter an integer to indicate the polling interval.

Tab. 7.1 Login settings




97 (184)

9. Select the check boxes for the TNMS CT Server, SNMP channel, and SURPASS hiT 7035 (named in step 7 as an example). Right-click the SURPASS hiT 7035 list item and select the Activate/Deactivate menu item from the context menu to activate the newly added NE (see Fig. 7.7).

Fig. 7.7 Activate SURPASS hiT 7035 LCT

10. Make sure that the newly added NE is running properly. Right-click the SURPASS hiT 7035 and select Start Element Manager. The LCT is opened (see Fig. 7.8).

ii Note

• If there are multiple IP addresses configured on the PC, the IP address used as the LCT trap IP should be different from the one used as TNMS CT server IP. If the same IP address is used and TNMS CT is already running, the LCT program can not be started successfully.

• The NE will be disconnected from the LCT program when the NE is restarted. The LCT program will re-connect to the NE automatically after the NE is restarted. To connect manually, the user needs to wait at least 40 seconds after the NE is restarted.

• The date and time of the user’s PC should not be changed when LCT is running.




98 (184)

Fig. 7.8 SURPASS hiT 7035 LCT main window

7.2.2 Chassis view

When the SURPASS hiT 7035 LCT is connected to an NE, the NE chassis view will be displayed, which shows the real-time status of the NE (see Fig. 7.9).




99 (184)

Fig. 7.9 Chassis view

For example, when the 1 x GE/T card in Fig. 7.9 was inserted, a green Active label will be marked on the card. If the card is removed, a red Absent warning label will be marked on the card.

In this view, the user can see a total representation of the current node status, including a graphical view of all the slots, the card functions, the card types, the status of individual ports, the power status, and other NE functions. The user can modify node properties in the configuration windows. The configuration windows can be opened from the main menu bar by or the context menu of the chassis view.

Right-click the chassis view and select Refresh Chassis from the context menu or select Configuration > Refresh Chassis from the menu bar to refresh the chassis view.




100 (184)

Fig. 7.10 Refreshing chassis

ii Note The user must click on the Nokia Siemens Networks chassis to select the chassis (see the red circle in Fig. 7.10), otherwise the corresponding card/slot will be selected depending on the location the user clicks.

7.2.3 NE synchronization

In order to synchronize the LCT database with the NE’s database, the user must follow the steps listed below.




101 (184)

Right-click the chassis view and select Synchronize NE. The “NE Synchronization” window will be shown (see Fig. 7.11).

Fig. 7.11 Synchronizing NE

Select the content to synchronize, and click OK to start the synchronization process. If the synchronization process succeeds, a message box will be shown.

Click Close to quit the current window.

Click to launch the Online Help.

7.2.4 NE properties configuration

To open the “NE Properties Configuration” window, two methods can be used:

• Right-click the chassis and select NE Property Configuration.

• From the chassis main menu, select Configuration > NE > Property Configuration.

The “NE Properties Configuration” window will be shown (see Fig. 7.12).




102 (184)

Fig. 7.12 NE Properties Configuration window

Each item in the window is described in the following table (see Tab. 7.2).




103 (184)

Item Description

NE type The type of NE card

NE label This is used to distinguish different nodes.

Version The hardware version of this node

Location The physical position of this node in real-life

IP address The IP address of this node

Description Input node’s detailed description.

Gateway The gateway of this node

Contact The contact or owner of this node

Serial number The serial number of this node configured by the manufacturer

Date and Time The current time on this node

Tab. 7.2 NE properties description

The card list gives the brief information of all the cards on this node. The user can access the card configuration window by double-clicking the corresponding line in the table.

ii Note The user can change properties of an NE, but modifications are only completed after the Apply button been clicked.

Click OK to confirm all the modifications and close the window.

If some of the properties are changed, click the Refresh button to check the latest status of this node.

Click Print to print the information of this node.

Click Cancel to quit this window. All unsaved modifications will be lost.





104 (184)

7.2.5 Shutting down NE

To shut down the NE, select Configuration > NE > Shut Down from the chassis main menu.

A shutdown confirmation window will appear. Click Yes to confirm shutting down of this NE.

ii Note An NE that has been shut down will be offline.

7.2.6 FTP settings

The FTP settings can get the latest software and data support from the FTP server. To perform NE software management and MIB management, the user needs to first configure the FTP setting as well as the FTP server.

Follow the steps below to apply FTP settings:

1. From the chassis main menu, select Configuration > FTP Configuration. The “NE FTP Configuration” window will be shown with the current FTP setting (see Fig. 7.13).

Fig. 7.13 NE FTP Configuration window

2. To modify the current configuration in the FTP server setting section:

− Input the FTP server’s IP address in the FTP server IP address text box.

− Input the FTP username in the Username text box.




105 (184)

− Input the FTP user password in the Password text box.

ii Note Both of username and password are pm by default if the Nokia Siemens Networks FTP server is used which is included in the software package.

All the latest software and data of the FTP server are stored in the <%Install_Drive%\ftproot\pm> folder (<%Install_Drive%> specifies the drive letter of the hard disk drive containing the LCT program). For example, if the LCT program is installed in Drive C, the FTP root will be in the <C:\ftproot\pm> folder (see Fig. 7.14).

Fig. 7.14 FTP root directory

The data of the user pm will be stored in the corresponding folders under the <%Install_Drive%\ftproot\pm> folder. For example, the MIB files uploaded from the LCT program will be stored in the <%Install_Drive%\ftproot\pm\MibUpload> folder.

Click Refresh to update the current configuration.

Click Apply to confirm the modification.

Click Close to quit the window. All unsaved modifications will be lost.





106 (184)

ii Note The configuration of the FTP server should be the same as the real FTP server setting. Generally, the LCT server and the FTP server are on the same physical machine. Note that the LCT server and FTP server can also be on different machines.

7.2.7 NE software management

Two software images can be stored in the SURPASS hiT 7035 LCT, an active image and a backup image. Using the LCT, the user can download a SURPASS hiT 7035 NE software image to the NE as the backup version from the FTP server or the user may switch software images between active and backup versions.

NE software management is done by the steps below:

1. From the chassis main menu, select Configuration > NE > Software Management. The “NE Software Management” window will be shown (see Fig. 7.15).

Fig. 7.15 NE Software Management window

Each item in the window is described as follows (see Tab. 7.3):




107 (184)

Item Description

Active software version The software version currently running

State of last command The last command status

Current software information

Location: where the load stored

Role: as a backup or active software in the system

Name: load version

Date time: the time when the load was downloaded

Tab. 7.3 Software management window field description

2. In the “NE Software Management” window, input the software file name on the FTP server in the Software file name field, and click Download Software from FTP Server to download the software image as the backup software version from the FTP server.

3. Click Switch to switch the software images between the active version and the backup version. After the switching process is finished, a result window will appear to prompt the user to cold reboot or warm reboot the NE.

ii Note

• System cold reboot (system initialization) takes up to 3 minutes to complete. It is suggested that no other operations (such as system power on or power off, card insertion or removal) be performed during the system initialization.

• System cold reboot will cause traffic hit. The traffic hit time is typically 30 seconds, but can last up to 3 minutes.

• System warm reboot process takes up to 2 minutes. It is suggested that no operations (such as system power on or power off, card insertion or removal) be performed during system reboot.

• Card reset will impact the traffic passing through this card. The traffic hit time is typically 30 seconds, but can last up to 60 seconds.

Click Close to quit this dialog. All unsaved modifications will be lost.

Click Refresh to refresh the information.





108 (184)

ii Note The user must make sure that the FTP server setting and the software image path are correctly configured before the operation is launched. The user can modify the FTP setting by clicking the FTP Setting tab.

7.2.8 MIB management

The SURPASS hiT 7035 MIB consists of the internal databases/files in the NE that store all the NE configurations and runtime status information. There are two versions of MIB files stored in the NE: an active version and a backup version. All the MIB management functions can be performed in LCT environment.

Follow the steps below to perform MIB management:

1. From the chassis main menu, select Configuration > NE > MIB Management. The “MIB Management” window will be shown (see Fig. 7.16).

Fig. 7.16 MIB Management window

2. To upload the MIB files to the FTP server, click the Upload tab and click the Browse button. A browse window will be shown (see Fig. 7.17).




109 (184)

Fig. 7.17 Selecting an MIB file for update

3. Input the file name and click the OK button to confirm the file name or click Cancel to quit. Then the management is ready for upload (see Fig. 7.18).




110 (184)

Fig. 7.18 Ready for MIB upload

Click Upload From NE to upload the MIB file to FTP server.



Uploading process takes about 30 seconds. A message of “Upload process is finished!” will appear in the status bar. (See Fig. 7.19)




111 (184)

Fig. 7.19 MIB upload completion

ii Note The Clear NE MIB button is only available after the uploading process has been finished to protect the user from clearing NE MIB accidentally.

To download an MIB file from FTP server, follow the steps below:

1. Click the Download tab and click the Browse button. A browse window will be shown (see Fig. 7.17).

2. Select the file name and click Open to start downloading the MIB file. Click Cancel to quit. The management window with “ready for download” message will be shown after the Open button has been clicked (see Fig. 7.20).




112 (184)

Fig. 7.20 Ready for download

Click Download to NE to download the MIB from FTP server.



Downloading process takes about 30 seconds. A message of “Download process is finished!” will appear in the status bar. (See Fig. 7.21)




113 (184)

Fig. 7.21 MIB download process

After the download is finished, the user can switch the active MIB file and backup MIB file by clicking the Switch NE MIB button.

ii Note The Switch NE MIB button is only available after the NE download process is finished.

ii Note When MIB switch is executed, the network management system reminds user to warm reboot or cold reboot the system. The user should reboot the system immediately. Before system reboot (after the MIB is switched), any NE operation will not be saved into MIB. Therefore, any operation before system reboot is invalid.

7.2.9 NE timing setting

Open the corresponding chassis view.

From the main menu, select Configuration > NE > Time Setting.

An “NE Time Setting” window will be shown (see Fig. 7.22).




114 (184)

Fig. 7.22 NE Time Settings window

In the drop-down list of Network time protocol, the protocol can be set to either Enabled or Disabled.

If the Network time protocol is enabled, input the NTP time server IP address in the corresponding text box.

In the drop-down list of NTP request periods, set the frequency to send the timing request to the NTP time server.

Under Managed NE list (active), select the corresponding NE whose time will be modified.

In the drop-down list of Network element time, the current time can be viewed manually.

Click Refresh to check the latest information on setting time.

Click Apply to confirm the modifications.

Click OK to quite the window, all the modifications will be saved.

Click Cancel to quit the window, all the unsaved modifications will be lost.




115 (184)


7.2.10 NE trap destination configuration

Select Configuration > NE > Trap Destination Configuration from the chassis main menu. A “Trap Destination Configuration” window will be shown (see Fig. 7.23).

Fig. 7.23 Trap Destination window

The function of each button is described as follows:

Click Refresh to update the current destination.

Click Add to add a new trap destination IP address into the list.

Click Delete to remove a trap destination from the list.

Click Close to quit the window without saving any modifications.





116 (184)

7.2.11 Card configuration and management

There are two methods to open the “Card Properties Configuration” window in the chassis view:

• Right-click the card to be configured, and select Card Property Configuration (see Fig. 7.24); or

Fig. 7.24 Selecting the card

• In the “NE Properties Configuration” window, double-click the line of card that the user wants to configure in the card list.

A “Card Properties” window will appear. (See Fig. 7.25)




117 (184)

Fig. 7.25 Card Properties window

In this window, the following card information is listed in Tab. 7.4:

Items Descriptions

Slot number The location of the card in the system

Card function The functionality of the card

Card type This identifies the type of card

Card state The operation status of the card in the system

Serial number The serial number provided by the manufacturer

Card label A label can be set to distinguish different card

Hardware version The current version of the card

Care description The statement about the card

Tab. 7.4 Card properties items description




118 (184)

The port list contains all the present ports information on the card. The user can double-click the entry of port list that the user wants to configure or view the statistics.

7.2.12 SDH port configuration and management

There are two ways to open the “SDH Port Configuration” window:

• In the chassis view, select the corresponding SDH port. Right-click and select SDH Port Property Configuration. The port selected will be framed in blue (see Fig. 7.26); or

Fig. 7.26 Port selection

• Open the corresponding “Card Properties Configuration” window, which has the port user wants to view or configure, and double-clicking the entry to the port list.

The “SDH Port Properties” window will be shown (see Fig. 7.27).




119 (184)

Fig. 7.27 SDH Port Properties window

In this window, each property item is described in Tab. 7.5 and each item of port status is described in Tab. 7.6.




120 (184)

Fields Descriptions

Port Port number

Port type This identifies the type of port.

Port label A user can change this easily to distinguish different ports.

Port mode

There are three modes:

• Auto mode: The system decides the optimum mode for this port.

• Monitor mode: When an alarm is generated from this port, it will be reported to the alarm management automatically.

• Non-monitor mode: No matter how many alarms are generated from this card, none of them will be reported.

Port admin mode

There are two port admin modes:

• Enable (connected), or

• Disable (unconnected).

Auto laser shutdown (ALS)

Yes/No means enable or disable the functionality that the laser transmitter will shutdown automatically when the laser receiver detects loss of signal.

Port ALS mode

• No command: means that no actions.

• Manual restart mode: means that restart laser once manually.

• Manual test mode: means that test the port laser having different time gap with manual restart.

Tab. 7.5 Port configuration table




121 (184)

Fields Descriptions

Operating status The port status whether it is under operation or not

Laser bias current Value of the laser bias current

Received laser power

Optical power received through this port (If the power is small, for example smaller than -40 dBm, the sensor will not show its real number but show "-40 dBm".)

Transmitted laser power

Optical power transmitted out through this port (If the power is small, for example smaller than -40 dBm, the sensor will not show its real number but show "-40 dBm".)

Laser temperature Temperature of the laser

Tab. 7.6 Port status

If any properties of the port are changed, click Apply to confirm them. Only after clicking this button, have the modifications been completed.

If the user is changing all the properties at the same time, click Refresh to check the latest status of the port.

Click Print to print the information of this port.

Click Cancel to quit this window. All the unsaved modifications will be lost.

Click OK to close the window.


7.2.13 Shutting down SUPRASS hiT 7035 LCT

There are two ways to shut down the SURPASS hiT 7035 LCT:

• Click at the top right of the SURPASS hiT 7035 LCT main window; or

• Click System > Exit from the main window menu.

A confirmation window will appear, click YES to confirm the shutdown request.

Initial measurements and tests



122 (184)

8 Initial measurements and tests During commissioning of the SURPASS hiT 7035, measurements and function tests are required in order to ensure that no damage has occurred during the transport and assembly, and that the equipment has been correctly installed.

!! WARNING When handling any hardware, the user must observe the protective measures given in Chapter 2.

For more information on electrical and optical parameters of the individual card and of the complete system, please refer to the SURPASS hiT 7035 Product Description.

8.1 Measurements and tests

This section describes the test target, test setup, connection description, test procedure, and test result of each test case, which is used for field test. The users can select the relevant test cases according to their needs and the availability of the hardware they have ordered.

8.2 Local tests

Local tests include the following tests:

• Battery voltage test

• Management port test

• Auxiliary port test




123 (184)

• SDH ports tests

• PDH ports tests

• Ethernet port test

• GE port auto-negotiation test

• OA port test

• Power protection test

8.2.1 Battery voltage test

Test target:

To avoid damages caused by the DC voltage beyond the specification range.

Test setup:

Connect a multimeter to the power distribution panel which is located on the top of the rack.

Test procedure:

Check the multimeter’s reads of the DC voltage for both power supply feeders.

Tesr result:

The DC voltage should be -48 V or within the -40 V ~ -72 V range.

8.2.2 Management port test

Test target:

To test if the management port is working properly.

Test setup:




124 (184)

Fig. 8.1 Management port test setup

Connection description:

Connect the NE’s management port to the compatible 10 M or 100 M Ethernet interface of a PC, using an Ethernet cable.

Test procedure:

Run the SURPASS hiT 7035 LCT program, and set up a connection to the NE.

Test result:

NE is connected to LCT successfully.

8.2.3 AUX port test

Test target:

To test if the auxiliary port is working properly.

ii Note The AUX port has a fixed IP address of 192.168.0.2.

Test setup:

Fig. 8.2 AUX port test setup

Connection description




125 (184)

Connect the NE’s AUX port to the compatible 10 M or 100 M Ethernet interface of a PC using an Ethernet cross-over cable.

Test procedure:

1. Configure the PC IP address as 192.168.0.xxx.

2. Open the Windows command window, add a route using the command: route add <Node IP> 192.168.0.2

3. Run the SURPASS hiT 7035 LCT program and set up a connection to the NE.

Test result:

NE is connected to LCT successfully.

8.2.4 STM-16 optical interface

STM-16 transmission optical power, laser receiving sensitivity and overload, and receiving optical power are measured.

STM-16 TX optical power Test target:

To measure the transmission optical power of the STM-16 laser.

Test setup: (see Fig. 8.3)

Fig. 8.3 STM-16 TX optical power test setup


Connect the NE’s STM-16 TX port to an optical power meter.




126 (184)

Test procedure:

1. Connect as shown in Fig. 8.3.

2. Set the corresponding wavelength λ on the optical meter.

3. Record the result.

Test result: (see Tab. 8.1)

Application code

Wavelength (nm) Source type Output power

(dBm)

S-16.1 1261 - 1360 SLM -5 ~ 0

L-16.1 1261 - 1360 SLM -2 ~ +3

L-16.2 1480 - 1580 SLM -2 ~ +3

V-16.2 1530 - 1560 Un-cooled SLM -2 ~ +3

U-16.2 1530 - 1560 Un-cooled SLM -2 ~ +3

Tab. 8.1 Standard optical transmission power for STM-16

STM-16 RX sensitivity and overload of STM-16 laser Test target:

To measure the receiving sensitivity and overload of the STM-16 laser.


Fig. 8.4 STM-16 RX sensitivity and overload test setup


1. Turn the optical attenuator up to 15 dBm.

2. Connect an STM-16 port of the NE to the optical attenuator.




127 (184)

3. Connect the tester to any other port of the system, such as an STM-1 port.

Test procedure:

1. Create a bi-directional circuit between the STM-16 port and the STM-1 port.

2. Configure the signal pattern as 223-1 PRBS on the tester.

3. Make sure that there is no alarm or bit error on this circuit.

4. Turn up the optical attenuator until there is bit error.

5. Turn the optical attenuator down 1 dBm and observe for 5 minutes.

6. Measure the receiving optical power on the STM-16 RX port and record it as the sensitivity.

7. Turn down the optical attenuator until there is bit error.

8. Turn the optical attenuator up 1 dBm and observe for 5 minutes.

9. Measure the receiving optical power on the STM-16 RX port and record it as the overload.





128 (184)

Application code Wavelength (nm)

Minimum sensitivity and overload (dBm)

S-16.1 1261 - 1360 -18 ~ 0

L-16.1 1261 - 1360 -27 ~ -9

L-16.2 1480 - 1580 -28 ~ -9

V-16.2 1530 - 1560 -28 ~ -9

U-16.2 1530 - 1560 -28 ~ -9

Tab. 8.2 Standard optical receiving sensitivity and overload for STM-16

STM-16 RX optical power Test target:

To measure the STM-16 receiving optical power.


NE

ODF

Optical Power Meter

TxSTM-16 STM-16

Fig. 8.5 STM-16 receiving optical power test setup


1. Find which fiber is connected from the ODF to the STM-16 RX port.

2. Re-connect the fiber to the optical meter.

Test procedure:

1. Configure the corresponding wavelength λ on the optical meter.





129 (184)




S-16.1 1261 - 1360 -18 ~ 0

L-16.1 1261 - 1360 -27 ~ -9

L-16.2 1480 - 1580 -28 ~ -9

V-16.2 1530 - 1560 -28 ~ -9

U-16.2 1530 - 1560 -28 ~ -9

Tab. 8.3 Standard optical receiving power range for STM-16


STM-4 transmitting optical power, laser receiving sensitivity and overload, and receiving optical power are measured.




Fig. 8.6 STM-4 TX optical power test setup


Connect the STM-4 TX port of the NE to an optical power meter.




130 (184)

Test procedure:





Application code Wavelength (nm) Source type Output power (dBm)

S-4.1 1261 - 1360 MLM -15 ~ -8

L-4.1 1261 - 1360 MLM -3 ~ +2

L-4.2 1480 - 1580 SLM -3 ~ +2

V-4.2 1480 - 1580 SLM +1 ~ +5








2. Connect the STM-4 port to the optical attenuator.

3. Connect the tester to any other port of the system, such as an STM-1 port.




131 (184)

Test procedure:

1. Create a bi-directional circuit between the STM-4 port and the STM-1 port.



4. Turn up the optical attenuator untill there is bit error.


6. Measure the receiving optical power on the STM-4 RX port and record it as the sensitivity.



9. Measure the receiving optical power on the STM-4 RX port and record it as the overload.




S-4.1 1261 - 1360 -28 ~ -8

L-4.1 1261 - 1360 -28 ~ -8

L-4.2 1480 - 1580 -28 ~ -8

V-4.2 1480 - 1580 -34 ~ -18 (BER ≤ 10E-12)








132 (184)

NE

ODF

Optical Power Meter

TxSTM-4 STM-4

Fig. 8.8 STM-4 receiving optical power test setup




Test procedure:




Application code Wavelength (nm) Minimum sensitivity and overload (dBm)

S-4.1 1261 - 1360 -28 ~ -8

L-4.1 1261 - 1360 -28 ~ -8

L-4.2 1480 - 1580 -28 ~ -8

V-4.2 1480 - 1580 -34 ~ -18 (BER ≤ 10E-12)



STM-1 transmission optical power, laser receiving sensitivity and overload, and receiving optical power are measured.




133 (184)




Fig. 8.9 STM-1 TX optical power setup


Connect the STM-1 TX of the NE to the optical power meter.

Test procedure:





Application code Wavelength (nm) Source type Output power (dBm)

S-1.1 1261 - 1360 MLM -15 ~ -8

L-1.1 1261 - 1360 MLM -5 ~ 0

L-1.2 1480 - 1580 SLM -5 ~ 0

V-1.2 1480 - 1580 SLM +1 ~ +5






134 (184)






2. Connect the STM-1 port to the optical attenuator.

3. Connect the tester to any other port of the system, such as another STM-1 port.

Test procedure:

1. Create a bi-directional circuit between the two STM-1 ports.



4. Turn up the optical attenuator until there is bit error.


6. Measure the receiving optical power on the tested STM-1 RX port and record it as the sensitivity.



9. Measure the receiving optical power on the tested STM-1 RX port and record it as the overload.





135 (184)



S-1.1 1261 - 1360 -8 ~ -28

L-1.1 1261 - 1360 -34 ~ -10

L-1.2 1480 - 1580 -34 ~ -10

V-1.2 1480 - 1580 -34 ~ -10 (BER ≤ 10E-12)





NE

ODF

Optical Power Meter

TxSTM-1 STM-1

Fig. 8.11 STM-1 RX optical power setup




Test procedure:






136 (184)


Application code Wavelength (nm) Minimum sensitivity and overload (dBm)

S-1.1 1261 - 1360 -8 ~ -28

L-1.1 1270 - 1360 -10 ~ -34

L-1.2 1480 - 1580 -10 ~ -34

V-1.2 1480 - 1580 -10 ~ -34 (BER ≤ 10E-12)


8.2.7 STM-1E port BER test

Test target:

To verify the STM-1E channel.

Test setup:

Fig. 8.12 STM-1E loop-back test setup


1. Set loop-back on an STM-1 port.

2. Connect the tester TX to the RX port of the STM-1E and connect the tester RX to the TX port of STM-1E.

Test procedure:

1. Create a bi-directional circuit between the STM-1 port and the STM-1E port.




137 (184)



4. Run the tester for 15 minutes.

Test result:

No alarm is detected on the tester.

8.2.8 PDH port test

E1 and E3/DS3 ports’ Bit Error Rate (BER) are tested.

E1 port BER test Test target:

To verify all the E1 channels.

Test setup:

Fig. 8.13 E1 port BER test setup


1. Loop-back an STM-4 port.

2. Daisy chain all the E1 ports.

3. Connect the tester TX to the RX port of the first E1.

4. Connect the tester RX to the TX port of the last E1.

Test procedure:




138 (184)

1. Create bi-directional circuits between the all the E1 ports and the STM-4 port.




Test result:


ii Note After the daisy chain setup completed, it is suggested to wait for at least 60 seconds for the PLLs to become stable, and then start the analyzer.

E3/DS3 port BER test Test target:

To verify all the E3/DS3 channels.

Test setup:

Fig. 8.14 E3/DS3 port BER test setup



2. Daisy chain all the E3/DS3 ports.

3. Connect the tester TX to the RX port of the first E3/DS3.

4. Connect the tester RX to the TX port of the last E3/DS3.

Test procedure:




139 (184)

1. Create bi-directional circuits between STM-4 port and all the E3/DS3 ports.




Test result:


8.2.9 Ethernet port

10/100 M and GE port mode are tested as well as auto-negotiation tests on 10/100 M and GE ports.

10/100 M port auto-negotiation test Test target:

To verify the auto-negotiation function of the 10/100 M port.

Test setup:

The 10/100 M port test setup is as shown in Fig. 8.15:

Fig. 8.15 10/100 M port auto-negotiation test setup


Connect one 10/100 M port to two 10/100 M ports of the Smartbits analyzer through an Ethernet splitter.

Test procedure:





140 (184)

2. Enable the auto-negotiation function on the NE’s 10/100 M port.

3. Enable the auto-negotiation function of the 10/100 M ports on the Smartbit analyzer.

4. See result.

Test result:

The port mode on both sides should be 100 M and full-duplex.

10/100 M port mode test Test target:

To verify the working mode of the 10/100 M port.

Test setup:

The 10/100 M port test setup is as shown in Fig. 8.16:

Fig. 8.16 10/100 M port working mode test setup


Connect one 10/100 M port to two 10/100 M ports of the Smartbit analyzer through an Ethernet splitter.

Test Procedure:


2. Set the Smartbits analyzer ports as 100 M and full-duplex.

3. Set 100 M and full-duplex on the NE’s 10/100 M port.

4. Send traffic out from the Smartbits analyzer’s port 1, and then check the receiving traffic of Smartbits analyzer on port 2.

5. See result 1.

6. Set the Smartbits analyzer ports as 100 M and half-duplex.




141 (184)

7. Set 100 M and half-duplex on the NE’s 10/100 M port.

8. Send traffic out from Smartbits analyzer’s port 1, and then check the receiving traffic of the Smartbits analyzer port 2.

9. See result 2.

10. Set the Smartbits analyzer ports as 10 M and full-duplex.

11. Set 10 M and full-duplex on the NE’s 10/100 M port.

12. Send traffic out of the Smartbits analyzer’s port 1, and then check the receiving traffic of the Smartbits analyzer on port 2.

13. See result 3.

14. Set the Smartbits analyzer port as 10 M and half-duplex.

15. Set 10 M and half-duplex on the NE’s 10/100 M port.

16. Send traffic out from the Smartbits analyzer’s port 1, and then check the receiving traffic of the Smartbits analyzer on port 2.

17. See result 4.

Test result:

1. The traffic should be OK.




8.2.10 GE port auto-negotiation test

Test target:

To verify the auto-negotiation function of the GE port.

Test setup:

NESmartbits Analyzer

GE

Fig. 8.17 GE port auto-negotiation test setup




142 (184)


Connect the NE’s GE port to the Smartbits analyzer’s GE port.

Test procedure:

1. Enable the auto-negotiation function on the NE’s GE port.

2. Enable the auto-negotiation function on the Smartbits analyzer’s GE port and enable the flow control function.

Test result:

The port mode on both sides should be 1 Gb, full-duplex, and flow control enabled.

8.2.11 OA port test

Test target:

To verify the OA channel.

Test setup:

Fig. 8.18 OA channel test setup

Connection and test procedure:

1. Enable the admin mode of the OA card using the SURPASS hiT 7035 LCT.

For more information on card properties configuration, please refer to Chapter 7.2.11.

2. Keep the OA card default manufacturer setting.

3. Measure the input optical power of the OA card.




143 (184)

4. Connect an optical patch cord to input of the OA card.

5. Measure the output optical power of the OA card.

6. Record the optical receiving power values in the table below.

Expected result:

The output optical power of the OA card should meet the default value as the table shown below (see Tab. 8.10).

Card type Parameters Minimum

(dBm)

Maximum

(dBm)

Default

(dBm)

Range of input power -10 3 N/A 13 dBm BOA

Output power 5 13 13 ± 0.5





Range of input power -35 -15 N/A 20 dB POA

Output power -15 -10 N/A

Tab. 8.10 Expected result of OA port test

8.2.12 Power 1 + 1 protection test

Test target:

To verify the 1 + 1 equipment protection for the power card works correctly.

Test setup:




144 (184)

Fig. 8.19 Power card 1 + 1 protection test setup


1. Connect an E1 port to the tester.


Test procedure:


2. Create a bi-directional circuit between the STM-4 port and the E1 port.



5. Cut off the power input 1.

6. Check the tester.

7. See result.

Test result:

Traffic is OK and error-free.

8.3 Network tests

ii Note The Network tests are optional to the users.

8.3.1 Bit error test on E1 (12 hours)

Test target:




145 (184)

To test the bit error of the E1 channel between two terminals (NEs).

Test setup:

Fig. 8.20 E1 bit error test setup


1. Connect an SDH/PDH analyzer to the local NE’s E1 port.

2. Loop back an E1 port on the remote NE station.

Test procedure:

1. Create a bi-directional VC-12 level connection from the local NE’s E1 port to the remote NE’s E1 port. A chain or ring configuration is possible.

2. Do a bit error measurement with the SDH/PDH analyzer and perform a bit error measurement with an injected payload of 2 Mbps for 12 hours using a PRBS 215-1 signal pattern.

Test result:

The traffic should be error-free.

8.3.2 Bit error test on E3 (12 hours)

Test target:

To test the bit error of the E3 channel between two terminals (NEs).

Test setup:




146 (184)

Fig. 8.21 E3 bit error test setup


1. Connect an SDH/PDH analyzer to the local NE’s E3 port.

2. Loop back an E3 port on the remote NE station.

Test procedure:

1. Create a bi-directional VC-3 level connection from the local NE’s E3 port to the remote NE’s E3 port. A chain or ring configuration is possible.


Test result:


8.3.3 Bit error test on DS3 (12 hours)

Test target:

To test the bit error of the DS3 channel between two terminals (NEs).

Test setup:




147 (184)

Fig. 8.22 DS3 bit error test setup


1. Connect an SDH/PDH analyzer to the local NE’s DS3 port.

2. Loop back a DS3 port on the remote NE station.

Test procedure:

1. Create a bi-directional VC-3 level connection from the local NE’s DS3 port to the remote NE’s DS3 port. A chain or ring configuration is possible.


Test result:


8.3.4 Bit error test on STM-1 (12 hours)

Test target:

To test the bit error of the STM-1 channel between two terminals (NEs).

Test setup:




148 (184)

Fig. 8.23 STM-1 bit error test setup


1. Connect an SDH analyzer to a local NE’s STM-1 port.

2. Loop back an STM-1 port on the remote station.

Test procedure:

1. Create a bi-directional VC-4 level connection from the local NE’s STM-1 port to the remotes NE’s STM-1 port. A chain or ring configuration is possible.


Test result:


8.3.5 Bit error test on STM-1E (12 hours)

Test target:

To test the bit error of the STM-1E channel between two terminals (NEs).

Test setup:




149 (184)

Fig. 8.24 STM-1E bit error test setup


1. Connect an SDH analyzer to the local NE’s STM-1E port.

2. Loop back an STM-1E port on the remote station.

Test procedure:

1. Create a bi-directional VC-4 level connection from the local NE’s STM-1E port to the remote NE’s STM-1E port. A chain or ring configuration is possible.


Test result:



Test target:


Test setup:




150 (184)



1. Connect an SDH analyzer to the local NE’s STM-4 port.

2. Loop back an STM-4 port on the remote station. Test procedure:

1. Create a bi-directional VC-4 level connection from the local NE’s STM-4 port to the remote NE’s STM-4 port. A chain or ring configuration is possible.


Test result:



Test target:


Test setup:




151 (184)



1. Connect an SDH analyzer to the local NE’s STM-16 port.

2. Loop back an STM-16 port on the remote station. If necessary, add a 10 dB attenuation in the loop back circuit.

Test procedure:

1. Create a bi-directional VC-4 level connection from the local NE’s STM-16 port to the remote NE’s STM-16 port. A chain or ring configuration is possible.


Test result:


8.3.8 Packet loss test on 8 x FE/T Ethernet card (12 hours)

Test target:

To measure the packet loss of the FE/T Ethernet channel between two terminals (NEs).

Test setup:




152 (184)

Fig. 8.27 8 x FE/T Ethernet card packet loss test setup


1. Connect an SDH Analyzer to the 8 x FE/T Ethernet card’s FE port of the local NE station.

2. Connect another SDH Analyzer to the 8 x FE/T Ethernet card’s FE port of the remote NE station.

Test procedure:

1. Create a bi-directional VC-12-5v connection from the local NE’s FE/T port to the remote FE/T port.

2. Confirm the traffic can transfer along FE (local) > STM-N port (local) > STM-N port (remote) > FE (remote), and the reverse direction as well.

3. Do a packet loss measurement between the two SDH analyzers and perform a packet loss measurement with 10 Mbps signal of packet length 64 Byte for 12 hours.

Test result:

There should be no packet loss.

8.3.9 Packet loss test on 8 x FE/L2 Ethernet card (12 hours)

Test target:

To measure the packet loss of the FE/L2 Ethernet channel between two terminals (NEs).

Test setup:




153 (184)

Fig. 8.28 8 x FE/L2 Ethernet card packet loss test setup


1. Connect an SDH analyzer to the 8 x FE/L2 Ethernet card’s FE port of the local NE station.

2. Connect another SDH analyzer to the 8 x FE/L2 Ethernet card’s FE port of the remote NE station.

Test procedure:

1. Configure both 8 x FE/L2 cards as double tag mode.

2. Configure LAN1 ports of both cards as detag mode.

3. Configure WAN1 ports of both cards as detag mode.

4. Configure both LAN1 and WAN1 with the same PVID, e.g., 11, and both LAN1 and WAN1 are in the same VLAN list, e.g., 11.

5. Create a bi-directional VC-12-5v connection from the local NE’s FE/L2 port to the remote FE/L2 port.

6. Confirm the traffic can transfer along FE (local) > STM-N port (local) > STM-N port (remote) > FE (remote), and the reverse direction as well.


Test result:


8.3.10 Packet loss test on Gigabit Ethernet card (12 hours)

Test target:




154 (184)

To measure the packet loss of Gigabit Ethernet channel between two terminals (NEs).

Test setup:

Fig. 8.29 Gigabit Ethernet card packet loss test setup


1. Connect an SDH analyzer to the 1 x GE/T card’s GE port of the local NE station.

2. Connect another SDH analyzer to the 1 x GE/T card’s GE port of the remote NE station.

Test procedure:

1. Create a bi-directional VC-4-4v connection from the local NE’s GE port to the remote GE port.

2. Confirm the traffic can transfer along GE (local) > STM-N port (local) > STM-N port (remote) > GE (remote), and the reverse direction as well.


Test result:


8.4 Field check lists and test report

The results of the commissioning measurements are to be recorded. Nokia Siemens Networks provides the forms, i.e., the field check lists and test report to the user for such purpose.




155 (184)

8.4.1 Certificate of customer acceptance

Project name:

Country:

Customer:

Station:

Product version:

Number of pages:

Remarks:

Customer acceptance engineer:

NOKIA SIEMENS Networks engineer:

Date:

Sign for the customer:

Sign for NOKIA SIEMENS Networks:




156 (184)

8.4.2 Circuit pack list of SURPASS hiT 7035

Slot name CP type CP code S/N number

SCE

PWR1

PWR2

CC1_LC

CC2_LC

LC1

LC2

LC3

LC4

LC5

LC6

LC7

LC8

LC9

LC10

LC11

IO1

IO2

IO3

IO4

IO5

IO6

IO7

SI




157 (184)

8.4.3 Load number of SURPASS hiT 7035 and TNMS-CT

SURPASS hiT 7035 NE load

TNMS-CT load

8.4.4 Tools and test equipment list

Equipment Type Recommendation Actual type

Bit error test set SDH/PDH analyzer Agilent Omni718 with STM-16/4/1 interface

IEEE 802.3 data analyzer

SmartBits 600 with FE module and GE module

Ethernet test set

Optical power meter Range –40 ~ +10 dBm

Cleaning material Optical test set

Fiber cables According to the delivered cards

Multimeter • Range 0 ~ 1000 V

• Accuracy ± 5%

ESD wristband

8.4.5 Test result

Test result Memo

Test item

Application Pass Fail

Battery voltage test 　　

Management port test

AUX port test

STM-16 optical interface [ ] N.A



STM-1E port BER test [ ] N.A

PDH port test [ ] N.A




158 (184)

Test result Memo

Test item

Application Pass Fail

Ethernet port [ ] N.A

GE port auto-negotiation test [ ] N.A

OA port test [ ] N.A

Power 1 + 1 protection test [ ] N.A

Bit error test on E1 (12 hours) [ ] N.A

Bit error test on E3 (12 hours) [ ] N.A

Bit error test on DS3 (12 hours) [ ] N.A

Bit error test on STM-1 (12 hours)

[ ] N.A

Bit error test on STM-1E (12 hours)

[ ] N.A


[ ] N.A


[ ] N.A

Packet loss test on 8 x FE/T Ethernet card (12 hours)

[ ] N.A

Packet loss test on 8 x FE/L2 Ethernet card (12 hours)

[ ] N.A

Packet loss test on Gigabit Ethernet card (12 hours)

[ ] N.A

ii Note Please select one type of bit error test referred to the type of available line interface and tributary type.

LED indications



159 (184)

9 LED indications This chapter gives an overview of the module front LEDs, which provide information for service and maintenance purposes.

For information on the functions of the LEDs, please refer to the SURPASS hiT 7035 Product Description.

9.1 Enhanced System Controller card (SCE)

The SCE card has six (6) LEDs (see Tab. 9.1).

Name Color Status Functional description

ON This module is in the active mode. ACTIVE Green

OFF This module is in the standby mode.

ON Power is available to the system. PWR Green

OFF Power is off.

ON There is fault condition on this module. FAULT Red

OFF There is no alarm on this module.

ON One or more critical alarms are present.

Flashing One or more critical communication alarms are present, or any card is mismatched or faulty (Major alarm LED will flash at the same time). CR Red

OFF No critical communication alarms are present, and card/system is in service.

ON There are one or more major alarms present.

MJ Orange OFF No major alarms.

LED indications



160 (184)

Name Color Status Functional description

ON There are one or more minor alarms present.

MN Yellow OFF

No minor alarms.

(Note: warning and indeterminate alarms will not turn the LED on.)

Tab. 9.1 LEDs on SCE card

9.2 Cross-connect and timing card with STM-4/1 optical module (CC + 1 x STM-4/1) or with STM-16/4 optical module (CC + 1 x STM-16/4)

The cross-connect and timing card with STM-4/1 optical module or with the STM-16/4 Optical module has four (4) LEDs shown in Tab. 9.2.

LED name Color Status Description

ON Power is available to the card. It indicates the presence of the internal power supply after the power conversion. PWR Green

OFF Power is not available due to broken power converter or, external power cable or connector.

ON The card is in working state. ACT Green

OFF The card in standby state.

ON There are fault conditions present in this module. FAULT Red

OFF This module is in normal condition.

ON Optical link is normal. LINK Green

OFF Optical link is off.

Tab. 9.2 LEDs on CC + 1 × STM-4/1 or CC + 1 x STM-16/4 module

LED indications



161 (184)

9.3 Traffic interface cards

On traffic interface cards, there are Fault LED, Link LED, and Fast Ethernet connector LEDs.

9.3.1 PWR and Fault LEDs

Most of the traffic interface cards have at least two LEDs shown in Tab. 9.3.

Traffic Interface Cards

LED name

LED color

LED status Explanation

ON Power is available to the system. It indicates the presence of the internal power supply after the power conversion. PWR Green

OFF Power is not available due to the broken power converter, or external power cable or connector.

ON There is fault condition presented in this module.FAULT Red

OFF This module is in normal condition.

Tab. 9.3 LEDs on the traffic interface cards

9.3.2 Link LEDs

Some optical traffic interface cards has the Link LED (see Tab. 9.4).

Traffic interface modules

LED name

LED color

LED status

Explanation

ON There is an optical signal detected in the port. Link Green

OFF There is no optical signal detected in the port.

Tab. 9.4 Link LEDs on the traffic interface cards

LED indications



162 (184)

9.3.3 Fast Ethernet connector LEDs

LEDs on the FE ports’ RJ 45 connectors of 8 × FE/T card and 8 × FE/L2 card, are different from the LEDs on the connectors of general Fast Ethernet service cards. Each RJ 45 connector on the 8 × FE/T card and 8 × FE/L2 card has two LEDs to indicate the data link status for 2 Ethernet ports.

RJ 45 connectors for RJ 45 to 2 x RJ 45 converter cable

LED position

Peer to peer Ethernet port LED color LED status Explanation

ON The link of Ethernet port A is OK.Down A Green

OFF The link of Ethernet port A is down.

ON The link of Ethernet port B is OK.Up B Green

OFF The link of the Ethernet port B is down.

Tab. 9.5 LEDs on RJ 45 connector for RJ 45 to 2 x RJ 45 converter cable

9.4 Power card

The power card has two LEDs (see Tab. 9.6).

Power card

LED name LED color LED status Explanation

ON Power supply is on. PWR Green

OFF Power supply is off.

ON There is a fault on power module.

FAULT Red OFF There is no fault detected on

power module.

Tab. 9.6 LEDs on the power card

Pin assignments



163 (184)

10 Pin assignments This chapter describes the pin assignments of each cable used in the system.

10.1 DC power supply cable

Fig. 10.1 DC power supply cable

Pin assignments



164 (184)

Fig. 10.2 DC power connector

Pin number Wire color Signal

1 Yellow/Green Ground

2 Blue -48 V

3 Red 0 (Return)

Tab. 10.1 DC power connector pin assignments

10.2 E1 cable

The E1 cable uses 7 x E1 2-mm connector or 21 x E1 2-mm connector. Each 7 x E1 2-mm connector provides up to 7 × 2 Mbps signals.

Pin assignments



165 (184)

Fig. 10.3 63 x E1 IO card (75/120 Ohm) faceplate with 7 x E1 2-mm interface

Fig. 10.4 63 x E1 IO card (75/120 Ohm) faceplate with 21 x E1 2-mm interface

Pin assignments



166 (184)

Fig. 10.5 Single 7 x E1 2-mm connector


Pin assignments



167 (184)

Fig. 10.7 7 x E1 2-mm connector pin assignments

Connector

Pin No. Description Coaxial cable No. Description Label printing

E6 INNER CONDUCTOR (CORE) T7

E5 OUTER CONDUCTOR (BRAID)1 TX7

D6 INNER CONDUCTOR (CORE)

D5 OUTER CONDUCTOR (BRAID)2 TX6 T6

E4 INNER CONDUCTOR (CORE)

E3 OUTER CONDUCTOR (BRAID)3 TX5 T5



C4 INNER CONDUCTOR (CORE)

C3 OUTER CONDUCTOR (BRAID)5 TX3 T3

E2 INNER CONDUCTOR (CORE)

E1 OUTER CONDUCTOR (BRAID)6 TX2 T2



C6

C5 SHORT

CIRCUIT

B6 INNER CONDUCTOR (CORE)

B5 OUTER CONDUCTOR (BRAID)8 RX7 R7

A6 INNER CONDUCTOR (CORE)

A5 OUTER CONDUCTOR (BRAID)9 RX6 R6

Pin assignments



168 (184)

Connector

Pin No. Description Coaxial cable No. Description Label printing





C2 INNER CONDUCTOR (CORE)

C1 OUTER CONDUCTOR (BRAID)12 RX3 R3





Tab. 10.2 E1 (75 Ohm) cable connector pin assignments

Connector pin No. Cable color Description Label printing

E6 WHITE TX7P T7P

E5 BROWN TX7N T7N

D6 WHITE TX6P T6P

D5 ORANGE TX6N T6N

E4 WHITE TX5P T5P

E3 GREEN TX5N T5N

D4 WHITE TX4P T4P

D3 BLUE TX4N T4N

C4 RED TX3P T3P

C3 BLUE TX3N T3N

E2 RED TX2P T2P

E1 ORANGE TX2N T2N

D2 RED TX1P T1P

D1 GREEN TX1N T1N

C6

C5 SHORT CIRCUIT

B6 WHITE RX7P R7P

Pin assignments



169 (184)

Connector pin No. Cable color Description Label printing

B5 BROWN RX7N R7N

A6 WHITE RX6P R6P

A5 ORANGE RX6N R6N

B4 WHITE RX5P R5P

B3 GREEN RX5N R5N

A4 WHITE RX4P R4P

A3 BLUE RX4N R4N

C2 RED RX3P R3P

C1 BLUE RX3N R3N

B2 RED RX2P R2P

B1 ORANGE RX2N R2N

A2 RED RX1P R1P

A1 GREEN RX1N R1N

Tab. 10.3 E1 (120 Ohm) cable connector pin assignments

ii Note The user should use RJ 48 Connector based on 120 Ohm E1 extension panel.Tab. 10.4 lists the RJ 48 connector pin assignments.

Pin assignments



170 (184)

TXD+

RXD-

RXD+

Ground

1 8

TXD-

Fig. 10.8 E1 (120 Ohm) RJ 48 connector

Pin number Signal

1 Rx Tip (+)

2 Rx Ring (-)

3 Not Connected

4 Tx Tip (+)

5 Tx Ring (-)

6 Not Connected

7 Not Connected

8 Not Connected

Tab. 10.4 E1 RJ 48 connector pin assignments

Pin assignments



171 (184)

10.3 SIPAC connector panel

Fig. 10.9 SIPAC connector panel showing

Fig. 10.10 SIPAC connector panel pin numbering

Pin assignments



172 (184)

1 - 21 22 - 42 43 - 63

DS2-01 (in) ~ DS2-07 (in) DS2-22 (in) ~ DS2-28 (in) DS2-43 (in) ~ DS2-49 (in) A

B DS2-01(out) ~ DS2-07 (out) DS2-22(out) ~ DS2-28 (out) DS2-43(out) ~ DS2-49 (out)

DS2-8 (in) ~ DS2-14 (in) DS2-29 (in) ~ DS2-35 (in) DS2-50 (in) ~ DS2-56(in) C

D DS2-8 (out) ~ DS2-14 (out) DS2-29 (out) ~ DS2-35 (out) DS2-50 (out) ~ DS2-56 (out)

DS2-15 (in) ~ DS2-21 (in) DS2-36 (in) ~ DS2-42 (in) DS2-57 (in) ~ DS2-63 (in) E

F DS2-15 (out) ~ DS2-21 (out) DS2-36 (out) ~ DS2-42 (out) DS2-57 (out) ~ DS2-63 (out)

Tab. 10.5 SIPAC connector panel pin numbering

64 - 84 85 - 105 106 - 126

DS2-64 (in) ~ DS2-70 (in) DS2-85 (in) ~ DS2-91 (in) DS2-106 (in) ~ DS2-112 (in) A

B DS2-64 (out) ~ DS2-70 (out) DS2-85(out) ~ DS2-91 (out) DS2-106(out) ~ DS2-112 (out)

DS2-71 (in) ~ DS2-77 (in) DS2-92 (in) ~ DS2-98 (in) DS2-113 (in) ~ DS2-119(in) C

D DS2-71 (out) ~ DS2-77 (out) DS2-92 (out) ~ DS2-98 (out) DS2-113 (out) ~ DS2-119 (out)

DS2-78 (in) ~ DS2-84 (in) DS2-99 (in) ~ DS2-105 (in) DS2-120 (in) ~ DS2-126 (in) E

F DS2-78 (out) ~ DS2-84 (out) DS2-99 (out) ~ DS2-105 (out) DS2-120 (out) ~ DS2-126 (out)

Tab. 10.6 SIPAC connector panel pin numbering (continued)

Pin assignments



173 (184)

From SCSI 100 connectors To SIPAC connectors

SCSI no. Pin no. Connector name 1 – 7 101 AB 8 –14 101 CD

1

15 –21 101 EF 22 – 28 102 AB 29 – 35 102 CD

2

36 – 42 102 EF 43 – 49 103 AB 50 – 56 103 CD

3

57 – 63 103 EF 64 – 70 104 AB 71 – 77 104 CD

4

78 – 84 104 EF 85 – 91 105 AB 92 – 98 105 CD

5

99 – 105 105 EF 106 – 112 106 AB 113 – 119 106 CD

6

120 - 126 106 EF

Tab. 10.7 SIPAC connector panel pin assignments

Pin assignments



174 (184)

10.4 Ethernet cable

Pin number Signal

1 Twisted-pair, Tx+

2 Twisted-pair, Tx-

3 Twisted-pair, Rx+

4 Not connected

5 Not connected

6 Twisted-pair, Rx-

7 Not connected

8 Not connected

Tab. 10.8 Ethernet cable RJ 45 connector pin assignments

Fig. 10.11 Ethernet cable RJ 45 connector

CAT 6 is used for 100 Mbps Ethernet cable. Following is a reference chart for wiring Category 6 (CAT 6) for the 10/100 Base-T Ethernet cables.

Pin assignments



175 (184)

1 2 3 4 5 6 7 8

White with orange strip

Orange White with green strip

Blue White with blue strip

Green White with brown strip

Brown

Tab. 10.9 Category 6 twisted pair color-code standards

For FE ports on the 8 x FE/T card and 8 x FE/L2 card, cables with RJ 45 connectors are needed. However the pin usages are different from the CAT 6 cable usage. An Ethernet splitter converter is needed (see Fig. 10.12).

Up Side View

Left Front View

Right Back View

Fig. 10.12 Ethernet splitter converter

For more information on how to connect splitter, please refer to Chapter 4.3.10.

Pin assignments



176 (184)

10.5 Management cable

The management interface port is a DTE port with an RJ 45 connector. The management cable pin assignments are provided in Tab. 10.10 below:

Pin number Signal

1 Twisted-pair, Tx+

2 Twisted-pair, Tx-

3 Twisted-pair, Rx+

4 Not connected

5 Not connected

6 Twisted-pair, Rx-

7 Not connected

8 Not connected

Tab. 10.10 Management cable RJ 45 connector pin assignments

Fig. 10.13 RJ 45 plug

Pin assignments



177 (184)

10.6 Timing, STM-1E, and E3/DS3 cables

The timing cable, STM-1E cable, and E3/DS3 cable use CC 4-1.0 connectors on the SURPASS hiT 7035 side. The connectors on the other end of the cables can be customized to the customers’ applications.

Fig. 10.14 CC 4-1.0 connector

10.7 Station alarm cables

Station alarm cables use RJ 45 connectors. However the pin usages are different from the CAT 6 cable usage. The pin assignments for the station alarm cable are provided in Tab. 10.11.

RJ 45 connector of NE alarm port (Source)

RJ 45 connector A of alarm card (Destination)

Pin Signal Pin Signal

1 Alarm4 + 5 Alarm4 -

2 Alarm4 - 7 Alarm3 -

3 Alarm3 + 6 Alarm4 +

4 Alarm3 - 8 Alarm3 +

RJ 45 connector of NE alarm port (Source)

RJ 45 connector B of alarm card (Destination)

Pin Signal Pin Signal

5 Alarm2 + Critical and Major alarm

5 Alarm2 -

6 Alarm2 - Return 7 Alarm1 -

7 Alarm1 + Minor Alarm 6 Alarm2 +

8 Alarm1 - Return 8 Alarm1 +

Tab. 10.11 Station alarm cable RJ 45 connector pin assignments

Pin assignments



178 (184)

Fig. 10.15 Station alarm cable connection

10.8 MDI cables

MDI cables use RJ 45 connectors. The pin assignments for the MDI cable are provided in Tab. 10.12 below.

Pin number Signal

1 MDI4+

2 MDI4-

3 MDI3+

4 MDI3-

5 MDI2+

6 MDI2-

7 MDI1+

8 MDI1-

Tab. 10.12 MDI cable RJ 45 connector pin assignments

Pin assignments



179 (184)

10.9 MDO cables

MDO cables use RJ 45 connectors. The pin assignments for the MDO cable are provided in Tab. 10.13 below.

Pin number Signal

1 MDO4+

2 MDO4-

3 MDO3+

4 MDO3-

5 MDO2+

6 MDO2-

7 MDO1+

8 MDO1-

Tab. 10.13 MDO cable RJ 45 connector pin assignments

10.10 EOW cable

EOW cables use RJ 45 connectors. The pin assignments for the EOW cable are provided in Tab. 10.14 and below.

Pin Number Signal

1 EOW_O_CLKP

2 EOW_O_CLKN

3 EOW_O_DATP

4 EOW_O_DATN

5 EOW_I_CLKP

6 EOW_I_CLKN

7 EOW_I_DATP

8 EOW_I_DATN

Tab. 10.14 EOW interface RJ 45 connector pin assignments

Pin assignments



180 (184)

ii Note The interface of EOW based on the standard of G.703 electrical characteristics of 64 Kbps co-directional interface, the nominal peak voltage of a pulse is 1.0 V, peak voltage of no pulse is 0 V ± 0.10 V.

10.11 Console cable

The console cable is only used during SURPASS hiT 7035 installation to connect the Command Line Interface (CLI) to initialize the unit. This cable is not necessary in later maintenance.

Fig. 10.16 Console cable connection

Pin no. Signal

1 Not used

2 Serial signal Tx

3 Serial signal Rx

4 Not used

5 Ground

6 Not used

7 Not used

8 Not used

9 Not used

Tab. 10.15 Console cable pin assignement

Abbreviations



181 (184)

Abbreviations ACO Alarm Cut Off

CD-ROM Compact Disc Read Only Memory

CE Communauté Européenne

DB Data Base

DC Direct Current

DCC Data Communication Channel

EGB Elektrostatisch Gefährdete Bauteile

EMC Electromagnetic Compatibility

EN European Standard

EOW Engineering Order Wire

ESD Electrostatic Sensitive Device

ETS European Telecommunication Standard

ETSI European Telecommunications Standards Institute

FAULT Fault Alarm LED

FO Fiber Optic

GMT Greenwich Mean Time

GND Ground

GUI Graphical User Interface

GUIMN Graphical User Interface Manual

HS Handset

HW Hardware

IEC International Electrotechnical Commission

LCAS Link Capacity Adjustment Scheme

LCT Local Craft Terminal

LED Light Emitting Diode

LWL Lichtwellenleiter (optical fiber)

MSP Multiplex Section Protection

NCT Network Craft Terminal

OSN Optical Service Node

PDF Portable Document Format

PE Protective Earth (Ground)

Abbreviations



182 (184)

PPP Point to Point Protocol

RAM Random Access Memory

Rx Received signal

SCE Enhanced System Controller

SDI Serial Debug Interface

SEC SDH Equipment Clock

SELV Separate Extra-Low Voltage

SFP Small Form Factor Pluggable (Module)

SNCP Sub-Network Connection Protection

SW Software

T3 Clock input

T4 Clock output

TIF Telemetry Interface

TNMS Telecommunication Network Management System

Tx Transmitted signal

UMN User Manual

VCDB Variable Configuration Data Block

WEEE Waste Electrical and Electronic Equipment

Index .



183 (184)

Index .

Ａ Accumulator handling, 23 Air filter, 16

Ｂ Battery handling, 23 bending radius of optical fibers, 19

Ｃ CE conformity declaration, 26 Checking the device for intactness, 27 Cleaning fluids for optical connectors, 20 Complete cable layout, 73 Connecting cables, 50

Ｄ Delivery check, 27 Device checking for intactness, 27 Dust filter, 16

Ｅ E3/DS3 cable, 177 Element Manager Software, 75 EOW cable, 179 ESD components, 18 ESD warning label, 18 Ethernet cable, 174

Ｆ Front door handling (at the subrack), 14

Ｇ Grounding bracelet, 18

Ｈ Handling

batteries and accumulators, 23 ESD components, 18 fiber-optic cables and connectors, 19 subrack front door, 14

WEEE, 25 High operating temperature warning label, 15

Ｉ Initial startup, 77 Installation steps, 28 Installing the chassis, 31 Installing the module cards, 39

Ｌ Laser class, 21 Laser devices, 20 Laser safety shutdown, 21 Laser warning label, 20 LED indications, 159

Ｍ Management cable, 176 MDI/MDO cable, 178, 179 MIB management, 108 Mounting the chassis, 39

Ｎ NE configuration and management, 91

Start, 91 Synchronize NE, 100

Ｏ Optical fiber bending radius, 19 Overvoltage on the power supply input, 17

Ｐ PC requirements, 75 Personal requirements, 26 Pin assignments, 163 Plug and pull aid with modules, 19 Protection against laser light, 20 Protection against power supply input overvoltage, 17 Protective caps for optical connectors, 20

Ｒ Replacement components, 24

Index .



184 (184)

Ｓ Safety shutdown of the laser, 22 Site preparation, 28 STM-1E cable, 177 Subrack front door handling, 14 Subrack weight, 15

Ｔ Temperature warning label, 15 Timing cable, 177

Ｕ Unpacking card shipping box, 30 Unpacking shipping box, 29

Ｗ Warning labels

heavy weight, 15 high operating temperature, 15 laser devices, 20

WEEE warning label, 25 Weight of the subrack warning label, 15

Date post:	26-Oct-2015
Category:	Documents
Upload:	ouzennou-assou
View:	136 times
Download:	3 times

hit_7035_itmn

Documents