Summary of Contents for Alcatel-Lucent 1675 LambdaUnite
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See notice on first page 1675 LambdaUnite MultiService Switch (MSS) Release 10.0 Installation and System Turn-up Guide 365-374-179R10.0 CC109670497 Issue 2 June 2009 Alcatel-Lucent - Proprietary This document contains proprietary information of Alcatel-Lucent and is not to be disclosed or used except in accordance with applicable agreements.
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Contents About this information product Purpose xxxiii xxxiii ..................................... Reason for reissue xxxiii xxxiii ................................Safety information xxxiii xxxiii ................................Intended audience xxxiii xxxiii ................................How to use this information product xxxiii xxxiii ........................... Conventions used xxxv xxxv ................................... Orientation aids xxxvii xxxvii ...................................
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Contents General notes on safety Overview ...................................... Structure of hazard statements ............................Basic safety aspects ................................. Specific safety areas Overview 1-10 1-10 ....................................Laser safety 1-11 1-11 ....................................Optical circuit pack specifications 1-14 1-14 ..........................Laser product classification 1-16 1-16 ..............................
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Contents Mark descriptions 2-14 2-14 ................................... Sequence of steps 2-15 2-15 ................................... Mechanical installation Overview ...................................... ETSI-2 installation Overview ...................................... Hardware items ..................................Technical data for rack ................................Procedure 3-1: Eye bolts ............................... Procedure 3-2: Floor mounting ............................Procedure 3-3: Top mounting 3-13 3-13 ............................
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Contents Procedure 3-13: Rack extension (height) 3-49 3-49 ........................Procedure 3-14: Rack adapter kit 3-51 3-51 ............................ Technical data for PDP 3-54 3-54 ................................ Technical data for subrack 3-56 3-56 ..............................Procedure 3-15: Mounting the subracks into rack 3-58 3-58 ....................
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Contents Configuration rules 5-40 5-40 ................................Procedure 5-6: Mounting the circuit packs 5-54 5-54 ......................... Physical installation check 5-62 5-62 ..............................Exit checklist – Part I Overview ...................................... Physical and power installation exit checklist ......................Power supply measurements ..............................Part II: NE provisioning and stand-alone installation test NE provisioning Overview ......................................
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Contents Stand-alone test procedures Overview ...................................... Procedure 8-1: LED test ................................ Procedure 8-2: Alarm reporting tests ..........................Procedure 8-3: NE synchronization test .......................... Procedure 8-4: Optical power meter test 8-11 8-11 ........................Procedure 8-5: Receiver sensitivity test 8-16 8-16 ........................Procedure 8-6: DS3 transmission and protection test 8-24 8-24...
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Contents Procedure 10-8: SNCP/UPSR test setup 10-43 10-43 ........................Test procedures Overview 10-50 10-50 ....................................Procedure 10-9: Line timing test 10-51 10-51 ........................... Procedure 10-10: 1+1 MSP/APS test 10-54 10-54 .......................... Procedure 10-11: 2-fiber MS-SPRing/BLSR test 10-59 10-59 ....................Procedure 10-12: 4-fiber MS-SPRing/BLSR test 10-65 10-65 ....................
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Contents Procedure A-1: Power failure ............................. Procedure A-2: Fan unit test failure ..........................Procedure A-3: NE synchronization failure ........................Procedure A-4: CTL failure ..............................Procedure A-5: CTL protection test failure A-10 A-10 ........................ Procedure A-6: XC protection test failure A-11 A-11 ........................
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Procedure D-7: Mounting the anti-recirculation plate D-14 D-14 ................... Result D-15 D-15 ......................................Mixed configuration: 1675 LambdaUnite MSS and 1665 DMX (High Capacity) Overview ...................................... Procedure E-1: Mounting the 1675 LambdaUnite MSS subrack ................. Procedure E-2: Mounting the heat baffle ........................®...
List of tables Part I: Physical and power installation Safety Optical circuit pack specifications 1-14 1-14 ........................Laser classes (FDA/CDRH regulations) 1-17 1-17 ....................... Laser classes (IEC 60825-1 standard) 1-17 1-17 ......................General information Required tools 2-12 2-12 ................................. Required test equipment 2-12 2-12 ............................
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List of tables Available fan power cables 4-17 4-17 ..........................Pin assignments (fan power cables) 4-18 4-18 ....................... Available controller cables 4-28 4-28 ..........................Pin assignments (Controller cable) 4-29 4-29 ......................... Available subrack alarm cables 4-31 4-31 ........................Pin assignments (subrack alarm cables) 4-32 4-32 .......................
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List of tables Part II: NE provisioning and stand-alone installation test NE provisioning Elements of the Settings tab 7-21 7-21 ..........................Elements of the Date and Time screen 7-33 7-33 ......................Stand-alone test procedures Mean launched power ranges 8-13 8-13 ...........................
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List of figures Part I: Physical and power installation Safety Laser warning labels 1-12 1-12 ............................. ESD symbol 1-20 1-20 ................................Climatic limits (transportation and storage) 1-24 1-24 ....................Climatic limits (operation) 1-36 1-36 ..........................General information Floorplan guidelines (top view) .........................
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List of figures Rack extension height, 600 mm 3-18 3-18 ........................3-10 Rack extension height, 750 mm 3-18 3-18 ........................3-11 Rack line-up without rack extensions (width) 3-20 3-20 ................... 3-12 Rack line-up with rack extensions (width) 3-21 3-21 ....................3-13 PDP layout 3-23...
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List of figures 3-36 Fiber guide mounting 3-63 3-63 ............................3-37 Mounting positions - two subracks (NEBS-2000 rack) 3-64 3-64 ................. 3-38 Mounting positions - one subrack (NEBS-2000 rack) 3-65 3-65 ................System cabling and final assembly Cable block diagram ...............................
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List of figures 4-24 Layout (Multi coax cable, STM-1e) 4-41 4-41 ......................4-25 STM-1e cabling with rack extension (width) 4-42 4-42 ..................... 4-26 STM-1e cabling without rack extension (width) 4-43 4-43 ..................4-27 Mounting of the cable bracket 4-44 4-44 .........................
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List of figures Fan unit LEDs ................................Rubber air flow baffles ............................Blank front plate (3N) — CC848782868 5-37 5-37 ....................Blank front plate (3N) with empty holes — CC848840112 5-38 5-38 ..............Blank front plate (6N) — CC848782876 5-39 5-39 ....................
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List of figures Stand-alone test procedures Mean launched power test 8-12 8-12 ..........................Receiver sensitivity test 8-18 8-18 ............................DS3 transmission test 8-25 8-25 ............................Daisy chain test 8-34 8-34 ..............................XC and CTL protection test 8-40 8-40 ..........................Part III: Network establishment and testing Network establishment and testing 10-1 Protected ring configuration...
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D-14 ........................D-10 Mounting positions (1675 LambdaUnite MSS and 1663 ADMu) D-15 D-15 ........... Mixed configuration: 1675 LambdaUnite MSS and 1665 DMX (High Capacity) Mounting the subrack guides ......................................................................... Alcatel-Lucent - Proprietary 365-374-179R10.0 xxiv See notice on first page...
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List of figures Mounting the subrack ............................Mounting the heat baffle ............................Mounting the anti-recirculation plate ......................Mounting positions (1675 LambdaUnite MSS and 1665 DMX) ........................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
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List of procedures Part I: Physical and power installation General information ® ® Running WaveStar CIT with Windows XP SP2 ..................Mechanical installation Eye bolts ..................................Floor mounting ................................Top mounting 3-13 3-13 ................................Rack extension (width) 3-15 3-15 ............................Rack extension (height) 3-17 3-17...
List of procedures 7-11 External timing inputs 7-43 7-43 ............................Stand-alone test procedures LED test ..................................Alarm reporting tests .............................. NE synchronization test ............................Optical power meter test 8-11 8-11 ............................. Receiver sensitivity test 8-16 8-16 ............................DS3 transmission and protection test 8-24 8-24 ......................
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List of procedures 10-15 Optical port provisioning for SCN 10-84 10-84 ....................... 10-16 DCC provisioning for SCN 10-86 10-86 ..........................® 10-17 Launching the WaveStar CIT ONNS application for the first time 10-88 10-88 ..........10-18 Path creation test 10-95 10-95 ..............................
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D-13 D-13 .......................... Mounting the anti-recirculation plate D-14 D-14 ......................Mixed configuration: 1675 LambdaUnite MSS and 1665 DMX (High Capacity) Mounting the 1675 LambdaUnite MSS subrack ..................Mounting the heat baffle ............................® Mounting the Metropolis DMX (High Capacity) subrack ..............
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LambdaUnite MultiService Switch (MSS) system. Furthermore, all steps for putting the system into operation are also described. Reason for reissue This is a revised version of this document for 1675 LambdaUnite MSS Release 10.0, containing improvements and corrections. Safety information This information product contains hazard statements for your safety.
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• Chapter 3, Mechanical installation This chapter provides all information needed to install the mechanical parts of a 1675 LambdaUnite MSS system, such as racks, subracks, and other needed accessories. • Chapter 4, System cabling and final assembly This chapter provides all tasks for complete system cabling and instructions for installing the rack doors and side cover plates.
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This appendix provides instructions for mounting a 1675 LambdaUnite MSS subrack together with one or two 1663 Add Drop Multiplexer-universal subrack(s) within one ETSI-2 rack. • Appendix E, Mixed configuration (1675 LambdaUnite MSS and 1665 DMX (High Capacity)) This chapter provides instructions for mounting a 1675 LambdaUnite MSS subrack together with one 1665 Data Multiplexer (High Capacity) subrack within one NEBS-2000 rack.
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About this information product Symbols Symbols Listing: Front View Rear View Top View Bottom View Star point. The stars in the figures refer to the descriptions in the text or in the legend. Item. The items mentioned in the figures refer to the text or to the list of materials Washer Ground Washer...
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About this information product Paddle Board Alarm Lamp Fuse Circuit Breaker Relay Contacts Cable Number View of the cabling side of the connector Codes The codes (CC, DC and SC) in this manual are used to define a hardware item owned by the Alcatel-Lucent Development Systems.
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About this information product Overall TOC Chapter TOC Index Overall TOC The overall table of contents (TOC) provides a structural overview of the entire document. It lists the content of each chapter and the associated page number where the respective information can be found. The overall table of contents can be found after the legal page, before the “About this information product”...
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• Applications and Planning Guide The 1675 LambdaUnite MSS Applications and Planning Guide (APG) is for use by network planners, analysts and managers. It is also for use by the Alcatel-Lucent Account Team. It presents a detailed overview of the system, describes its applications, gives planning requirements, engineering rules, ordering information, and technical specifications.
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(NE) software and WaveStar CIT software. It also includes a listing of features, known problems, fixed problems, and other helpful information. The manuals and engineering drawings related to 1675 LambdaUnite MSS are shown in the following table: Document title Document code...
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Alcatel-Lucent Online Customer Support Site (OLCS) (https://support.lucent.com) or through your Local Customer Support. Related training For detailed information about the 1675 LambdaUnite MSS training courses and how to register please refer to the 1675 LambdaUnite MSS Applications and Planning Guide, chapter 8. Intended use This equipment shall be used only in accordance with the intended use, corresponding installation and maintenance statements as specified in this documentation.
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About this information product Conventional lasers can produce an intense beam of monochromatic light. The term “monochromaticity” means a single wavelength output of pure color that may be visible or invisible to the eye. A conventional laser produces a small-size beam of light, and because the beam size is small the power density (also called irradiance) is very high.
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About this information product Laser safety precautions for optical fiber telecommunication systems CAUTION Laser hazard Use of controls, adjustments, and procedures other than those specified herein may result in hazardous laser radiation exposure. In its normal operating mode, an optical fiber telecommunication system is totally enclosed and presents no risk of eye injury.
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4. All unauthorized personnel shall be excluded from the immediate area of the optical fiber telecommunication systems during installation and service. For the optical specifications please refer to the 1675 LambdaUnite MSS Applications and Planning Guide, chapter 10, section “Transmission parameters”.
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3rd party who engages in the installation and/or integration of the 1675 LambdaUnite MSS system. It is required that the 1675 LambdaUnite MSS product be installed using this Installation Guide. Furthermore, this document needs to be completed as an initial requirement to activating technical support services such as Remote Technical Support (RTS).
Overview ..............................................Purpose This part of the 1675 LambdaUnite MSS Installation Guide contains the physical ® installation of the racks and subracks, the system cabling and powering, the WaveStar CIT and NE software installation and the installation of circuit packs, side panels and doors.
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Are there any obstacles that will affect the physical installation or cabling? Are the required fuse/breaker positions available? Are the needed 1675 LambdaUnite MSS racks available (ETSI-2 or NEBS-2000)? Are the needed 1675 LambdaUnite MSS subracks available? Are all needed 1675 LambdaUnite MSS...
Physical and power installation Overview Procedure Completed Initials Notes Is the 1675 LambdaUnite MSS CD-ROM (CC109646745) available which contains ® the WaveStar CIT and NE software? Is a laptop or desktop PC available that fulfills the minimum requirements (see section “Requirements”...
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..............................................Purpose The aim of this chapter on safety is to provide users of 1675 LambdaUnite MSS systems with the relevant information and safety guidelines to safeguard against personal injury. Furthermore, this chapter may be useful to prevent material damage to the equipment.
Safety General notes on safety Overview ..............................................Purpose This section provides general information on the structure of safety instructions and summarizes general safety requirements. Contents Structure of hazard statements Basic safety aspects ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
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Safety Structure of hazard statements ..............................................Overview Hazard statements describe the safety risks relevant while performing tasks on Alcatel-Lucent products during deployment and/or use. Failure to avoid the hazards may have serious consequences. General structure Hazard statements include the following structural elements: Item Structure element Purpose...
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Safety Structure of hazard statements Signal words The signal words identify the hazard severity levels as follows: Signal word Meaning DANGER Indicates an imminently hazardous situation (high risk) which, if not avoided, will result in death or serious injury. WARNING Indicates a potentially hazardous situation (medium risk) which, if not avoided, could result in death or serious injury.
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Safety Structure of hazard statements Radioactivity Hazard caused by batteries Hot surface Heavy load Unhealthy, irritating substance Hazard of falling ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
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Safety Basic safety aspects ..............................................General safety requirements In order to keep the technically unavoidable residual risk to a minimum, it is imperative to observe the following rules: • Transport, storage and operation of the system must be under the permissible conditions only.
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• For information on proper mounting instructions, consult the 1675 LambdaUnite MSS Installation Guide. • Install only equipment identified in the 1675 LambdaUnite MSS Installation Guide provided with this product. Use of other equipment may result in improper connection of circuitry leading to fire or injury to persons.
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CAUTION Laser hazard 1675 LambdaUnite MSS systems contain optical circuit packs that can emit laser radiation assessed as IEC Hazard Level 3A or IEC Hazard Level 1M. Therefore, 1675 LambdaUnite MSS systems may only be installed in restricted access...
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..............................................Purpose The aspects of “laser safety” and “handling of components sensitive to electrostatic discharge (ESD)” are of vital importance for the 1675 LambdaUnite MSS equipment. Therefore, the key safety instructions for these subjects are summarized in the following. Contents...
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Please also refer to “Laser product classification” (p. 1-16). These laser warning labels (not to scale) are affixed on the 1675 LambdaUnite MSS equipment. They refer to the system as a whole in normal operation. Figure 1-1 Laser warning labels (1 of 2) ..............................................
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Safety Laser safety Figure 1-1 Laser warning labels (2 of 2) Potential sources of danger Beware of the following potential sources of danger which will remain despite all safety measures taken: • Laser radiation can cause damage to the skin and eyes. •...
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Safety Laser safety CAUTION Laser hazard Use of controls, adjustments and procedures other than those specified herein may result in hazardous laser radiation exposure..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 1-13 Issue 2, June 2009 See notice on first page...
Safety Optical circuit pack specifications ..............................................Specifications The following table contains the specifications of the 1675 LambdaUnite MSS optical circuit packs. Please refer to the 1675 LambdaUnite MSS Applications and Planning Guide for more detailed technical specifications. Table 1-1 Optical circuit pack specifications...
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It is the class of the circuit pack, not that of the telecommunications system as a whole, that is specified. The OP10/1.5LR1 circuit packs delivered with 1675 LambdaUnite MSS Releases 1.0 or 2.0 are classified as Class 3A laser products in accordance with the IEC classification (cf.
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Safety Laser product classification ..............................................Standards compliance The 1675 LambdaUnite MSS product complies with the applicable IEC standards and the Food and Drug Administration’s Center for Devices and Radiological Health (FDA/CDRH) regulations. FDA/CDRH regulations Laser products are classified in accordance with the FDA/CDRH - 21 CFR 1010 and 1040.
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Safety Laser product classification FDA/CDRH laser classification The following table provides an overview of laser classes for wavelengths of 1310 nm and 1550 nm in accordance with the FDA/CDRH regulations. Table 1-2 Laser classes (FDA/CDRH regulations) Laser class Wavelength Max. output power of laser radiation 1310 nm 1.53 mW +1.85 dBm...
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Safety Laser product classification Table 1-3 Laser classes (IEC 60825-1 standard) (continued) Laser class Wavelength Max. output power of laser radiation 1310 nm > 500 mW > +27 dBm 1550 nm > 500 mW > +27 dBm Notes: Class 3R only exists if the maximum power is within five times the Accessible Emission Limit (AEL) of Class 1.
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Safety Laser product classification Hazard levels for optical transmission equipment are assigned in either of the following two ways: • the actual output power from the connector or fiber cut. • if automatic power reduction is used, the output power at the connector or fiber cut one second after automatic power reduction takes place, provided that maximum output and restart conditions are met.
Safety Electrostatic discharge ..............................................Introduction Electrostatic discharge (ESD), caused by touching with the hand for example, can destroy semiconductor components. The correct operation of the complete system is then no longer assured. Industry experience has shown that all semiconductor components can be damaged by static electricity that builds up on work surfaces and personnel.
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Safety Electrostatic discharge • Store and ship circuit packs and components in their shipping packing. Circuit packs and components must be packed and unpacked only at workplaces suitably protected against build-up of charge. • Whenever possible, maintain the relative humidity of air above 20%..............................................
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..............................................Purpose To enable rapid orientation, safety instructions are given on the following pages, which are assigned to various stages in the life cycle of the 1675 LambdaUnite MSS equipment (“deployment phases”). Deployment phases The instructions are arranged according to the following deployment phases: •...
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Safety Transportation ..............................................Weight WARNING Risk of injury due to unsecured shelf. A fully-equipped shelf weighs more than 30 kg (66 lbs) and can cause considerable injuries if it is knocked over or dropped. This can also cause serious damage to the shelf.
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Safety Transportation Climatic limits for transportation and storage These are the climatic limits for transportation and storage of 1675 LambdaUnite MSS systems: Temperature range -40 °C (-40 °F) to +70 °C (+158 °F) (exceptional: +85 °C (+185 °F)) Humidity range relative humidity: 10% to 100% absolute humidity: 0.5 g/m...
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Safety Storage ..............................................Weight WARNING Risk of injury due to unsecured shelf. A fully-equipped shelf weighs more than 30 kg (66 lbs) and can cause considerable injuries if it is knocked over or dropped. This can also cause serious damage to the shelf.
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Safety Storage Climatic conditions CAUTION Damage to system components under extreme environmental conditions. Extreme environmental conditions can damage system components and cause malfunctioning. Ensure that the climatic limits for transportation and storage of 1675 LambdaUnite MSS equipment are complied with during storage; please refer to “Climatic limits for transportation and storage”...
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Safety Installation ..............................................Weight WARNING Risk of injury due to unsecured shelf. A fully-equipped shelf weighs more than 30 kg (66 lbs) and can cause considerable injuries if it is knocked over or dropped. This can also cause serious damage to the shelf.
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The following label is affixed on the 1675 LambdaUnite MSS subrack: Receiver sensitivities You can find the receiver sensitivities in the 1675 LambdaUnite MSS Applications and Planning Guide (Technical specifications)..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0...
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Invisible laser radiation DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on.
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Destruction of components due to a supply voltage of incorrect polarity or too high. 1675 LambdaUnite MSS equipment operates at a nominal voltage of -48 V or -60 V. The permissible tolerance range is -40.5 V to -72 V. Ensure that the supply voltage has the correct range and polarity before connecting the voltage.
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Safety Taking into operation Condensation CAUTION Condensation causes malfunctioning. Condensation can occur in the network element during transport, especially on moving from outside to closed rooms; this can cause malfunctioning of the circuit packs. Ensure that circuit packs and shelves have reached room temperature and are dry before taking them into operation.
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Invisible laser radiation DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on.
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Safety Operation and maintenance DANGER Power Interface PI/100NOCB: Arcing on removing or connecting live power supply cable lugs. Arcing can cause burns to the hands and damage to the eyes. Before removing or connecting the power supply cable lugs at the Power Interface (PI/100NOCB), ensure that the power supply line is switched off at the upstream circuit breaker in the BDFB (Battery Distribution and Fuse Bay) or PDP (Power Distribution Panel).
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The following label is affixed on the 1675 LambdaUnite MSS subrack: Receiver sensitivities You can find the receiver sensitivities in the 1675 LambdaUnite MSS Applications and Planning Guide (Technical specifications)..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0...
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(p. 1-35) are complied with during operation. Climatic limits for the operation of 1675 LambdaUnite MSS equipment These are the climatic limits for the operation of 1675 LambdaUnite MSS systems: Temperature +5 °C (+41 °F) to +40 °C (+104 °F) range (exceptional: –5°C (+23 °F) to +50 °C (+122 °F))
Absolute humidity [g water/kg dry air]. The dashed curve specifies a constant absolute humidity of 24 g water per kg dry air. Permissible range for the operation of 1675 LambdaUnite MSS systems. Exceptional conditions, permissible for a short duration only.
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Invisible laser radiation DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on.
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1-20)). Disposal The equipment in the 1675 LambdaUnite MSS system series must be disposed of at the end of its lifetime. Please contact us in this case and we will arrange for proper and environment-friendly disposal of your equipment (most parts of the system can be recycled).
G eneral information Overview ..............................................Purpose The purpose of this chapter is to provide the information needed to plan the installation of a 1675 LambdaUnite MSS system. Contents Floorplan guidelines (ETSI-2 / NEBS-2000) Technical data EMC/ESD information ® WaveStar CIT requirements ®...
General information Floorplan guidelines (ETSI-2 / NEBS-2000) ..............................................Overview This section describes the floorplan data for both rack types (ETSI-2 and NEBS-2000). NOTE: For exact measurements see the relevant project documents. Local circumstances can allow deviations from these guidelines. Guidelines Use the following figures and data as guidelines: •...
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General information Floorplan guidelines (ETSI-2 / NEBS-2000) Legend: Inches 23.622” 29.527” 1350 53.149” Figure 2-2 Floorplan guidelines (side view) Legend: Inches 2.948” ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
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General information Floorplan guidelines (ETSI-2 / NEBS-2000) 11.811” 23.622” 29.527” 1350 53.149” 2125 83.661” 2200 86.615” 2525 99.410” 2600 102.201” ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
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The standard height is 2200 mm [86.614”] for an ETSI-2 rack and 2125 mm [83.661”] for a NEBS-2000 rack. The racks are designed to accommodate two 1675 LambdaUnite MSS subracks. Rack weights The ETSI-2 rack has a maximum weight of 92.3 kg [203.5 lbs] (including PDP, rack...
General information EMC/ESD information ..............................................Required connections The system was developed in compliance with the ETSI Mesh Ground requirements. This means EMC compliance and personnel safety can be achieved only if the system is connected to a System-Reference Potential Plane (SRPP) at many places as described in ETS 300 253 (see the figure below).
General information EMC/ESD information Circuit pack handling The following ESD instructions must be observed when handling circuit packs: • Wear work garments made of 100% cotton to avoid electrostatic charging. • Touch the circuit packs at the edges or the insertion and removal facilities only. •...
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General information ® WaveStar CIT requirements ..............................................Requirements ® For a WaveStar CIT a personal computer is necessary that fulfills the following minimum requirements: ® Pentium III processor with 800 MHz 512 MB RAM 2 GB of free hard-disk drive space CD-ROM drive (16×...
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General information ® ® Procedure 2-1: Running WaveStar CIT with Windows ..............................................Overview ® ® ® When using WaveStar CIT with Windows XP Service Pack 2, the Windows security features introduced with SP2 require some user interaction to allow running ®...
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® ® General information Procedure 2-1: Running WaveStar CIT with Windows XP SP2 ........................................Click to confirm that message........................................Activate the context menu of the MSIE information bar and select Allow Blocked Content{ ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 2-10 See notice on first page Issue 2, June 2009...
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® ® General information Procedure 2-1: Running WaveStar CIT with Windows XP SP2 A security warning window appears. Result: ........................................Click S T E P S ...................................................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary 2-11 Issue 2, June 2009 See notice on first page...
General information Required tools and test equipment ..............................................Tools A variety of tools is required to carry out the installation procedures. The following table provides an overview of the required tools. Table 2-1 Required tools Quantity Description Comments Metric tool set To be used for physical installation Torque wrench To be used when tightening the subracks to the...
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General information Required tools and test equipment Table 2-2 Required test equipment (continued) Quantity Description Comments 15 dB LBO To be used for optical test loops or for testing the individual ports ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 2-13 Issue 2, June 2009 See notice on first page...
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General information Mark descriptions ..............................................CE mark The CE mark indicates that the products conform to the relevant European Community (EC) Directives. This CE-marked subrack is compliant with the following Directives: • EC89.336/EEC - Electromagnetic Compatibility (EMC) • EC73.23/EEC - Low-Voltage Directive (LVD). UR mark The UR mark indicates that the products conform to the relevant Directives of the United States of America.
This manual is structured according to the sequence of steps that should be observed when installing the 1675 LambdaUnite MSS system. The table below gives an overview of all needed installation steps which are described in detail in the following chapters.
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General information Sequence of steps Table 2-3 Sequence of steps Main task Chapter Subtask [section/page] number Rack installation Checking the “Hardware items” (p. 3-4) (ETSI-2) or Checking the “Hardware items” (p. 3-35) (NEBS-2000) Procedure 3-2: “Floor mounting” (p. 3-9) (ETSI-2) or Procedure 3-10: “Floor mounting”...
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General information Sequence of steps Table 2-3 Sequence of steps (continued) Main task Chapter Subtask [section/page] number Power and ground “Power wiring (External battery - PDP)” (p. 4-7) cable installation Procedure 4-1: “Power wiring (PDP - PI/100)” (p. 4-11) Procedure 4-2: “Ground wiring” (p. 4-21) Internal cable Procedure 4-3: “Subrack alarm wiring”...
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General information Sequence of steps Table 2-3 Sequence of steps (continued) Main task Chapter Subtask [section/page] number ® NE login “Connecting the WaveStar CIT to the NE” (p. 7-3) Procedure 7-1: “NE login via OSI” (p. 7-7) NE provisioning Procedure 7-3: “Changing the NE name (TID)” (p. 7-14) Procedure 7-4: “System parameters”...
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General information Sequence of steps Table 2-3 Sequence of steps (continued) Main task Chapter Subtask [section/page] number Network Procedure 10-1: “Connecting the fiber cables” (p. 10-4) establishing Procedure 10-2: “Provision DCC” (p. 10-12) ® Procedure 10-3: “WaveStar CIT remote login test via DCC” (p.
Purpose The purpose of this chapter is to provide the information needed to install all mechanical parts of a 1675 LambdaUnite MSS system. The chapter is divided into two sections. The first section describes the ETSI-2 installation for the international market, the second section the NEBS-2000 installation for the USA domestic market.
Mechanical installation Overview Contents ETSI-2 installation Hardware items Technical data for rack Procedure 3-1: Eye bolts Procedure 3-2: Floor mounting Procedure 3-3: Top mounting 3-13 Procedure 3-4: Rack extension (width) 3-15 Procedure 3-5: Rack extension (height) 3-17 Procedure 3-6: Rack adapter kit 3-19 Technical data for PDP 3-22...
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Mechanical installation ETSI-2 installation Overview ..............................................Purpose The purpose of this section is to provide all needed instructions for mounting an ETSI-2 rack (international market). NOTE: Metric tools have to be used for equipment installation! Contents Hardware items Technical data for rack Procedure 3-1: Eye bolts Procedure 3-2: Floor mounting Procedure 3-3: Top mounting...
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Mechanical installation Hardware items ..............................................Reference For a complete and up-to-date list of all hardware items with the respective comcodes please refer to the Engineering Drawings ED8C948-10 and ED8C948-20, that you can: • find appended at the end of this document, correct at the time of going to print (if they were ordered from the Customer Information Center (CIC)) •...
Mechanical installation Technical data for rack ..............................................Specifications The ETSI-2 rack has the specifications as given in the table below. Table 3-1 ETSI-2 rack specifications Item Quantity / Size Weight 92.3 kg [203.5 lbs] (including PDP, rack cables and 2 door sets) 53.7 kg [118.4 lbs] (without doors) Dimensions (HxWxD) 2200 mm [86.614”] x 600 mm [23.622”] x 600 mm [23.622”]...
Mechanical installation Technical data for rack Figure 3-1 Rack layout (ETSI-2 rack) Legend: ETSI-2 rack ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
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Mechanical installation Technical data for rack Rack door, left (optional) Rack door, right (optional) Door support bottom 5, 6 Door support top with indicator strip Bottom-access entry hole Top-access entry hole Eye bolt (optional) Subrack guide Cable guide brackets Cable rod Side cover plate (optional) Adjustable feet Anti recirculation plate (optional)
Mechanical installation Procedure 3-1: Eye bolts ..............................................Before you begin This section describes the mounting of eye bolts which are needed for rack transportation. It can be skipped if no rack transportation is required. Procedure Proceed as follows to mount the eye bolts: ........................................
Mechanical installation Procedure 3-2: Floor mounting ..............................................Dimensions The following figure shows the plate layout (with dimensions) of the ETSI-2 rack. Figure 3-3 Top/Bottom plate layout (ETSI-2 rack) Legend: Hole locations for the anchors (anchoring kit SE12150W-1 — CC408414951) Adjustable feet — CC407890623 NOTE: The front panel is identified by the “cable guide brackets”...
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Mechanical installation Procedure 3-2: Floor mounting Complete the following steps to mount an ETSI-2 rack on the floor: ........................................Drill the necessary holes (18 mm [0.7”] in diameter and 100 mm [4”] in depth) in the floor (*1)........................................Put the rack frame in place........................................
Mechanical installation Procedure 3-3: Top mounting ..............................................Before you begin This section can be skipped if a top infrastructure (e.g. cable tray) does not exist. Needed parts The following parts are needed for a top mounting fixture: • M12 threaded rods (CC408854065) •...
Mechanical installation Procedure 3-3: Top mounting Figure 3-7 Top mounting fixture (ETSI-2 rack) S T E P S ....................................................................................... Alcatel-Lucent - Proprietary 365-374-179R10.0 3-14 See notice on first page Issue 2, June 2009...
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Mechanical installation Procedure 3-4: Rack extension (width) ..............................................Purpose The ETSI-2 rack extension (CC848894416) is used to route STM-1e, DS3 and fiber cables which do not fit properly in the rack frame. Mounting the rack extension Proceed as follows to mount the rack extension: ........................................
Mechanical installation Procedure 3-4: Rack extension (width) Result Figure 3-8 Mounting the rack extension (width) ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 3-16 See notice on first page Issue 2, June 2009...
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Mechanical installation Procedure 3-5: Rack extension (height) ..............................................Purpose This rack extension is used to enlarge the rack frame with a height of 400 mm [15.748”]. The additional space can be used for STM-1e cable excess lengths, for example. Available rack extensions The following rack extensions are available: •...
Mechanical installation Procedure 3-5: Rack extension (height) Result Figure 3-9 Rack extension height, 600 mm Figure 3-10 Rack extension height, 750 mm ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 3-18 See notice on first page Issue 2, June 2009...
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Mechanical installation Procedure 3-6: Rack adapter kit ..............................................Overview The rack adapter kit is used to mount rack frames together side-by-side to establish a line-up. Before you begin If the existing rack(s) already have side-cover plates, remove these cover plates from the sides of the existing rack(s) to which another rack(s) will be connected.
Mechanical installation Procedure 3-6: Rack adapter kit ........................................IF ... THEN ... rack extensions (width) are not place the rack frame (item 4) of the extension rack used next to the existing rack. rack extensions (width) are used place the rack extension of the extension rack next to the rack extension (item 5) of the existing rack.
Mechanical installation Technical data for PDP ..............................................Specifications The Power Distribution Panel (PDP) is already pre-mounted on the rack frame and has the specifications as given in the table below. Table 3-2 PDP specifications Item Quantity / Size Power consumption (subrack), Release 1.0 and 2.0: Circuit breakers •...
Mechanical installation Technical data for PDP Figure 3-13 PDP layout Power conversion ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 3-23 Issue 2, June 2009 See notice on first page...
Mount the MDIO terminal rail (SC02071000, item 1) to the rack top (front side) as shown in the figure below. NOTE: Each MDIO terminal rail supports one 1675 LambdaUnite MSS subrack. Figure 3-14 Mounting the MDIO terminal rail S T E P S ........................................
Mechanical installation Technical data for subrack ..............................................Specifications A 1675 LambdaUnite MSS subrack has the specifications as given in the table below. Table 3-3 Subrack specifications Item Quantity/Value Voltage range -48 to -60 V battery voltage (all components) (-40.5 V minimum, -72 V maximum)
Mechanical installation Technical data for subrack Figure 3-15 Subrack mounting dimensions Legend: Required space for air outlet (≥ 100 mm [3.94”]) when a single subrack is mounted into a rack frame. Bending radius of fiber and external cabling..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 3-26 See notice on first page...
(which should then be mounted in the upper position). NOTE: If a mixed configuration with 1663 ADMu NEs is used, please refer to Appendix D, “Mixed configuration: 1675 LambdaUnite MSS and 1663 ADMu”. Procedure...
Mechanical installation Procedure 3-8: Mounting the subracks into rack ........................................Mount each subrack on the rear rack frame using M6x16 screws (CC901331421) with 7 ± 1.0 Nm [61.96 ± 2.65 lbs-in] torque. Use the hole positions #9, #14, #19, #25, #31, #36 and #41 for the upper subrack and #47, #52, #57, #63, #69, #74 and #79 for the lower subrack (see Figure 3-18, “Mounting positions (ETSI-2 rack)”...
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Mechanical installation Procedure 3-8: Mounting the subracks into rack ........................................Mount one side guide (DC1001518, item 3) at each corner of the subracks by clicking them into the holes on the top and bottom panels of the subracks. S T E P S ........................................
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Mechanical installation Procedure 3-8: Mounting the subracks into rack Result Figure 3-16 Subrack mounting ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 3-30 See notice on first page Issue 2, June 2009...
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Mechanical installation Procedure 3-8: Mounting the subracks into rack Mounting of special fiber guides Important! The following procedure must only be performed if it is necessary to route fiber cables within the rack extension (width). In that case special fiber guides which are part of the rack extension kit (CC848894416) must be mounted on each subrack.
Mechanical installation Procedure 3-8: Mounting the subracks into rack Result Figure 3-17 Fiber guide mounting Mounting positions The mounting positions are given in the following figure..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 3-32 See notice on first page Issue 2, June 2009...
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Mechanical installation Procedure 3-8: Mounting the subracks into rack Figure 3-18 Mounting positions (ETSI-2 rack) ETSI-2 Rack LambdaUnite Subrack LambdaUnite Subrack ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 3-33 Issue 2, June 2009 See notice on first page...
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Mechanical installation NEBS-2000 installation Overview ..............................................Purpose The purpose of this section is to provide all needed instructions for mounting the NEBS-2000 rack (USA domestic market). NOTE: Metric tools have to be used for equipment installation! Contents Hardware items 3-35 Technical data for rack 3-36 Procedure 3-9: Eye bolts...
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Mechanical installation Hardware items ..............................................Reference For a complete and up-to-date list of all hardware items with the respective comcodes please refer to the Engineering Drawings ED8C948-10 and ED8C948-20, that you can: • find appended at the end of this document, correct at the time of going to print (if they were ordered from the Customer Information Center (CIC)) •...
Mechanical installation Technical data for rack ..............................................Specifications The NEBS-2000 rack has the specifications as given in the table below. Table 3-4 NEBS-2000 rack specifications Item Quantity / Size Weight 90.5 kg [199.6 lbs] (includes PDP, rack cables and 2 door sets) 52.7 kg [116.2 lbs] (without doors) Dimensions (HxWxD) 2125 mm [83.661”] x 600 mm [23.622”] x 600 mm [23.622”]...
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Mechanical installation Technical data for rack Figure 3-19 Rack layout (NEBS-2000 rack) Legend: NEBS-2000 rack Rack door, left (optional) ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 3-37 Issue 2, June 2009 See notice on first page...
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Mechanical installation Technical data for rack Rack door, right (optional) Door support bottom 5, 6 Door support top with indicator strip Bottom-access entry hole Top-access entry hole Eye bolt (optional) Subrack guide Cable guide brackets Cable rod Side cover plate (optional) Strain relief Anti recirculation plate (optional) Power Distribution Panel (PDP)
Mechanical installation Procedure 3-9: Eye bolts ..............................................Before you begin This section describes the mounting of eye bolts which are needed for rack transportation. It can be skipped if no rack transportation is required. Procedure Proceed as follows to mount the eye bolts: ........................................
Mechanical installation Procedure 3-10: Floor mounting ..............................................Dimensions The following figure shows the plate layout (with dimensions) of the NEBS-2000 rack. Figure 3-21 Top/Bottom layout of plate (NEBS-2000 rack) Legend: Hole locations for the anchors NOTE: The front panel is identified by the cable guide brackets (see item 11 in Figure 3-19, “Rack layout (NEBS-2000 rack)”...
Mechanical installation Procedure 3-10: Floor mounting Figure 3-22 Drilling template (NEBS-2000 rack) Important! Read the label for drilling instructions! ........................................Put the rack frame in place........................................Put the appropriate earthquake anchor (CC408414951 or CC408526242, item 2) through the anchor hole provided in the rack bottom plate........................................
Mechanical installation Procedure 3-10: Floor mounting Figure 3-24 Anchoring kit (NEBS-2000 rack) Legend: Safety/dust cap Hexagonal nut Flat washer Plate washer (60 mm [2.4”]) Spacer Stud Rack frame Concrete Indication marking labels The rack hole numbers #1 and #79 are marked with “indication marking labels”. The hole numbering is counted from top to the bottom of the rack frame.
Mechanical installation Procedure 3-10: Floor mounting Shim Plates The shim plates (SC1006075) are used to balance the cabinet in a horizontal position on the floor. One shim plate is 1 mm [0.04”] thick. Figure 3-25 Shim plates (NEBS-2000 rack) Legend: 1 mm [0.04”] 2 mm [0.08”] 3 mm [0.12”]...
Mechanical installation Procedure 3-11: Top mounting ..............................................Before you begin This section can be skipped if a top infrastructure (e.g. cable tray) does not exist. Needed parts The following parts are needed for a top mounting fixture: • M12 threaded rods (CC408854065) •...
Mechanical installation Procedure 3-11: Top mounting Figure 3-27 Top mounting fixture (NEBS-2000 rack) S T E P S ....................................................................................... Alcatel-Lucent - Proprietary 365-374-179R10.0 3-46 See notice on first page Issue 2, June 2009...
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Mechanical installation Procedure 3-12: Rack extension (width) ..............................................Purpose The NEBS-2000 rack extension (CC848894424) is used to route STM-1e, DS3 and fiber cables which do not fit properly in the rack frame. Mounting Proceed as follows to mount the rack extension: ........................................
Mechanical installation Procedure 3-12: Rack extension (width) Result Figure 3-28 Mounting the rack extension (width) ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 3-48 See notice on first page Issue 2, June 2009...
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Mechanical installation Procedure 3-13: Rack extension (height) ..............................................Purpose This rack extension is used to enlarge the space for STM-1e cables (e.g. for excess lengths). Available rack extensions The following rack extensions are available: • Rack extension (height), 600 mm [23.622”] x 400 mm [15.748”] — CC848902656 This rack extension must be used for racks without rack extensions (width).
Mechanical installation Procedure 3-13: Rack extension (height) Result Figure 3-29 Rack extension height, 600 mm Figure 3-30 Rack extension height, 750 mm ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 3-50 See notice on first page Issue 2, June 2009...
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Mechanical installation Procedure 3-14: Rack adapter kit ..............................................Overview The rack adapter kit is used to mount rack frames together side-by-side to establish a line-up. Before you begin If the existing rack(s) already have side cover plates, remove these cover plates from the sides of the existing rack(s) to which another rack(s) will be connected.
Mechanical installation Procedure 3-14: Rack adapter kit ........................................IF ... THEN ... rack extensions (width) are not place the rack frame (item 4) of the extension rack used next to the existing rack. rack extensions (width) are used place the rack extension of the extension rack next to the rack extension (item 5) of the existing rack.
Mechanical installation Technical data for PDP ..............................................Specifications The Power Distribution Panel (PDP) is already pre-mounted on the rack frame and has the specifications as given in the table below. Table 3-5 PDP specifications Item Quantity / Size Power consumption (subrack), Release 1.0 and 2.0: Circuit breakers •...
Mechanical installation Technical data for PDP Figure 3-33 PDP layout Power conversion ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 3-55 Issue 2, June 2009 See notice on first page...
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Mechanical installation Technical data for subrack ..............................................Specifications A 1675 LambdaUnite MSS subrack has the specifications as given in the table below. Table 3-6 Subrack specifications Item Quantity/Value Voltage range -48 to -60 V battery voltage (all components) (-40.5 V minimum, -72 V maximum)
Mechanical installation Technical data for subrack Figure 3-34 Subrack mounting dimensions Legend: Required space for air outlet (≥ 100 mm [3.94”]) when a single subrack is mounted into a rack frame. Bending radius of fiber and external cabling..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 3-57 Issue 2, June 2009...
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(see section “Mounting positions (one subrack mounted)” (p. 3-65)). If a mixed configuration is used (1675 LambdaUnite MSS and 1665 DMX subracks within one rack) please refer to Appendix E, “Mixed configuration: 1675 LambdaUnite MSS and 1665 DMX (High Capacity)”.
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Mechanical installation Procedure 3-15: Mounting the subracks into rack ........................................Mount each subrack on the rear rack frame using M6x16 screws (CC901331421) with 7 ± 1.0 Nm [61.96 ± 2.65 lbs-in] torque. Use the hole positions #8, #13, #18, #24, #30, #35 and #40 for the upper subrack and #46, #51, #56, #62, #68, #73 and #78 for the lower subrack (see Figure 3-37, “Mounting positions - two subracks (NEBS-2000...
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Mechanical installation Procedure 3-15: Mounting the subracks into rack ........................................Mount one side guide (DC1001518, item 3) at each corner of the subracks by clicking them into the holes in the top and bottom panels of the subracks. S T E P S ........................................
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Mechanical installation Procedure 3-15: Mounting the subracks into rack Result Figure 3-35 Subrack mounting ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 3-61 Issue 2, June 2009 See notice on first page...
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Mechanical installation Procedure 3-15: Mounting the subracks into rack Mounting of special fiber guides Important! The following procedure must only be performed if it is necessary to route fiber cables within the rack extension (width). In that case special fiber guides which are part of the rack extension kit (CC848894424) must be mounted on each subrack.
Mechanical installation Procedure 3-15: Mounting the subracks into rack Result Figure 3-36 Fiber guide mounting ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 3-63 Issue 2, June 2009 See notice on first page...
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Mechanical installation Procedure 3-15: Mounting the subracks into rack Mounting positions (two subracks mounted) The following figure shows the mounting positions for the case that two subracks are mounted. Figure 3-37 Mounting positions - two subracks (NEBS-2000 rack) NEBS-2000 Rack LambdaUnite Subrack LambdaUnite...
Mechanical installation Procedure 3-15: Mounting the subracks into rack Mounting positions (one subrack mounted) The following figure shows the mounting positions for the case that one subrack is mounted only. NOTE: A stiffening plate is required for that configuration if the system is installed in seismic zone 4 areas according to Telcordia GR-63.
S ystem cabling and final assembly Overview ..............................................Purpose The purpose of this chapter is to provide all tasks for complete system cabling. This chapter will also provide instructions for the final assembly steps of side cover and door mounting installation. Orderable cables For a complete and up-to-date list of all available cables with the respective comcodes please refer to the Engineering Drawings ED8C948-10 and ED8C948-20, that you can:...
System cabling and final assembly Overview Figure 4-1 Cable block diagram PI/100 A/B ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
System cabling and final assembly Overview Table 4-1 Cable list Cable Cable Section number Power input cable (+DC) “Power wiring (External battery - PDP)” (p. 4-7) Power input cable (–DC) Office grounding cable Procedure 4-2: “Ground wiring” (p. 4-21) PI cable Procedure 4-1: “Power wiring (PDP - PI/100)”...
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System cabling and final assembly Overview Table 4-1 Cable list (continued) Cable Cable Section number Controller cable (CI-CTL – Fan) “Controller cable (CI-CTL – Fan unit)” (p. 4-28) DS3/EC1 cable “DS3/EC1 interface” (p. 4-50) Contents Power and ground cable installation Power wiring (External battery - PDP) Procedure 4-1: Power wiring (PDP - PI/100) 4-11...
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System cabling and final assembly Overview Application of attenuators 4-97 Installation of doors and side cover plates 4-98 Procedure 4-5: Side cover plates 4-99 Procedure 4-6: Rack doors 4-102 ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
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System cabling and final assembly Power and ground cable installation Overview ..............................................Purpose This section provides information about the power and ground cable installation. Contents Power wiring (External battery - PDP) Procedure 4-1: Power wiring (PDP - PI/100) 4-11 Power wiring (PI/100 - Fan unit) 4-17 Procedure 4-2: Ground wiring 4-21...
System cabling and final assembly Power wiring (External battery - PDP) ..............................................Before you begin Before connecting any power cables be sure that all circuit breakers that are located in the external Battery Distribution and Fuse Bay (BDFB) and on the rear side of the subracks (on the Power Interfaces) are in the position! Cable data...
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System cabling and final assembly Power wiring (External battery - PDP) Legend: +DC (red, return) -DC (blue) The U-bracket (connection between return and ground) has to be removed if the return wire is only grounded at the external battery (BDFB) source (e.g. valid for the USA domestic market);...
System cabling and final assembly Power wiring (External battery - PDP) Figure 4-3 Securing the power input cables Routing Please route the power input cables in the following way: In the case of ... Then ... top access route the cables (item 1) directly into the PDP. bottom access route the cables as shown in the figure below (according to *1 or *2).
System cabling and final assembly Power wiring (External battery - PDP) Figure 4-4 Routing the power input cables ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-10 See notice on first page Issue 2, June 2009...
System cabling and final assembly Procedure 4-1: Power wiring (PDP - PI/100) ..............................................Before you begin The PI/100 units can only be used when the rack is provided with 25 mm power cables. Cable data Important! The cables are prefabricated and mounted within the rack frames. Each cable (cable for side A and cable for side B) supports both subracks (upper and lower).
System cabling and final assembly Procedure 4-1: Power wiring (PDP - PI/100) In the case of ... then ... side B the PI cables, B-side (item 2), should be routed at the left-rear side of the rack frame as shown in the figure below.
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System cabling and final assembly Procedure 4-1: Power wiring (PDP - PI/100) Cable connection ........................................Remove the protection cap by unscrewing the two screws at the bottom of the protection cap........................................Remove the strain relief by unscrewing the four screws........................................
System cabling and final assembly Procedure 4-1: Power wiring (PDP - PI/100) Result: Figure 4-7 Connecting the PI cables (PI/100 / subrack side) S T E P S ....................................................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary 4-15 Issue 2, June 2009 See notice on first page...
System cabling and final assembly Procedure 4-1: Power wiring (PDP - PI/100) Pin assignment Table 4-3 Pin assignment (PI cables) Point on connector Signal name Color Ground Yellow/Green –DC Blue Return ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-16 See notice on first page Issue 2, June 2009...
System cabling and final assembly Power wiring (PI/100 - Fan unit) ..............................................Cable data The table below lists the available fan power cables. Table 4-4 Available fan power cables Cable Comcode Fan power cable, A-side 848811550 Fan power cable, B-side 848811576 Fan power cable, A-side, halogen free 848929410...
System cabling and final assembly Power wiring (PI/100 - Fan unit) Figure 4-8 Fan power cable Connector A Connector B Table 4-5 Pin assignments (fan power cables) Point on Signal name Point on Signal name connector connector Ground Ground –DC –DC +DC (rtn) +DC (rtn)
System cabling and final assembly Power wiring (PI/100 - Fan unit) Routing Figure 4-9 Routing to the fan unit ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-19 Issue 2, June 2009 See notice on first page...
System cabling and final assembly Power wiring (PI/100 - Fan unit) Figure 4-10 Routing to the PIs Important! Please check that the fan power cables are connected correctly (with the right polarity)! ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-20 See notice on first page Issue 2, June 2009...
System cabling and final assembly Procedure 4-2: Ground wiring ..............................................Required grounding Only the PDP must be grounded with the office ground as shown in the figure below. All the other parts (rack, subracks, ...) are grounded as a result of the physical mounting (physical/electrical connection of device and rack frame).
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System cabling and final assembly Procedure 4-2: Ground wiring Additional grounding (optional) Important! The cables mentioned in the procedure below are not part of the system delivery, but they can be ordered separately. If additional grounding connections are wanted (or required), you can do the following: ........................................
System cabling and final assembly Procedure 4-2: Ground wiring Result Figure 4-12 Office and subrack grounding M8x20 M5x20 ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-23 Issue 2, June 2009 See notice on first page...
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System cabling and final assembly Internal cable installation Overview ..............................................Purpose This section provides information about the intra-system cabling. Contents Cable management 4-25 Controller cable (CI-CTL – Fan unit) 4-28 Procedure 4-3: Subrack alarm wiring 4-31 Station alarm wiring 4-35 ..............................................
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Electrical cables The electrical cables listed below must be routed on both sides from the top or bottom of the 1675 LambdaUnite MSS rack frame to the subrack via the guides that are mounted on the rear of the subrack.
System cabling and final assembly Cable management Figure 4-13 Cable management (top access) Bottom access The figure below shows the cable routing for bottom access..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-26 See notice on first page Issue 2, June 2009...
System cabling and final assembly Cable management Figure 4-14 Cable management (bottom access) ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-27 Issue 2, June 2009 See notice on first page...
System cabling and final assembly Controller cable (CI-CTL – Fan unit) ..............................................Cable data The table below lists the available controller cables. Table 4-6 Available controller cables Cable Comcode Standard controller cable 848811568 Halogen free controller cable 848929428 Connector data The connector types of the controller cable are as follows: •...
System cabling and final assembly Controller cable (CI-CTL – Fan unit) Figure 4-15 Controller cable Fan unit side Controller side Table 4-7 Pin assignments (Controller cable) CI-CTL Point on Signal name Point on Signal name connector connector C Clock line C Clock line C Data line C Data line...
System cabling and final assembly Controller cable (CI-CTL – Fan unit) Routing Figure 4-16 Routing of the controller cable ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-30 See notice on first page Issue 2, June 2009...
System cabling and final assembly Procedure 4-3: Subrack alarm wiring ..............................................Cable data The table below lists the available subrack alarm cables. Table 4-8 Available subrack alarm cables Cable Comcode Length Standard cable, PDP – CI-CTL, 848811527 1100 mm upper subrack [3.609 ft] Standard cable, PDP –...
System cabling and final assembly Procedure 4-3: Subrack alarm wiring Figure 4-17 Connectors of the subrack alarm cables Table 4-9 Pin assignments (subrack alarm cables) CI-CTL Point on Signal name Point on Signal name connector connector Ground Ground Major rack-top return Major rack-top return Ground Ground...
System cabling and final assembly Procedure 4-3: Subrack alarm wiring Result Figure 4-18 Routing the subrack alarm cables (PDP side) Figure 4-19 Connections of the subrack alarm cables (PDP side) Routing (subrack side) The figure below shows the cable routing on the subrack side..............................................
System cabling and final assembly Procedure 4-3: Subrack alarm wiring Figure 4-20 Routing the subrack alarm cables (subrack side) ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-34 See notice on first page Issue 2, June 2009...
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System cabling and final assembly Station alarm wiring ..............................................Station alarms The connector of the station alarm cable consists of six isolated alarm output-pairs (Critical acoustic/visual, Major acoustic/visual and Minor acoustic/visual). If required, an external alarm equipment can be connected to this interface. Cable data Length of pre-fabricated cables, 8x2x0.4 mm / AWG 26 + overall screen: •...
System cabling and final assembly Station alarm wiring Figure 4-21 Connector of the station alarm cable Table 4-10 Pin assignment (station alarm cable) Point on connector Signal name Critical audio output Critical visual output Major audio-output return Major visual output Minor audio output Minor visual output Ground...
System cabling and final assembly Station alarm wiring Table 4-10 Pin assignment (station alarm cable) (continued) Point on connector Signal name Minor visual output return Ground Ground Routing The figure below shows the cable routing of the station alarm cable..............................................
System cabling and final assembly Station alarm wiring Figure 4-22 Routing the station alarm cable ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-38 See notice on first page Issue 2, June 2009...
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System cabling and final assembly External cable installation Overview ..............................................Purpose This section provides information about the external system cabling. NOTE: All cabling procedures described in this section are optional (customer dependent). Contents STM-1e interface 4-40 Procedure 4-4: STM-1e cable assembly instructions 4-47 DS3/EC1 interface 4-50...
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System cabling and final assembly STM-1e interface ..............................................Before you begin Due to the limited cabling space within a rack it is highly recommended to use rack extensions (see chapter 3) to be able to route the STM-1e cables properly. If the STM-1e interface paddle boards are not yet installed, mount them in the planned positions (see section below) by tightening the screws.
System cabling and final assembly STM-1e interface The cable consists of the parts listed in the table below. Table 4-11 Connector/wire technical data (Single coax cable, STM-1e) Part Comcode Connector: 408663482 1.6/5.6 coax (straight) or 1.6/5.6 coax (45°) Cable (without connector): 4.1 mm single coax with overall shield or 848068607 or 847716081 4.1 mm 8 fold coax with overall shield...
System cabling and final assembly STM-1e interface If a rack extension (width) is available, the slack should be created within the rack extension as shown in the figure below. Otherwise, the slack should be created within the left/right rack frame or above the rack (e.g. within a rack extension (height), if available).
System cabling and final assembly STM-1e interface Figure 4-26 STM-1e cabling without rack extension (width) Cabling of two subracks If two subracks are used within one rack, a rack extension (width) is required and the STM-1e cables of both subracks should be led via the rack extension to the top/bottom of the rack.
System cabling and final assembly STM-1e interface Figure 4-27 Mounting of the cable bracket Unprotected STM-1e routing Unprotected STM-1e cabling can be done only with the use of a rack extension (width). General information The STM-1e cables need to be routed loosely (with some slack) to allow service engineers to pull out an STM-1e interface paddle board without affecting traffic of an adjacent interface.
System cabling and final assembly STM-1e interface Figure 4-28 STM-1e cabling with rack extension (width) Cabling of two subracks If two subracks are used within one rack, a rack extension (width) is required and the STM-1e cables of both subracks should be led via the rack extension to the top/bottom of the rack.
System cabling and final assembly STM-1e interface Figure 4-29 Mounting of the cable bracket ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-46 See notice on first page Issue 2, June 2009...
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System cabling and final assembly Procedure 4-4: STM-1e cable assembly instructions ..............................................Description There are the following type of connectors: • IMS — type 3320.52.1420.0D5 (45°) • IMS — type 2630.52.1310.0D5 (straight) Important! Use of the correct tools to ensure a proper connection........................................
System cabling and final assembly Procedure 4-4: STM-1e cable assembly instructions Results Figure 4-30 IMS assembly procedure ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-48 See notice on first page Issue 2, June 2009...
System cabling and final assembly DS3/EC1 interface ..............................................Before you begin Due to the limited cabling space within a rack it is highly recommended to use rack extensions (see chapter 3) to be able to route the DS3/EC1 cables properly. If the ECI51 interface paddle boards are not yet installed, mount them in the planned positions by tightening the four screws (see figure below).
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System cabling and final assembly DS3/EC1 interface The following US-type cables are available: • 15 m [50 ft] DS3/EC1 cable — CC848956587 • 30 m [100 ft] DS3/EC1 cable — CC848956595 • 46 m [150 ft] DS3/EC1 cable — CC848956603 •...
System cabling and final assembly DS3/EC1 interface Figure 4-33 DS3/EC1 cabling without rack extension (width) Cabling of two subracks If two subracks are used within one rack, a rack extension (width) is required and the DS3/EC1 cables of both subracks should be led via the rack extension to the top/bottom of the rack.
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System cabling and final assembly Miscellaneous Discrete Inputs/Outputs (MDIs/MDOs) ..............................................Overview Miscellaneous Discrete Inputs and Outputs allow the network provider to use the system to monitor and control other equipment co-located with the system. For example, an MDI can be connected to monitor a temperature sensor, and an MDO can be connected to control a fan or generator.
System cabling and final assembly Miscellaneous Discrete Inputs/Outputs (MDIs/MDOs) Figure 4-34 Connector of the MDI/MDO cables Table 4-12 Pin assignment (MDI/MDO cables) Point on Signal name Point on Signal name connector connector IN 0 IN 1 IN 2 IN 3 IN 4 IN 5 IN 6...
System cabling and final assembly Miscellaneous Discrete Inputs/Outputs (MDIs/MDOs) Routing with MDIO terminal rail The figures below show the complete MDI/MDO cable routing. The first figure shows the cable routing of the MDI/MDO cables described above (subrack side). The second figure shows the cabling on the PDP or MDIO terminal rail side.
System cabling and final assembly Miscellaneous Discrete Inputs/Outputs (MDIs/MDOs) Figure 4-36 Routing via the MDIO terminal rail Legend: Shielded MDI/MDO cable → all pins should be connected to the MDIO terminal rail (one-by-one). The cable should be shortened to the appropriate length. Preferred earth connection point for the braid of the MDI/MDO cable.
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System cabling and final assembly Miscellaneous Discrete Inputs/Outputs (MDIs/MDOs) The cable routing on the subrack side is shown in Figure 4-35, “Routing the MDI/MDO cable (subrack side)” (p. 4-55). The cables that should be used are mentioned in section “Cable data” (p. 4-53).
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System cabling and final assembly User byte interfaces (G.703/V.11) ..............................................Overview The six user byte interfaces provide the user data channels. If required, an external orderwire equipment can be connected to these interfaces. There are four universal interfaces which can be used as G.703 co-directional or V.11 contra-directional interfaces.
System cabling and final assembly User byte interfaces (G.703/V.11) Figure 4-37 Connector of the user byte cables Table 4-13 Pin assignment (user byte cables) Point on Signal name V.11 G.703 connector Ground Output-Clock contra-directional co-directional Positive balanced balanced Output-Frame contra-directional co-directional Positive balanced...
System cabling and final assembly User byte interfaces (G.703/V.11) Figure 4-38 Routing the user byte cables Legend: Routing for USERBIO 1, 4 and 5. Routing for USERBIO 2, 3 and 6..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-61 Issue 2, June 2009 See notice on first page...
System cabling and final assembly TI-DS1 Station clock I/O interface (100/110 Ω) ..............................................Cable quantity One input cable and one output cable are needed for each Timing Interface (TI). Cable data (TI-DS1 output, 100/110 Ω) Length of pre-fabricated cables, shielded twisted pair 100/110 Ω + overall screen: •...
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System cabling and final assembly TI-DS1 Station clock I/O interface (100/110 Ω) Table 4-14 Pin assignment (DS1 station clock output cables, 100/110 Ω) (continued) Point on Signal name Wire Wire color *1 connector Ground Screen 6, 9 Strap Cable data (TI-DS1 input, 100/110 Ω) Length of pre-fabricated cables, shielded twisted pair 100/110 Ω...
System cabling and final assembly TI-DS1 Station clock I/O interface (100/110 Ω) Figure 4-40 Connector of the 100/110 Ω DS1 station clock input cables Table 4-15 Pin assignment (DS1 station clock input cables, 100/110 Ω) Point on Signal name Wire Wire color *1 connector Station-Clock Input Positive...
System cabling and final assembly TI-DS1 Station clock I/O interface (100/110 Ω) Figure 4-41 Routing the station clock I/O cables ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-65 Issue 2, June 2009 See notice on first page...
System cabling and final assembly TI-E1 Station clock I/O interface (120 Ω) ..............................................Cable quantity One input cable and one output cable are needed for each Timing Interface (TI). Cable data (TI-E1 Output, 120 Ω) Length of pre-fabricated cables, shielded twisted pair, 120 Ω + overall screen: •...
System cabling and final assembly TI-E1 Station clock I/O interface (120 Ω) Figure 4-44 Routing the station clock I/O cables ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-68 See notice on first page Issue 2, June 2009...
System cabling and final assembly TI-E1 Station clock I/O interface (75 Ω) ..............................................Cable quantity One input cable and one output cable are needed for each Timing Interface (TI). Cable data (TI-E1 output, 75 Ω) Length of pre-fabricated cables, coaxial 75 Ω: •...
System cabling and final assembly TI-E1 Station clock I/O interface (75 Ω) Figure 4-47 Routing the station clock I/O cables ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-71 Issue 2, June 2009 See notice on first page...
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System cabling and final assembly LAN 10/100 Base-T interface ..............................................Locations The LAN ports are positioned on the: • User Panel (LAN1): - LAN1 → CIT interface • CI-CTL (LAN2, LAN3, LAN4): - LAN2, LAN3 → Local EMS (HUB) or CIT interfaces - LAN4 →...
System cabling and final assembly LAN 10/100 Base-T interface Figure 4-48 CIT connection (LAN crossed) White/Orange White/Blue Orange Blue White/Blue White/Orange White/Green White/Green Green Green Blue Orange White/Brown White/Brown Brown Brown Table 4-20 Pin assignment (LAN cables, crossed) Point on connector Signal name Transmit-data positive Transmit-data negative...
System cabling and final assembly LAN 10/100 Base-T interface Each HUB connection uses the following pre-fabricated straight LAN cables (CAT5 with 4-wire RJ-45/RJ-45 connectors): • 10 m [32.808 ft] LAN cable — CC109155929 • 25 m [82.021 ft] LAN cable — CC109155945 •...
System cabling and final assembly LAN 10/100 Base-T interface Figure 4-51 Routing LAN2, LAN3 and LAN4 (CI-CTL) ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-75 Issue 2, June 2009 See notice on first page...
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System cabling and final assembly Fiber cabling Overview ..............................................Purpose This section provides information about the fiber cabling and routing. Note that fiber cables cannot be connected to the optical circuit packs at this moment . That should be done later (see chapter 10, section Procedure 10-1: “Connecting the fiber cables”...
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System cabling and final assembly Optical circuit packs ..............................................Application packs The following pack types are available: • OP155M • OP622 • OPLB • OP2G5, OP2G5D, OPT2G5 • OP10, OP10D • GE1/SX4, GE1/LX4 • GE10PL1/1A8. For a complete and up-to-date list of all available circuit packs with the respective comcodes please refer to the Engineering Drawings ED8C948-10 and ED8C948-20, that you can: •...
System cabling and final assembly Optical circuit packs OP155M The following figure shows the layout of the OP155M circuit pack (KFA18). Figure 4-52 OP155M layout Legend: Richco twist lock TL250 — DC1004336 (part of circuit pack delivery) Important! For this transmission unit only optical break-out cables (bundles of 12 single mode fibers) with 45°...
SFPs inserted on the parent board can be varied flexibly between 0 and 8. The remaining SFP sockets can be left empty. The 1675 LambdaUnite MSS SFPs are marked by the manufacturer, and they are checked upon insertion, in order to protect against accidental insertion of non 1675 LambdaUnite MSS specific SFPs.
System cabling and final assembly Optical circuit packs Figure 4-54 OP622 layout Legend: Richco twist lock TL250 — DC1004336 (part of circuit pack delivery) Important! For this transmission unit only optical break-out cables (bundles of 12 single mode fibers) with 45° boots must be used! OP2G5 The following figure shows the layout of the OP2G5 circuit pack (KFA12, KFA203, KFA204).
System cabling and final assembly Optical circuit packs Figure 4-55 OP2G5 layout Legend: Richco twist lock TL250 — DC1004336 (part of circuit pack delivery) OP2G5/PWDM with OM2G5/PWDM modules The following figure shows the layout of the OP2G5/PWDM board (KFA20)..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-81...
System cabling and final assembly Optical circuit packs Figure 4-56 OP2G5/PWDM with OM2G5/PWDM modules Legend: OP2G5/PWDM board Module Richco twist lock TL250 — DC1004336 (part of circuit pack delivery) OP2G5D/PAR8 with OM2G5 or OM2G5/CWDM SFP modules The modules have a transmission rate of 2.5 Gbit/s. Up to eight SFPs fit on the parent board.
System cabling and final assembly Optical circuit packs OP10 The following figure shows the layout of the OP10 board. Figure 4-57 OP10 layout Legend: Is part of the board LC connector — CC108265950 and ASSY-A1LC-BASE (BLACK) B* — CC108265950 OP10D/PAR2 with OM10 modules The following figure shows the layout of the OP10D/PAR2 board (KFA630).
System cabling and final assembly Optical circuit packs Figure 4-58 OP10D/PAR2 with OM10 modules Legend: OP10D/PAR2 board OM10 module Richco twist lock TL250 — DC1004336 (part of circuit pack delivery) OP10D/PAR2XFP with OMX10 modules The following figure shows the layout of the OP10D/PAR2XFP board (KFA632) that can accommodate two XFP modules (OMX10/10KM1 and/or OMX10/40KM1).
System cabling and final assembly Optical circuit packs Figure 4-59 OP10D/PAR2XFP layout OP10/PAR1XFP with OMX10 module The OP10/PAR1XFP board (KFA631) can accommodate one XFP module (OMX10/10KM1 or OMX10/40KM1)..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-85 Issue 2, June 2009 See notice on first page...
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System cabling and final assembly Gigabit Ethernet circuit packs ..............................................Application packs The following pack types are available: • GE1/SX4 • GE1/LX4 • GE10PL1/1A8. Cable data Important! Only the fiber cables with listed comcode (see Engineering Drawings) are allowed to be used, otherwise the proper functioning of the system cannot be guaranteed.
System cabling and final assembly Gigabit Ethernet circuit packs Figure 4-60 GE1 circuit packs Legend: Richco twist lock TL250 — DC1004336 (part of circuit pack delivery) GE10PL1/1A8 The following figure shows the layout of the GE10PL1/1A8 circuit pack with plugged dust covers.
System cabling and final assembly Gigabit Ethernet circuit packs Figure 4-61 GE10PL1/1A8 circuit pack 8x SFP 1x XFP ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-88 See notice on first page Issue 2, June 2009...
System cabling and final assembly Fiber engineering rules ..............................................Overview This section provides information related to the fiber capacity restrictions of the 1675 LambdaUnite MSS system. The number of fibers can be extended by using the rack extension (width) in combination with special fiber guides (see chapter 3). NOTE: It is highly recommended to use 1.6 mm fibers only because the use of 2 mm fibers can rapidly lead to space constraints.
System cabling and final assembly Fiber engineering rules Each standard side guide supports per quadrant • 64 fibers (2 mm) / 32 ports or • 128 fibers (1.6 mm) / 64 ports. NOTE: Enhanced side guides which are part of the rack extension kits are required if more than 128 fibers / 64 ports are available per quadrant.
Fiber engineering rules General fiber management All fiber cables must be routed within the front half of the 1675 LambdaUnite MSS rack frame and from both sides of the subrack to the top or bottom via the side guides (DC1001518, item 2) which are mounted at each corner position of the subrack. The cables are tightened with Velcro tape (DC1005002, item 3) before they enter the subrack.
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System cabling and final assembly Fiber engineering rules Legend: Cable routed to the lower subrack Routing rules/examples All break-out cables must be routed through chambers 1 and 2, the 1.6 mm fibers through chambers 3 and 4. The figures below show recommended cable dressings depending on the number of applied subracks and ports.
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System cabling and final assembly Fiber engineering rules Figure 4-66 Routing without rack extension (1 subrack) Break-out cables from rack top to upper fiber guide max. max. Fiber clip Break-out point Fiber clip to lower fiber guide Break-out point Subrack (side view) Cable slack can also be used for accommodating overlength ..............................................
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System cabling and final assembly Fiber engineering rules Figure 4-67 Routing with rack extension (1 subrack) Break-out cables Break-out cables from rack top from rack extension Subrack (side view) to upper fiber guide max. max. max. Fiber clip Break-out points max.
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System cabling and final assembly Fiber engineering rules Figure 4-68 Routing without rack extension (2 subracks) Break-out cables from rack top to upper fiber guide max. max. Fiber clip Break-out point Fiber clip to lower fiber guide Break-out point Subrack (side view) to upper fiber guide Fiber clip Break-out point...
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System cabling and final assembly Fiber engineering rules Figure 4-69 Routing with rack extension (2 subracks) Break-out cables Break-out cables from rack top from rack extension Subrack (side view) to upper fiber guide max. max. max. Fiber clip Break-out points Subrack 1 max.
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System cabling and final assembly Application of attenuators ..............................................Overview Attenuators (e.g. LC-Line Build-Out or Allwave Attenuators) can be required to ensure a correct optical power input level, which protects the circuit packs against overload. It is not mandatory to have an attenuator (e.g. LC-Line Build-Out or Allwave Attenuators) between the optical port (e.g.
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System cabling and final assembly Installation of doors and side cover plates Overview ..............................................Purpose This section describes the two final (optional) assembly steps, the side cover plate and rack door mounting. Contents Procedure 4-5: Side cover plates 4-99 Procedure 4-6: Rack doors 4-102 ..............................................
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System cabling and final assembly Procedure 4-5: Side cover plates ..............................................Before you begin The side cover plates can be mounted on each side of a stand-alone rack frame with or without rack extension, but within a rack line-up only the two outer sides of the cabinet can be covered.
System cabling and final assembly Procedure 4-5: Side cover plates Results Figure 4-70 Side cover plate mounting onto the rack frame ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 4-100 See notice on first page Issue 2, June 2009...
System cabling and final assembly Procedure 4-5: Side cover plates Figure 4-71 Side cover plate mounting onto the rack extension ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 4-101 Issue 2, June 2009 See notice on first page...
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System cabling and final assembly Procedure 4-6: Rack doors ..............................................Installation procedure Proceed as follows to install the rack doors: ........................................Place the lower hinge pin of the door in the eye of the door support bottom. The following rack doors should be used: •...
System cabling and final assembly Procedure 4-6: Rack doors Result Figure 4-72 Installing the rack doors Opening the rack doors Proceed as follows to open the rack doors: ........................................Put a finger in the hole below the door latch to lift the latch (see figure below)........................................
System cabling and final assembly Procedure 4-6: Rack doors Result Figure 4-73 Opening the rack doors Installing the rack door lock (optional) Proceed as follows to install the rack door-lock: ........................................Follow the procedure for “Opening the rack doors” (p. 4-103).
System cabling and final assembly Procedure 4-6: Rack doors ........................................Press straight in the bezel, then upwards........................................Tilt the locking module and engage the tabs into the holes in the bezel........................................Snap the locking module into place. S T E P S ........................................
Overview ..............................................Purpose This chapter describes • the powering of the 1675 LambdaUnite MSS system, ® • the WaveStar CIT and NE software installation, • the circuit pack installation, and • two final tests that should be performed to end the physical installation part.
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Destruction of components due to a supply voltage of incorrect polarity or that is too high. 1675 LambdaUnite MSS equipment operates at a nominal voltage of -48 V or -60 V. The permissible tolerance range is -40.5 V to -72 V.
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Power, software and circuit pack installation Overview Contents Procedure 5-1: Switching on and testing the supply voltage Procedure 5-2: Fan unit test ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
Power, software and circuit pack installation Procedure 5-1: Switching on and testing the supply voltage ..............................................Overview This section describes the procedure for activating the voltage supply lines via the PI/100 units. Please observe the order of the steps described below. NOTE: If “breaker-less”...
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Power, software and circuit pack installation Procedure 5-1: Switching on and testing the supply voltage The voltage on the PDP must be in the range of –40.5 { –72.0 V DC. Result: CAUTION: Do not proceed if the voltage is outside the range! ........................................
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S T E P S ........................................Breaker-less PIs (PI/100 NOCB) If “breaker-less” PIs (PI/100 NOCB) are used, the 1675 LambdaUnite MSS subrack has to be connected via an external circuit breaker to the central office power installation. The current rating of the hydraulic-magnetic circuit breaker (no thermal fuse) depends on the configuration of the subrack.
Power, software and circuit pack installation Procedure 5-1: Switching on and testing the supply voltage Figure 5-2 “Breaker-less” PIs (PI/100 NOCB) ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
Procedure 5-2: Fan unit test ..............................................Overview This test verifies the correct working of the fan unit in the 1675 LambdaUnite MSS subrack. The test should be carried out for each installed NE. Procedure Proceed as follows to test the correct functionality of the fan unit: ........................................
Power, software and circuit pack installation Procedure 5-2: Fan unit test ........................................Check the following: • All four fans are running. • The air flow direction is from bottom to top. Use the “rubber air flow baffles” to confirm the correct direction of air flow. Figure 5-4 Rubber air flow baffles ........................................
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Power, software and circuit pack installation Procedure 5-2: Fan unit test ........................................Reconnect both “POWER INPUT” cables (A and B). You can do this without switching off the power supply. The “PWR ON” LED and the “FAULT” LED should be illuminated. Result: ........................................
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Power, software and circuit pack installation Software and circuit pack installation Overview ..............................................Purpose ® This section describes the WaveStar CIT and NE software installation. It also contains a circuit pack mounting procedure and special configuration rules. Contents ® Procedure 5-3: WaveStar CIT installation 5-12 ®...
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Power, software and circuit pack installation ® Procedure 5-3: WaveStar CIT installation ..............................................Overview ® Use this procedure to install the WaveStar CIT software on a new system. NOTE: Please note that this installation procedure is only valid for the current ®...
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® Power, software and circuit pack installation Procedure 5-3: WaveStar CIT installation Required web browser ® For the User Assistance functionality of the WaveStar CIT application a “weblication” is used that displays information in HTML. Therefore the off-the-shelf browsers Netscape 4.05 (or higher) or Internet Explorer 4.02 (or higher) are recommended. The browser to be used must be set as the default browser on the personal computer on ®...
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® Power, software and circuit pack installation Procedure 5-3: WaveStar CIT installation Installation ® Complete the following steps to install the WaveStar CIT software on your PC: ........................................® Insert the WaveStar CIT CD-ROM (CC109646745) into the appropriate drive of your ........................................
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® Power, software and circuit pack installation Procedure 5-3: WaveStar CIT installation ® Result: The WaveStar CIT files are extracted. This will take a few minutes. Then Welcome to the InstallShield Wizard for WaveStar CIT window appears........................................Click to continue the installation. Next window appears.
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® Power, software and circuit pack installation Procedure 5-3: WaveStar CIT installation Click Next Important! This configuration can only be done during installation. Result: Setup Type window appears........................................Select and click WaveStar CIT Next window appears. Result: Select Components ........................................
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® Power, software and circuit pack installation Procedure 5-3: WaveStar CIT installation ........................................® To verify proper installation, double click the WaveStar CIT Icon on your desktop to start the application. S T E P S ....................................................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary 5-17 Issue 2, June 2009 See notice on first page...
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NOTE: “LUC01” and “LUC02” are pre-installed Super User logins which must be used together with the passwords “LUC+01” and “LUC+02” throughout this manual. More information related to user administration and privilege codes is given in the “1675 LambdaUnite MSS User Operations Guide” (chapters 2 and 14)........................................®...
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Power, software and circuit pack installation Procedure 5-5: NE software installation ..............................................Overview ® The software generic has to be copied from the WaveStar CIT CD-ROM to the ® ™ WaveStar CIT PC and then to an empty and pre-formatted CompactFlash card via ®...
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Step you prefer manual installation, proceed to Step ........................................Insert the 1675 LambdaUnite MSS CD-ROM with the new NE software........................................IF ... THEN ... the Welcome Screen appears, proceed to Step the Welcome Screen does not...
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Power, software and circuit pack installation Procedure 5-5: NE software installation ........................................Click the NE Software button on the right..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 5-21 Issue 2, June 2009 See notice on first page...
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Skip the following steps and proceed to section “Remove CompactFlash card from CTL” (p. 5-23)........................................Insert the 1675 LambdaUnite MSS CD-ROM with the new NE software........................................If the Welcome Screen appears, select to exit from the automatic installation Cancel procedure.
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Power, software and circuit pack installation Procedure 5-5: NE software installation ........................................Click with the right mouse button and select Start Explore ........................................® Select the hard-disk drive where the WaveStar CIT software is installed........................................Click Program Files ........................................Click , respectively (see “Installation...
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Power, software and circuit pack installation Procedure 5-5: NE software installation ™ Proceed as follows to remove the CompactFlash card from the CTL: ........................................™ Locate the Security Bar for the CompactFlash card that is located on the top edge of the CTL unit as shown below.
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Power, software and circuit pack installation Procedure 5-5: NE software installation ........................................Open the Security Bar as shown below........................................™ Push the button beside the CompactFlash card as shown below to release the ™ CompactFlash card..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 5-25 Issue 2, June 2009 See notice on first page...
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Power, software and circuit pack installation Procedure 5-5: NE software installation ........................................™ ™ Carefully remove the CompactFlash card from the CompactFlash slot. The ™ CompactFlash card should fit snugly but not require a great deal of force to remove. ™...
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Power, software and circuit pack installation Procedure 5-5: NE software installation ™ NE software installation on CompactFlash card ™ Proceed as follows to install the NE software on the CompactFlash card: ........................................™ Take the removed CompactFlash card or another Alcatel-Lucent-provided and ™...
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Power, software and circuit pack installation Procedure 5-5: NE software installation ........................................In the window, click and then in the Prepare PCMCIA Disk Copy Generic confirmation window. The file copy function starts and you see a “Copying generic files...” Result: message.
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Power, software and circuit pack installation Procedure 5-5: NE software installation ........................................™ If the CompactFlash card driver software that you are using requires you to stop the ™ CompactFlash card before ejecting it, stop the card now. If the software that you are using does not allow for this procedure, make sure that the used slot is not being accessed (the LED is not flashing for about 5 seconds) before continuing.
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Power, software and circuit pack installation Procedure 5-5: NE software installation ........................................If the screws are not loose, use a small Phillips Screw Driver to loosen the screws two turns. Do not remove the screws........................................Open the Security Bar as shown below........................................
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Power, software and circuit pack installation Procedure 5-5: NE software installation ........................................™ ™ Carefully insert the CompactFlash card into the CompactFlash slot. The ™ CompactFlash card should fit snugly but not require a great deal of force to insert........................................
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Power, software and circuit pack installation Circuit packs ..............................................Overview This section gives an overview about the available circuit packs. For a complete and up-to-date list with the respective comcodes please refer to the Engineering Drawings ED8C948-10 and ED8C948-20, that you can: •...
Power, software and circuit pack installation Circuit packs Table 5-2 Available interface modules Short Name Function Parent board Max. Max. ports ports board shelf OM10 Optical interface module OP10D/PAR2 OC-192 / STM-64 OMX10/10km1 10-Gbit/s Ethernet LANPHY GE10PL1/1A8 optical XFP interface module OP10/PAR1XFP (10 km) OP10D/PAR2XFP...
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Minimum required circuit packs The minimum recommended complement of circuit packs required for an operational 1675 LambdaUnite MSS shelf is • two switching units, one working and one protection • one controller unit (traditional applications) or two controller units, one working and one protection (ONNS functionality) •...
Power, software and circuit pack installation Circuit packs Figure 5-6 Blank front plate (3N) with empty holes — CC848840112 Legend: Hang the cables temporarily in the empty holes in the front blank when you pre-arrange the cables. NOTE: The maximum upward and downward displacement of the plastic latches shall not exceed 5 mm to avoid any destruction! ..............................................
Power, software and circuit pack installation Circuit packs 6N type Figure 5-7 Blank front plate (6N) — CC848782876 ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 5-39 Issue 2, June 2009 See notice on first page...
Power, software and circuit pack installation Configuration rules ..............................................Overview This section describes the configuration rules that must be observed. General configuration rules The following figure and table show the valid slot positions of the circuit packs looking at the subrack from the front. Figure 5-8 Slot positions of the circuit packs USRPNL Legend...
Power, software and circuit pack installation Configuration rules Gigabit Ethernet and 10-Gbit/s port units To avoid thermic stress, it is recommended not to place a 10-Gbit/s port unit directly above a Gigabit Ethernet port unit. Optical port unit protection In the case of optical port protection (1+1 Linear APS / 1+1 MSP) it is recommended to place the working port unit and the protection port unit side by side for ease of maintenance.
Power, software and circuit pack installation Configuration rules EP51/ECI51 slot assignments The table below shows the association between the EP51 slots and the slots of the rear-side ECI51 interface paddle boards. Table 5-3 Association between EP51 slots and ECI51 slots EP51 slots ECI51 slots ECI51 position...
Power, software and circuit pack installation Configuration rules The table below shows the association between the EP51 slots and the protection groups (“PROTECTION GROUP 1” or “PROTECTION GROUP 2”) of each ECI51 interface paddle board depending on its location. Table 5-4 Association between EP51 slots and ECI51 protection groups ECI51 position ECI51 slots...
Power, software and circuit pack installation Configuration rules Figure 5-11 ECI51 protection group assignment ECI51 LXC160 configuration rules These rules and guidelines apply when the of the system Maximum Switch Capacity is set to LXC160 (160 Gbit/s): 1. The maximum switching capacity of the system is 160 Gbit/s (3072 × 3072 VC-3/STS-1;...
Power, software and circuit pack installation Configuration rules 4. All cross-connection and timing units can be provisioned in slot 9 and slot 10. However, the maximum switching capacity that can be used is 160 Gbit/s, and the slot equippage rules as described above apply independent of which cross-connection and timing unit is used.
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Power, software and circuit pack installation Configuration rules LXC320 configuration rules These rules and guidelines apply when the of the system Maximum Switch Capacity is set to LXC320 (320 Gbit/s): 1. The maximum switching capacity of the system is 320 Gbit/s (6144 × 6144 VC-3/STS-1;...
Power, software and circuit pack installation Configuration rules Figure 5-13 LXC configuration rules with XC320 User panel 33 34 35 36 10 11 13 14 15 16 front view LXC640 configuration rules These rules and guidelines apply when the Maximum Switch Capacity of the system is set to (640 Gbit/s):...
Power, software and circuit pack installation Configuration rules 6. Lower order cross-connection units of type LOXC40G3S/1 (3 slots wide) can be used in the universal slots 4 and 19 (worker LOXC40G3S/1 in the slots 2/3/4, protection LOXC40G3S/1 in the slots 17/18/19). 7.
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Power, software and circuit pack installation Configuration rules Max. switching capacity Slot assignment LOXC (W) LOXC (P) Remarks and additional equipage guidelines LXC320 Option 1 The slots 3 and 18 must remain empty. Bear in mind, that the slots 2 and 17 may be required at a later date in case an in-service upgrade is planned towards LOXC units which occupy 3 slots.
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Power, software and circuit pack installation Configuration rules LXC160: User panel ( ) P 10 11 front view LXC320: User panel ( ) P 33 34 35 36 10 11 13 14 15 16 ( ) P front view ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 5-52...
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Power, software and circuit pack installation Configuration rules LXC640: User panel ( ) P ( ) P front view ONNS configuration rules A special subrack equippage is required for ONNS applications. Observe these rules and guidelines with regard to an LXC configuration supporting ONNS applications: 1.
Power, software and circuit pack installation Procedure 5-6: Mounting the circuit packs ..............................................Overview This section describes the physical mounting of the circuit packs. Safety CAUTION Subrack destruction due to insertion of damaged circuit packs or due to incorrect circuit pack insertion. Subracks can be destructed if damaged circuit packs are inserted or if circuit packs are inserted incorrectly.
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Power, software and circuit pack installation Procedure 5-6: Mounting the circuit packs Figure 5-15 Undamaged connector blocks ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 5-55 Issue 2, June 2009 See notice on first page...
Power, software and circuit pack installation Procedure 5-6: Mounting the circuit packs Figure 5-16 Undamaged/damaged EMI shields Figure 5-17 Undamaged guide headers ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 5-56 See notice on first page Issue 2, June 2009...
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Power, software and circuit pack installation Procedure 5-6: Mounting the circuit packs Insertion of circuit packs Proceed as follows to insert a circuit pack: ........................................Put the circuit pack onto the lower guiding extrusion as shown in the figure below. NOTE: The right rail of the guiding extrusion must be used.
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Power, software and circuit pack installation Procedure 5-6: Mounting the circuit packs ........................................Make sure that the latches engage the subrack latch-panel. Lock the latches of behind the circuit pack simultaneously ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 5-58 See notice on first page Issue 2, June 2009...
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Power, software and circuit pack installation Procedure 5-6: Mounting the circuit packs ........................................Check that the metal clip of each latch is visible as shown in the figure below. S T E P S ....................................................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary 5-59 Issue 2, June 2009 See notice on first page...
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Power, software and circuit pack installation Procedure 5-6: Mounting the circuit packs Blank front plate The maximum upward and downward displacement of the plastic latches shall not exceed 5 mm to avoid any destruction. Mounting order Mount the circuit packs in the following order: ........................................
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Power, software and circuit pack installation Procedure 5-6: Mounting the circuit packs ........................................Push the XC unit (protection) firmly into slot “XC P” (#10). The “Active” LED must flash after about 20 seconds. Result: Troubleshooting: If that is not the case, check that the XC unit is plugged correctly. If that does not solve the problem, replace the XC unit (protection).
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Power, software and circuit pack installation Physical installation check ..............................................Overview A complete physical installation check should be done to ensure that all components are complete and the cables are connected correctly. It should also be checked if the NE is up and running. Checks Check that •...
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E xit checklist – Part I Overview ..............................................Purpose This chapter contains the exit checklist for Part I (see next page) and a table for entering the power supply values measured in chapter 5. Contents Physical and power installation exit checklist Power supply measurements ..............................................
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Exit checklist – Part I Physical and power installation exit checklist ..............................................Verify that all procedures described below have been completed. If a procedure was not applicable, indicate “N/A”. Procedure Result Initials Notes (Passed/Completed, or N/A) Rack installed Rack extension (width) installed Rack extension (height) installed Rack adapter kit installed MDIO terminal rail installed...
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Exit checklist – Part I Power supply measurements ..............................................Measured values Feeder Measured voltage ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
Part II: NE provisioning and stand-alone installation test Overview ..............................................Purpose This part of the 1675 LambdaUnite MSS Installation Guide contains the NE provisioning and the stand-alone test procedures. Contents This part of the document contains the following chapters: • Chapter 7, NE provisioning •...
NE provisioning and stand-alone installation test Overview Procedure Completed Initials Notes Is the following test equipment available? • Optical power meter with LC connectors • SDH/SONET analyzer • Adjustable optical attenuator Contents Chapter 7, NE provisioning Chapter 8, Stand-alone test procedures Chapter 9, Exit checklist –...
This chapter describes the NE login procedure and the initial NE provisioning via ® WaveStar CIT. Assumption The person setting up the system should be familiar with 1675 LambdaUnite MSS, the ® SDH or SONET functionality and WaveStar CIT. Contents NE login ®...
NE provisioning NE login Overview ..............................................Purpose ® This section describes the NE login procedure and how WaveStar CIT has to be connected to a NE. Important! At this point in the NE turn-up only an Procedure 7-1: “NE login via OSI” (p.
® The WaveStar CIT (LAN card) is connected to the 1675 LambdaUnite MSS via the “CIT” port of the user panel or through a backplane connector (LAN I/O Panel). A shielded CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
® NE provisioning Connecting the WaveStar CIT to the NE ® WaveStar CIT LAN access (network) ® WaveStar CIT access to more than one NE can be done via a HUB. Shielded CAT5 straight LAN cables with RJ-45/RJ-45 connectors must be used for this connection. ®...
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® NE provisioning Connecting the WaveStar CIT to the NE ® Figure 7-3 WaveStar CIT access via DCC ® WaveStar CIT DCC Data Communication Channel ® WaveStar CIT access via TCP/IP ® The WaveStar CIT can be connected to NEs via TCP/IP in the following ways: •...
® NE provisioning Connecting the WaveStar CIT to the NE ® Figure 7-4 WaveStar CIT access via TCP/IP ® The following figure gives an example on conneting the WaveStar CIT through an IP network (Intranet). ® Figure 7-5 WaveStar CIT access via IP network (Intranet) IP Network ®...
NE provisioning Procedure 7-1: NE login via OSI ..............................................Overview This section describes the login procedure to an NE using an OSI connection. It is ® necessary that the WaveStar CIT is already connected to the NE (see section ® “Connecting the WaveStar CIT to the NE”...
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“UNITE+02”. NOTE: “LUC01” and “LUC02” are pre-installed Super User logins which must used throughout this manual. More information related to user administration and privilege codes is given in the “1675 LambdaUnite MSS User Operations Guide” (chapters 2 and 14). Result:...
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NE provisioning Procedure 7-1: NE login via OSI ........................................Click to connect. window appears. Result: Legal Notice ........................................Click to the legal notice. window appears for the selected NE. Result: System View S T E P S ........................................Password rules The following characters are allowed in a password: •...
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NE provisioning Procedure 7-1: NE login via OSI The following characters are not allowed in a password: • space Spaces are ignored, so they are not stored with the password, they are not evaluated for password validity and they do not count for the password length. •...
(left window column), enter the target NE Management View identifier (TID) of the NE you wish to connect in the NE Name box........................................Select “1675 LambdaUnite MSS” as NE Type ........................................For the select “TCP/IP” and click Connection Type Graphical ..............................................
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NE provisioning Procedure 7-2: NE login via TCP/IP window appears. Result: TCP/IP Configure ........................................Enter the IP address and click window appears. Result: Unite Login Dialog ........................................Log in with your User Id and Password for the NE........................................Click to connect.
NE provisioning Provisioning system parameters Overview ..............................................Purpose This section describes all provisioning tasks which should be performed to prepare the system for operation and to be able to perform some tests. Related information ® An overview about all WaveStar CIT related tasks is given in the “1675 LambdaUnite MSS User Operations Guide”.
NE provisioning Procedure 7-3: Changing the NE name (TID) ..............................................Overview This section provides a procedure for changing the NE name (TID). Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2.
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NE provisioning Procedure 7-3: Changing the NE name (TID) • Each NE name can be up to 20 characters in length. • The NE name may contain segments separated by hyphens (“-”) or slashes (“/”), but each segment must begin with a letter or number. NOTE: NE names are not case sensitive.
The Equip selection tab appears on the left side of the window........................................Select “1675 LambdaUnite MSS” in the selection tab and click Equip Provision The selection window for the system parameters appears on the right side Result: of the window.
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NE provisioning Procedure 7-4: System parameters ........................................In the group box, specify the System Settings System Interface Standard Default IF { THEN { the system will interface select . This is the default setting. predominantly with SDH If the Note: System Interface Standard Default equipment, set to...
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NE provisioning Procedure 7-4: System parameters ........................................In the group box, specify the System Settings System Synch Characteristics IF { THEN { the system shall predominantly select . This is the default setting. comply with SDH synchronization requirements, the system shall predominantly select SONET comply with SONET...
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NE provisioning Procedure 7-4: System parameters ........................................In the group box, enable or disable the Fault Management Enhanced SA/NSA Alarm Classification IF { THEN { you want to enable the enhanced mode of SA/NSA select Enable alarm classification for SNCP/UPSR rings, you want LOS and LOF alarms always to be reported select Disable...
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In the WaveStar , select System View Fault → Enter/Exit Maintenance Condition... → Exit Maintenance Condition... The 1675 LambdaUnite MSS NE will now perform a system reset (takes Result: about ten minutes). As a consequence, the management association between the ® WaveStar CIT and the NE will be lost.
NE provisioning Procedure 7-4: System parameters Screen of the Settings tab Figure 7-6 Screen of the Settings tab Elements of the Settings tab The elements of the tab and their meaning are listed in the following table. Settings Table 7-1 Elements of the Settings tab Option Meaning...
NE provisioning Procedure 7-4: System parameters Table 7-1 Elements of the Settings tab (continued) Option Meaning Used to set the synchronization characteristics for the NE by System Synch Characteristics selecting the corresponding radio button ( SONET characteristics or characteristics). This parameter basically impacts the default settings for the expected external timing reference signals, the Synchronization Status Message (SSM) handling, and the output timing mode of operation.
NE provisioning Procedure 7-5: LAN port configuration for TCP/IP access ..............................................Overview This section provides a procedure for configuring a LAN port on a 1675 ® LambdaUnite MSS NE for access from WaveStar CIT via TCP/IP or for establishing connectivity to an Element Management System (EMS). NOTE: This section can be skipped if that kind of access is not required! Required equipment Prior to performing this task, the following equipment must be available:...
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NE provisioning Procedure 7-5: LAN port configuration for TCP/IP access Procedure Proceed as follows to assign an IP address to the LAN port and enable IP-LAN for an ........................................Check that the NE is in Maintenance Condition (“Maintenance” must be indicated in red;...
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NE provisioning Procedure 7-5: LAN port configuration for TCP/IP access ........................................Select the tab and check that the is enabled. TARP TARP Originator ........................................By means of the equipment selection window, select the LAN port that will be used for TCP/IP access (“LAN lan2” or “LAN lan3”) and click Select Result: LAN Management...
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Mode box checked (see Step or “LAN lan2” is used for TCP/IP, “LAN lan3” with the Advanced the 1675 LambdaUnite MSS NE will now perform Mode box checked (see Step a controller reset (takes about three minutes). As a is used for TCP/IP, consequence, the management association between ®...
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NE provisioning Procedure 7-5: LAN port configuration for TCP/IP access The 1675 LambdaUnite MSS NE will now perform a system reset (takes Result: about ten minutes). As a consequence, the management association between the ® WaveStar CIT and the NE will be lost.
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NE provisioning Procedure 7-5: LAN port configuration for TCP/IP access ........................................Select the tab. TCP/IP Gateway ........................................Enable TCP/IP Gateway Control by clicking the respective radio button........................................Provision the TCP/IP Gateway Host List This list contains the possible management systems that may set up management associations through the T-TD gateway.
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NE provisioning Procedure 7-5: LAN port configuration for TCP/IP access ........................................Click Close S T E P S ....................................................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary 7-29 Issue 2, June 2009 See notice on first page...
NE provisioning Procedure 7-6: NE password aging ..............................................Overview For time and convenience this section provides a procedure for preventing NE password aging and inactivity timeout. Reference More information related to security administration is given in chapter 2 of the “1675 LambdaUnite MSS User Operations Guide”.
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NE provisioning Procedure 7-6: NE password aging ........................................In the area, click on Inactivity Timeout Disable ........................................Click Modify ® The WaveStar CIT warning window appears. Result: ........................................Click to confirm and return to the System View NOTE: Local or company procedures may require these timers to be restored when the NE is added to the network.
NE provisioning Procedure 7-7: NE date and time ..............................................Overview This section provides a procedure for setting the NE date and time. Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2.
NE provisioning Procedure 7-7: NE date and time ........................................Click and confirm the resulting system message by clicking S T E P S ........................................Date and Time screen Figure 7-7 Date and Time screen Elements of the Date and Time screen The elements of the Date and Time screen and their meaning are listed in the...
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NE provisioning Procedure 7-7: NE date and time Date and time recovery in case of a power failure In case of a power failure, the system is able to recover the date and time information from an internal real-time clock. A precondition however is that the active controller is of the type CTL/3S, CTL/3T, CTL/4T or CTL/4S.
NE provisioning Procedure 7-8: Mounting the CTL protection unit ..............................................Overview The procedure described below must only be performed if a second CTL unit is required (for 1+1 equipment protection). Safety CAUTION ESD hazard Electronic components can be destroyed by electrostatic discharge. Hold circuit packs only at the edges or on the insertion and removal facilities.
NE provisioning Procedure 7-9: External timing references ..............................................Overview This section provides a procedure for configuring the external timing references. Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
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NE provisioning Procedure 7-9: External timing references Proceed as follows: To disable an external timing reference, select Not Connected To enable an external timing reference, select the external timing input port associated to the respective external timing reference: • “exttmg0” is associated to Ext.
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NE provisioning Procedure 7-9: External timing references If you want the incoming SSM value of the external timing reference to be evaluated (provided that the is set to ), then select System SSM Mode QL Enable AUTO Otherwise select a specific value. For external timing interfaces which do not support SSM (2-MHz signals for example), it is recommended to select a value other than AUTO Result:...
NE provisioning Procedure 7-10: System timing ..............................................Overview This section provides a procedure for configuring the system timing. Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
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NE provisioning Procedure 7-10: System timing ........................................Enable or disable the evaluation of the Synchronization Status Message (SSM) information by selecting from the QL Enable QL Disable System SSM Mode drop-down list box. The SSM information, carried in incoming timing reference QL Enable signals, is evaluated.
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NE provisioning Procedure 7-10: System timing An “infinite” wait-to-restore time can be used in situations when enough timing references are available, and you do not want to use a timing reference again that has failed before........................................Important! It is strongly recommended to switch from the free-running mode to the locked mode as soon as valid timing references are available and assigned.
NE provisioning Procedure 7-10: System timing ........................................Click Close S T E P S ........................................System timing screen Figure 7-8 System timing screen ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 7-42 See notice on first page Issue 2, June 2009...
NE provisioning Procedure 7-11: External timing inputs ..............................................Overview This section provides a procedure for configuring the external timing inputs. Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
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NE provisioning Procedure 7-11: External timing inputs The following values are possible for SONET: • (Extended Super Frame; supports SSM) • (Super Frame) ........................................IF ... THEN ... (SDH) format is used, proceed to Step 2MHZ (SDH) format is select from the 2MBIT-FRAMED SUPPORTED...
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NE provisioning Procedure 7-11: External timing inputs ........................................Click Close S T E P S ....................................................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary 7-45 Issue 2, June 2009 See notice on first page...
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Make sure all assumptions listed below are fulfilled before carrying out any tests: • All NEs are mounted and cabled correctly (see chapters 3 and 4). • The people carrying out the tests are familiar with 1675 LambdaUnite MSS, the ®...
Stand-alone test procedures Procedure 8-1: LED test ..............................................Overview This test ensures the functionality of the LEDs on all circuit packs as well as on the User Panel. The “PWR ON” LED on the User Panel and the fan unit LEDs are not affected by the LED test.
Stand-alone test procedures Procedure 8-2: Alarm reporting tests ..............................................Overview The tests described below verify that currently active alarms of the system are reported ® to the WaveStar CIT, to the User Panel and to the rack alarm lamps that are located at the rack top (front and rear).
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Stand-alone test procedures Procedure 8-2: Alarm reporting tests ........................................® In the WaveStar System View , select Fault → NE Alarm List Reports → Alarm List to check if the “Fan Voltage Feed A Failure” alarm is reported to the ®...
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Stand-alone test procedures Procedure 8-2: Alarm reporting tests window for this port appears. The Result: Provision Parameters Equip selection tab appears on the left side of the window........................................Click Provision ........................................Set the Port Mode Monitored ........................................Click Apply and then in the confirmation window.
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Stand-alone test procedures Procedure 8-2: Alarm reporting tests ........................................Select → → and check the Fault NE Alarm List Reports NE Alarm List ® WaveStar CIT alarm list for correct clearing of the reported alarm. To make sure that the “NE Alarm List” reflects the current alarm status, click the Refresh button.
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Stand-alone test procedures Procedure 8-2: Alarm reporting tests ........................................® In the WaveStar , select → → System View Fault NE Alarm List Reports to check if the “Timing Reference Failure” alarm is reported to the Alarm List ® WaveStar CIT.
Stand-alone test procedures Procedure 8-3: NE synchronization test ..............................................Overview This test ensures protected synchronization of the NE to external clock sources. Important! The test must only be carried out for NEs with connected external clock sources. Required equipment Prior to performing this task, the following equipment must be available: ®...
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Stand-alone test procedures Procedure 8-3: NE synchronization test window appears. Result: Configure Timing/Synchronization ........................................Check that the following parameters are set for both external clock sources as given in the table below. If necessary change the parameters according to section “Provisioning system parameters”...
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Stand-alone test procedures Procedure 8-3: NE synchronization test ........................................Disconnect the first clock source. The second clock source should become active. Result: To check that, select the Timing References tab. “EXTREF2” should be displayed Reference in the Active System Timing Reference field.
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector. Always observe the laser warning instructions (cf.
Stand-alone test procedures Procedure 8-4: Optical power meter test Figure 8-1 Mean launched power test LambdaUnite STM-x/OC-x Optical power meter OP = Optical Pack Procedure Proceed as follows to check the mean launched power: ........................................Clean the output port to be tested (see appendix A, Procedure A-12: “Fiber cleaning”...
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Stand-alone test procedures Procedure 8-4: Optical power meter test ........................................Check that the measured value is within the range shown in Table 8-1, “Mean launched power ranges” (p. 8-13)........................................Repeat Step 1 Step 4 for all optical ports. S T E P S ........................................
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Stand-alone test procedures Procedure 8-4: Optical power meter test Table 8-1 Mean launched power ranges (continued) Circuit pack Comcode Wavelength Mean launched power [nm] range [dBm] OM2G5/1.5LR1 109192278 1550 –2.0 ... +2.0 (Module) OM2G5/921...959PWDM 109154658 ... 1550 –3.0 ... 0 109154971 (Modules) OM2G5/CL47S1 ...
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Stand-alone test procedures Procedure 8-4: Optical power meter test Table 8-1 Mean launched power ranges (continued) Circuit pack Comcode Wavelength Mean launched power [nm] range [dBm] OMX10/10KM1 109546838 1310 –8.0 ... +0.5 OMX10/40KM1 109546853 1550 –1.0 ... +2.0 OMX10/80KM1 109577841 1550 0 ...
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Stand-alone test procedures Procedure 8-5: Receiver sensitivity test Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)” (p. 4-73)) 3.
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Stand-alone test procedures Procedure 8-5: Receiver sensitivity test Figure 8-2 Receiver sensitivity test LambdaUnite Attenuator STM-x/ OC-x Optical power meter SDH/SONET 1) Cross-connection STM-x/OC-x analyzer OP = Optical Pack Procedure Proceed as follows to check the receiver sensitivity: ........................................Connect the output of the port to be tested with its input via an adjustable optical attenuator.
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Stand-alone test procedures Procedure 8-5: Receiver sensitivity test • (SDH) / (SONET) VC416C STS48 • (SDH) / (SONET) VC464C STS192 Please note that it is not possible to proceed to the next window before selecting the cross-connection rate........................................In the group box, select XC Application 2-Way Point-to-Point...
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Stand-alone test procedures Procedure 8-5: Receiver sensitivity test ........................................Verify that the cross-connection is established. Proceed as follows: ® 1. In the WaveStar , select System View View → Cross Connection List... 2. Select of the Shelf 1 (DUR) Ptn Grp 3.
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Stand-alone test procedures Procedure 8-5: Receiver sensitivity test appears. Result: Screen 2 ........................................Select ALL Legs of this cross-connection and click Next> appears. This window contains the parameters of the selected Result: Screen 3 cross-connection........................................Click to delete the cross-connection and confirm the resulting message by Finish clicking ........................................
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Stand-alone test procedures Procedure 8-6: DS3 transmission and protection test Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
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Stand-alone test procedures Procedure 8-6: DS3 transmission and protection test DS3 transmission test Proceed as follows to perform the DS3 transmission test: ........................................Establish an optical loop by connecting the output port of any optical circuit pack with its input........................................
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Mbit/s as signal rate. NOTE: The default DS3 signal format is “C-bit parity”. If you want to change this, please refer to chapter 4 of the “1675 LambdaUnite MSS User Operations Guide”. Result: No bit errors are present during this time.
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Stand-alone test procedures Procedure 8-6: DS3 transmission and protection test IF ... THEN ... no further DS3 ports have to be Skip the following steps and proceed to section tested and a DS3 protection test “DS3 protection test” (p. 8-29). shall be performed, ........................................
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Stand-alone test procedures Procedure 8-6: DS3 transmission and protection test DS3 protection test Important! This test should only be performed if DS3 1+1 equipment protection is used. Make sure that the configuration rules given in chapter 5, section “DS3/EC1 equipment protection rules” (p. 5-42) are fulfilled for the DS3 port unit (EP51/EL36 or EP51/EL36B) to which the transmission analyzer is connected (via the associated ECI51/MP72 paddle board).
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Stand-alone test procedures Procedure 8-6: DS3 transmission and protection test The active DS3 port unit is marked with “(A)” (active side) in the Result: ® WaveStar , the standby DS3 port unit is marked with “(S)” System View (standby side)........................................
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Stand-alone test procedures Procedure 8-6: DS3 transmission and protection test ........................................® In the WaveStar , select System View Configuration → Cross-Connection → to delete the established cross-connection. Delete appears. Result: Screen 1 ........................................Click the Equip tab on the left........................................
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Stand-alone test procedures Procedure 8-7: Optical port transmission test (daisy chain test) Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
Stand-alone test procedures Procedure 8-7: Optical port transmission test (daisy chain test) Figure 8-4 Daisy chain test ® WaveStar CIT LambdaUnite User panel Rx Tx Optical loops SDH/SONET STM-x/OC-x analyzer OP = Optical Pack Procedure Proceed as follows to perform the port transmission test: ........................................
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Stand-alone test procedures Procedure 8-7: Optical port transmission test (daisy chain test) ........................................In the group box, select XC Application 1-Way Point-to-Point ........................................Click the left Select button to select the source tributary. selection tab appears. Result: Ptn Grp ........................................Select one port in the list or enter the AID in the Enter AID text box above.
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Stand-alone test procedures Procedure 8-7: Optical port transmission test (daisy chain test) ........................................Before starting a signal transmission check that the optical output power of the SDH/SONET analyzer is not too high. The allowed power input ranges for all optical circuit packs are given in Table 10-1, “Power input ranges of the optical circuit packs”...
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Stand-alone test procedures Procedure 8-7: Optical port transmission test (daisy chain test) ........................................Click Close S T E P S ...................................................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary 8-37 Issue 2, June 2009 See notice on first page...
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Stand-alone test procedures Procedure 8-8: XC and CTL protection test Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
Stand-alone test procedures Procedure 8-8: XC and CTL protection test Figure 8-5 XC and CTL protection test LambdaUnite 2xCTL 2xXC 1) Cross-connection 2) Optical loop SDH/SONET OP = Optical Pack STM-x/OC-x analyzer XC = Switching matrix XC protection test Proceed as follows to perform the XC protection test: ........................................
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Stand-alone test procedures Procedure 8-8: XC and CTL protection test ........................................In the group box, select XC Application 2-Way Point-to-Point ........................................Click the left Select button to select the source tributary. selection tab appears. Result: Ptn Grp ........................................Select the port to which the SDH/SONET analyzer is connected. Result: In the Tributary...
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Stand-alone test procedures Procedure 8-8: XC and CTL protection test ........................................Click Close ........................................Before starting a signal transmission check that the optical output power of the SDH/SONET analyzer is not too high. The allowed power input ranges for all optical circuit packs are given in Table 10-1, “Power input ranges of the optical circuit packs”...
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Stand-alone test procedures Procedure 8-8: XC and CTL protection test After about two minutes the following must be observed: • The “Active” LEDs on all I/O packs and the active CTL are permanently illuminated. • The “Active” LED and the “Fault” LED on the “XC unit (active)” are extinguished.
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Stand-alone test procedures Procedure 8-8: XC and CTL protection test NOTE: In the following the removed CTL unit will be called “CTL unit (active)”. The following can be observed: Result: • A switch to the standby CTL unit is caused without affecting traffic. ®...
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Stand-alone test procedures Procedure 8-8: XC and CTL protection test window appears. Result: Switch Protection ........................................Select 1+1 Equipment ectlgrp in the Ptn Grp tab on the left-hand side of the window and click the Select button........................................From the drop-down list box, select Switch Type Manual To Working...
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Stand-alone test procedures Procedure 8-8: XC and CTL protection test In the list box on the right the existing cross-connection that shall be Result: deleted is displayed........................................Select this cross-connection and click Next> Result: Screen 2 appears........................................Select of this cross-connection and click ALL Legs Next>...
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E xit checklist – Part II Overview ..............................................Purpose This chapter contains the exit checklist for Part II (see next page) and a table for entering the optical output power values measured in chapter 8. Contents NE provisioning and stand-alone installation test exit checklist Optical output power measurements ..............................................
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Exit checklist – Part II NE provisioning and stand-alone installation test exit checklist ..............................................Verify that all procedures described below have been completed. If a procedure was not applicable, indicate “N/A”. Procedure Result Initials Notes (Passed/Completed, or N/A) NE login performed NE name (TID) provisioned System parameters provisioned NE LAN port for TCP/IP access...
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Exit checklist – Part II Optical output power measurements ..............................................Measured values NOTE: If required, please make copies of the following table. Slot Circuit pack Port Mean launched Receiver number number power [dBm] sensitivity [dBm] ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
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Exit checklist – Part II Optical output power measurements Slot Circuit pack Port Mean launched Receiver number number power [dBm] sensitivity [dBm] ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
Overview ..............................................Purpose This part of the 1675 LambdaUnite MSS Installation Guide contains the physical network installation, the network provisioning, and the network test procedures related to a ring configuration. Contents This part of the document contains the following chapters: •...
Network establishment and testing Overview Procedure Completed Initials Notes Is a CAT5 crossover LAN cable with RJ-45/RJ-45 connectors available (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)” (p. 4-73))? Is the following test equipment available? • Optical power meter with LC connectors •...
Network establishment and testing Overview ..............................................Purpose This chapter describes all steps that are required for establishing the network and the tests that should be carried out to check the functionality of the overall system. Contents Network establishment 10-3 Procedure 10-1: Connecting the fiber cables 10-4 Procedure 10-2: Provision DCC 10-12...
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Network establishment and testing Overview Procedure 10-15: Optical port provisioning for SCN 10-84 Procedure 10-16: DCC provisioning for SCN 10-86 ® Procedure 10-17: Launching the WaveStar CIT ONNS application for 10-88 the first time ONNS test 10-91 Procedure 10-18: Path creation test 10-95 Procedure 10-19: Path restoration test 10-98...
Network establishment and testing Network establishment Overview ..............................................Purpose This section provides a procedure for establishing a network via fiber connections from NE to NE. Furthermore, it describes the required network provisioning that must be done before performing the tests. Assumption The people carrying out the procedures described below are familiar with the ®...
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-1: Connecting the fiber cables Required equipment Prior to performing this task, the following equipment must be available: 1. Optical power meter – Range: –35 ... +20 dBm – Wavelength: 1310 nm/1550 nm 2. ESD Wrist Strap. Prerequisites Prior to performing this task, all used optical ports and connectors must be clean.
Network establishment and testing Procedure 10-1: Connecting the fiber cables The detection interval is • for STM-1: 700 sec. for a BER threshold of 10 78 sec. for a BER threshold of 10 • for STM-4: 188 sec. for a BER threshold of 10 21 sec.
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Network establishment and testing Procedure 10-1: Connecting the fiber cables Procedure Proceed as follows to establish a protected ring configuration: ........................................Connect an optical fiber to the NE-A OUT port of the optical circuit pack to be used in this test........................................
Network establishment and testing Procedure 10-1: Connecting the fiber cables Optical input power ranges The following table provides the allowed value range of the received optical power as well as the wavelength ranges of the optical circuit packs. Table 10-1 Power input ranges of the optical circuit packs Circuit pack Comcode...
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Network establishment and testing Procedure 10-1: Connecting the fiber cables Table 10-1 Power input ranges of the optical circuit packs (continued) Circuit pack Comcode Wavelength [nm] Allowed range [dBm] OM2G5/CL47L1 ... 109496794 ... 1471 ... 1611 –28.0 ... –9.0 OM2G5/CL61L1 109496869 (Modules) OP622/1.3IR16...
Network establishment and testing Procedure 10-1: Connecting the fiber cables Figure 10-4 AllWave LC and SC attenuators Safety CAUTION Destruction of AllWave attenuators caused by mechanical overload. Putting too much of a mechanical load on the AllWave attenuators will cause the destruction of the attenuators.
Network establishment and testing Procedure 10-2: Provision DCC ..............................................Overview Use this procedure to create new DCC (Data Communication Channel) terminations. This is necessary for exchanging network management information between NEs and performing the network establishment procedures described in this chapter as well as the tests described in chapter “Test procedures”...
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Network establishment and testing Procedure 10-2: Provision DCC Procedure Important! Only ports to which fiber cables are connected should be configured for DCC terminations! Proceed as follows to create a new DCC termination: ........................................® Connect the WaveStar CIT PC to NE-A and perform an NE login as described in chapter 7, section Procedure 7-1: “NE login via OSI”...
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Network establishment and testing Procedure 10-2: Provision DCC ........................................In the group box, select (Acknowledged Information DCC Channel Parameters AITS Transfer Service) or (Unacknowledged Information Transfer Service) as UITS LAPD Mode Important! If the LAPD mode of a DCC channel is set to AITS a modification of the LAPD role will raise a DCC Fail alarm for some seconds.
Network establishment and testing ® Procedure 10-3: WaveStar CIT remote login test via DCC ..............................................Overview The test ensures the accessibility to all NEs via a DCC remote login. Safety CAUTION ESD hazard Electronic components can be destroyed by electrostatic discharge. Always observe the ESD instructions (cf.
Proceed as follows to perform a remote login test: ........................................Start a remote login to NE-B. To do that, enter the following: • The TID of NE-B as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type Click Graphical ..............................................
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® Network establishment and testing Procedure 10-3: WaveStar CIT remote login test via All units of NE-B will be displayed. Result: If a remote login is not possible, please refer to appendix A, section Reference: Procedure A-9: “Remote login failure” (p. A-16).
Network establishment and testing Procedure 10-4: Line timing test setup ..............................................Overview This section provides the information needed to set up the line timing test (see section Procedure 10-9: “Line timing test” (p. 10-51)). Safety CAUTION ESD hazard Electronic components can be destroyed by electrostatic discharge. Always observe the ESD instructions (cf.
Network establishment and testing Procedure 10-4: Line timing test setup Test setup Figure 10-6 Line timing test setup NE-B (Line timing) Rx Tx Rx Tx TI-A IN External clock NE-C NE-A sources TI-B IN (External timing) (Line timing) NE-D (Line timing) OP = Optical Pack Checking the external timing references Proceed as follows to check the external timing references in NE-A:...
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Proceed as follows to configure the line timing references in NE-B, NE-C and NE-D: ........................................Start a remote login to NE-B. To do that, enter the following: • The TID of NE-B as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type Click Graphical ..............................................
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Network establishment and testing Procedure 10-4: Line timing test setup All units of NE-B will be displayed. Result: ........................................® In the WaveStar System View , select Configuration → Timing/Synchronization Result: Configure Timing/Synchronization window appears with the active Timing References tab.
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Network establishment and testing Procedure 10-4: Line timing test setup Note the following for Step • NE-C: Select the port that is connected to NE-B. • NE-D: Select the port that is connected to NE-C. S T E P S ........................................
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-5: 1+1 MSP/APS test setup Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
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Network establishment and testing Procedure 10-5: 1+1 MSP/APS test setup Test setup Figure 10-7 1+1 MSP/APS test setup Creating a 1+1 MSP/APS protection group Proceed as follows to create the required 1+1 MSP/APS protection group: ........................................® Connect the WaveStar CIT PC to NE-A and perform an NE login as described in chapter 7, section Procedure 7-1: “NE login via OSI”...
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Network establishment and testing Procedure 10-5: 1+1 MSP/APS test setup On the right side of the window the protection parameter fields for the Result: selected shelf appear........................................Select in the Protection Type drop-down list box the type 1+1 MSP (SDH) or (SONET).
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Network establishment and testing Procedure 10-5: 1+1 MSP/APS test setup To do that, enter the following: • The TID of NE-B as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type NOTE: In Step 6 select “Port #2 OP2G5 #2”...
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Network establishment and testing Procedure 10-5: 1+1 MSP/APS test setup In the list box on the right, the AIDs of all STSs belonging to Result: Tributary the respective port are displayed........................................Select the STS which shall be used as the source and click the Select button.
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-6: 2-fiber MS-SPRing/BLSR test setup Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
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Network establishment and testing Procedure 10-6: 2-fiber MS-SPRing/BLSR test setup Test setup Figure 10-8 2-fiber MS-SPRing/BLSR test setup Fiber loop Rx Tx East West NE-B West East Rx Tx Rx Tx SDH/SONET 2F-MS-SPRing/BLSR NE-C NE-A STM-x/OC-x analyzer East West NE-D West East OP = Optical Pack...
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Network establishment and testing Procedure 10-6: 2-fiber MS-SPRing/BLSR test setup window appears. Result: Create New Protection Group ........................................Select the shelf in the Ptn Grp selection tab and click Select I/O Shelf On the right side of the window the protection parameter fields for the Result: selected shelf appear.
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NEs in the ring via remote login. To do that, enter the following: • The NE TID as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type To verify that the MS-SPRing/BLSR setup is correct perform the steps mentioned below.
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Network establishment and testing Procedure 10-6: 2-fiber MS-SPRing/BLSR test setup ........................................Click the button and check that there are no “Ring Protection Switch Alarm List Suspended” alarms........................................Repeat Step 17 Step 22 for all other NEs within the ring. S T E P S ........................................
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Network establishment and testing Procedure 10-6: 2-fiber MS-SPRing/BLSR test setup In the list box on the right, the AIDs of all VCs/STSs belonging Result: Tributary to the respective port are displayed........................................Select the VC/STS which shall be used as the source and click the Select button.
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-7: 4-fiber MS-SPRing/BLSR test setup Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)”...
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Network establishment and testing Procedure 10-7: 4-fiber MS-SPRing/BLSR test setup Test setup Figure 10-9 4-fiber MS-SPRing/BLSR test setup Fiber loop Rx Tx East West NE-B East West Rx Tx Rx Tx Rx Tx Rx Tx SDH/SONET 4F-MS-SPRing/BLSR NE-C NE-A STM-x/OC-x analyzer East West...
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Network establishment and testing Procedure 10-7: 4-fiber MS-SPRing/BLSR test setup ........................................® In the WaveStar , select System View Configuration → Create New → Protection Group... window appears. Result: Create New Protection Group ........................................Select the shelf in the Ptn Grp selection tab and click Select I/O Shelf Result:...
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NEs in the ring via remote login. To do that, enter the following: • The NE TID as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type To verify that the MS-SPRing/BLSR setup is correct perform the steps mentioned below.
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Network establishment and testing Procedure 10-7: 4-fiber MS-SPRing/BLSR test setup ........................................Check that the field displays RING Node APS (Automatic Protection Switch) State “Idle”........................................Click Close ........................................Click the button and check that there are no “Ring Protection Switch Alarm List Suspended”...
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Network establishment and testing Procedure 10-7: 4-fiber MS-SPRing/BLSR test setup selection tab appears. Result: Ptn Grp ........................................Select the port to which the SDH/SONET analyzer is connected. In the list box on the right, the AIDs of all VCs/STSs belonging Result: Tributary to the respective port are displayed.
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-8: SNCP/UPSR test setup Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)” (p. 4-73)) 3.
Network establishment and testing Procedure 10-8: SNCP/UPSR test setup Ring setup Figure 10-10 SNCP/UPSR test setup Fiber loop Rx Tx Working path Protection path NE-B Rx Tx Rx Tx SDH/SONET NE-C NE-A SNCP/UPSR STM-x/OC-x analyzer NE-D OP = Optical Pack 1) Cross-connections Creating cross-connections Proceed as follows to create the required cross-connections:...
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Network establishment and testing Procedure 10-8: SNCP/UPSR test setup window appears. Result: Create New Cross Connection ........................................Select/Activate the Signal Auto Rate Set check box and define the cross-connection rate in the Rate drop-down list box according to the analyzer signal used. The following values are possible: •...
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Network establishment and testing Procedure 10-8: SNCP/UPSR test setup ........................................Set the Protection Type • For a UPSR select • For an SNCP you can select (using non-intrusive monitoring or (using SNCN SNCI inherent monitoring). SNCI protection, generally, protects against failures in the server layer. The protection process and the defect detection process are performed by two adjacent layers.
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Network establishment and testing Procedure 10-8: SNCP/UPSR test setup To do that, enter the following: • The TID of NE-B as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type NOTE: • Select the port that is connected to NE-C as port (Path 1).
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Network establishment and testing Procedure 10-8: SNCP/UPSR test setup In the list box on the right, the AIDs of all VCs/STSs belonging Result: Tributary to the respective port are displayed........................................Select the VC/STS which shall be used as the source and click the Select button.
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Network establishment and testing Test procedures Overview ..............................................Purpose This section describes all the network tests that should be carried out to check the functionality of the system. Contents Procedure 10-9: Line timing test 10-51 Procedure 10-10: 1+1 MSP/APS test 10-54 Procedure 10-11: 2-fiber MS-SPRing/BLSR test 10-59...
Proceed as follows to perform the line timing test: ........................................Start a remote login to NE-B. To do that, enter the following: • The TID of NE-B as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type Click Graphical All units of NE-B will be displayed.
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Network establishment and testing Procedure 10-9: Line timing test window appears with the active Result: View Timing/Synchronization tab. Timing References ........................................Select the System Timing tab. Result: The following must be displayed: • Locked in the Clock Mode field. • Normal in the System Clock mode Status...
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Network establishment and testing Procedure 10-9: Line timing test ........................................Click Close ........................................Repeat Step 10 Step 12 for NE-C and NE-D........................................Re-install the external clock source that has been removed in Step 6 to NE-A........................................® In the WaveStar of NE-A, select System View View →...
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-10: 1+1 MSP/APS test 3. SDH/SONET analyzer The required transmission rate depends on the circuit packs used. The optical circuit pack with the lowest transmission rate determines the required transmission rate of the analyzer. For the test setup mentioned below an STM-16/OC-48 analyzer is required because OP2G5 circuit packs are used.
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Network establishment and testing Procedure 10-10: 1+1 MSP/APS test An immediate switch to the “Protection” line and a short traffic Result: interruption of about 10 ms is caused........................................Select the Switch Status tab and click Refresh Result: “Protection (AID#)” will be indicated as the Active Port ........................................
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Network establishment and testing Procedure 10-10: 1+1 MSP/APS test ........................................Check that “Protection (AID#)” is indicated as the Active Port NOTE: After the defined WTR time (1 minute) a switch back to the “Working” line and a short traffic interruption of about 10 ms is caused. You can verify this by clicking the button again.
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Network establishment and testing Procedure 10-10: 1+1 MSP/APS test appears. This window contains the parameters of the selected Result: Screen 3 cross-connection........................................Click Finish to delete the cross-connection and confirm the resulting message by clicking ........................................Click Close ........................................Repeat Step 1 Step 7...
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-11: 2-fiber MS-SPRing/BLSR test 3. SDH/SONET analyzer The required transmission rate depends on the optical circuit packs used within the ring. The optical circuit pack with the lowest transmission rate determines the transmission rate which should be used for the test. For example, if OP2G5 and OP10 circuit packs are used, an STM-16/OC-48 transmission signal is required.
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Step 8 for all other NEs within the ring via remote login. To do that, enter the following: • The NE TID as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type Note the following for Step •...
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Network establishment and testing Procedure 10-11: 2-fiber MS-SPRing/BLSR test window appears. Result: Protection Switch ........................................Select the existing 2F MS-SPRing# (SDH) or 2F BLSR# (SONET) in the Ptn Grp on the left-hand side of the window and click the Select button.
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Network establishment and testing Procedure 10-11: 2-fiber MS-SPRing/BLSR test Note the following for Step • NE-B: “Switching” will be displayed in the RING Node APS (Automatic field. Protection Switch) State • NE-C and NE-D: “Passthrough” will be displayed in the RING Node APS field.
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Network establishment and testing Procedure 10-11: 2-fiber MS-SPRing/BLSR test appears. Result: Screen 1 ........................................Click the Equip tab on the left........................................Expand the tree of the circuit pack to which the SDH/SONET analyzer is connected and select the respective port. In the list box on the right the existing cross-connection that shall be Result: deleted is displayed.
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-12: 4-fiber MS-SPRing/BLSR test 3. SDH/SONET analyzer The required transmission rate depends on the optical circuit packs used within the ring. The optical circuit pack with the lowest transmission rate determines the transmission rate which should be used for the test. For example, if OP2G5 and OP10 circuit packs are used, an STM-16/OC-48 transmission signal is required.
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Step 8 for all other NEs within the ring via remote login. To do that, enter the following: • The NE TID as NE Name • 1675 LambdaUnite MSS as NE Type • OSI as Connection Type Note the following for Step •...
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Network establishment and testing Procedure 10-12: 4-fiber MS-SPRing/BLSR test window appears. Result: Switch Protection ........................................Select the existing 4F MS-SPRing# (SDH) or 4F BLSR# (SONET) in the Ptn Grp on the left-hand side of the window and click the Select button.
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Network establishment and testing Procedure 10-12: 4-fiber MS-SPRing/BLSR test Note the following for Step • NE-B: “Switching” will be displayed in the RING Node APS (Automatic field. Protection Switch) State • NE-C and NE-D: “Passthrough” will be displayed in the RING Node APS field.
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Network establishment and testing Procedure 10-12: 4-fiber MS-SPRing/BLSR test appears. Result: Screen 1 ........................................Click the Equip tab on the left........................................Expand the tree of the circuit pack to which the SDH/SONET analyzer is connected and select the respective port. In the list box on the right the existing cross-connection that shall be Result: deleted is displayed.
Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Procedure 10-13: SNCP/UPSR test 3. SDH/SONET analyzer The required transmission rate depends on the optical circuit packs used within the ring. The optical circuit pack with the lowest transmission rate determines the transmission rate which should be used for the test. For example, if OP2G5 and OP10 circuit packs are used, an STM-16/OC-48 transmission signal is required.
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Network establishment and testing Procedure 10-13: SNCP/UPSR test “Protection” will be indicated as the path. Result: Active ........................................Re-install the fiber connection between NE-A and NE-B. After the defined WTR time (1 minute) a switch back to the “Working” Result: path and a short traffic interruption of about 15 ms is caused.
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Network establishment and testing Procedure 10-13: SNCP/UPSR test ........................................Select the existing in the tab on the left-hand side of the Path Protection Ptn Grp window and click the button. Select ........................................Check that “Protection” is indicated as the Active path.
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Network establishment and testing Procedure 10-13: SNCP/UPSR test ........................................Select the existing in the tab on the left-hand side of the Path Protection Ptn Grp window and click the button. Select ........................................Check that “Working” is indicated as the Active path.
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Network establishment and testing Procedure 10-13: SNCP/UPSR test appears. This window contains the parameters of the selected Result: Screen 3 cross-connection........................................Click Finish> to delete the cross-connection and confirm the resulting message by clicking ........................................Click to exit the window.
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Network establishment and testing Procedure 10-13: SNCP/UPSR test ........................................Click to exit the window. Close Delete Cross Connection ........................................Repeat Step 10 Step 17 for NE-D. NOTE: In Step 13 select the port which is connected to NE-A. S T E P S ........................................
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Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Overview Assumed network configuration Analyzer 2 STM-x Rx Tx NE-C Rx Tx Rx Tx NE-D NE-B WaveStar CIT NE-A STM-x Analyzer 1 OP = Optical Pack Required equipment The following equipment must be available: ® 1. WaveStar CIT PC 2.
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Network establishment and testing Overview Prerequisites Make sure all assumptions listed below are fulfilled before carrying out any ONNS procedures: 1. Two ONNS controllers (CTL/2, CTL/3S or CTL/4S) and two cross-connects (XC160, XC320/B or XC640) are used (duplex control is recommended for ONNS) 2.
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® In the WaveStar , select → System View Administration Data Communications... Result: Data Communications window appears........................................Select “1675 LambdaUnite MSS” and click Select ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary 10-81 Issue 2, June 2009 See notice on first page...
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The selection tab appears on the left side of the window. Equip ........................................Select “1675 LambdaUnite MSS” and click Provision Result: The selection window for the system parameters appears on the right-hand side of the window. This window consists of two tabs,...
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Network establishment and testing Procedure 10-14: Setting the IP address and ONNS system parameters of the SCN nodes The 1675 LambdaUnite MSS NE will now perform a system reset. As a Result: ® consequence, the management association between the WaveStar CIT and the NE will be lost.
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Network establishment and testing Procedure 10-15: Optical port provisioning for SCN ..............................................Purpose This section provides a procedure for preparing a transmission port for ONNS applications. Required equipment Prior to performing this task, the following equipment must be available: ® 1.
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Network establishment and testing Procedure 10-15: Optical port provisioning for SCN An additional tab labelled is displayed in the port provisioning Result: ONNS window. Port classes: Additional information • iNNI ports interface to other iNNI ports and connect one ONNS node to another ONNS node within an autonomous system.
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Network establishment and testing Procedure 10-16: DCC provisioning for SCN ..............................................Purpose This section provides a procedure for creating new DCC terminations for SCN and enabling the ONNS auto-discovery function. Required equipment Prior to performing this task, the following equipment must be available: ®...
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Network establishment and testing Procedure 10-16: DCC provisioning for SCN ........................................Enable the by selecting the option in the SCN Termination Enabled SCN Channel group box and click Parameters ........................................Repeat Step 3 Step 6 for all other iNNI ports........................................
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Network establishment and testing ® Procedure 10-17: Launching the WaveStar CIT ONNS application for the first time ..............................................Purpose ® This section provides a procedure for launching the WaveStar CIT ONNS application for the first time. Required equipment Prior to performing this task, the following equipment must be available: ®...
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® Network establishment and testing Procedure 10-17: Launching the WaveStar CIT ONNS application for the first time The new will appear in the field. Result: Alias ........................................Click and then in the confirmation window. The new configuration will be saved and the screen Result: Edit Configuration...
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® Network establishment and testing Procedure 10-17: Launching the WaveStar CIT ONNS application for the first time A pop-up message will appear informing you that all other functionality Result: will be disabled until the node movement option has been disabled........................................
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Safety DANGER Laser hazard 1675 LambdaUnite MSS systems operate with invisible laser radiation. Laser radiation can cause considerable injuries to the eyes. Never look into the end of an exposed fiber or into an open optical connector as long as the optical source is switched on. Always observe the laser warning instructions (cf.
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Network establishment and testing Overview Required equipment Prior to performing this task, the following equipment must be available: ® 1. WaveStar CIT PC 2. CAT5 crossover LAN cable with RJ-45/RJ-45 connectors (see chapter 4, Figure 4-48, “CIT connection (LAN crossed)” (p. 4-73)) Prerequisites This test can only be done after each NE has been prepared for ONNS (see section...
Network establishment and testing Overview Test setup Figure 10-11 ONNS test setup Analyzer 2 STM-x Rx Tx NE-C Rx Tx Rx Tx NE-D NE-B WaveStar CIT NE-A STM-x Analyzer 1 OP = Optical Pack Contents Procedure 10-18: Path creation test 10-95 Procedure 10-19: Path restoration test 10-98...
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Network establishment and testing Overview Procedure 10-21: 1+1 protection test 10-100 ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 10-94 See notice on first page Issue 2, June 2009...
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Network establishment and testing Procedure 10-18: Path creation test ..............................................Purpose This test provides a procedure for testing the automatic connection setup via ONNS. Procedure Proceed as follows to create a path between NE-A and NE-C via NE-B and NE-D: ........................................
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Network establishment and testing Procedure 10-18: Path creation test ........................................Select in the group box via the drop-down list box the port to which Source Port “analyzer 1” is connected........................................Select in the Source group box via the Trib drop-down list box the desired tributary.
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Network establishment and testing Procedure 10-18: Path creation test disappears. The Result: Explicit Routing Node List Selection Dialog Path field is populated with the selected managed elements........................................Click Result: Create New Path screen disappears and the Network Map will display the configured path (highlighted in green).
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Network establishment and testing Procedure 10-19: Path restoration test ..............................................Purpose This test provides a procedure for testing the automatic path restoration function of ONNS. Procedure Proceed as follows to perform the test: ........................................Remove the fiber connection between NE-C and NE-D. The existing path between NE-A, NE-B, NE-D and NE-C disappears after Result: a few seconds.
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Network establishment and testing Procedure 10-20: Path deletion test ..............................................Purpose This test provides a procedure for testing the “path tear-down” functionality of ONNS. Procedure Proceed as follows to delete the connection between NE-A and NE-C: ........................................Select → → from the map’s menu View View Paths...
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Network establishment and testing Procedure 10-21: 1+1 protection test ..............................................Purpose This test provides a scenario for testing the ONNS 1+1 protection. Creation of paths Two paths must be created for a 1+1 protection. Proceed as follows to create the first path between NE-A, NE-D and NE-C, and the second (protection) path between NE-A, NE-D, NE-B and NE-C: ........................................
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Network establishment and testing Procedure 10-21: 1+1 protection test ........................................Select in the group box via the drop-down list box the desired Destination Trib tributary........................................Select in the Protection Type drop-down list box........................................Select in the group box. Bidirectional Direction ........................................
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Network establishment and testing Procedure 10-21: 1+1 protection test The SCN IP addresses of NE-D and NE-B will appear in the Result: Selected list. Nodes ........................................Click Result: Explicit Routing Node List Selection Dialog disappears. The Path 2 field is populated with the SCN IP addresses of NE-D and NE-B........................................
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Exit checklist – Part III Overview ..............................................Purpose This chapter contains the exit checklist for Part III (see next page) and a signoff sheet to make sure that all required tasks described in this manual have been done. Contents Network establishment and testing exit checklist 11-2 Completion form 11-3...
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Exit checklist – Part III Network establishment and testing exit checklist ..............................................Verify that all procedures described below have been completed. If a procedure was not applicable, indicate “N/A”. Procedure Result Initials Notes (Passed/Completed, or N/A) Fiber connection established DCC provisioned Remote login test performed Timing test performed 1+1 MSP/APS test performed...
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Exit checklist – Part III Completion form ..............................................® Document Title: LambdaUnite MultiService Switch (MSS) Installation Guide Identification No.: Issue No.: Date: Location Information All chapters have passed successfully: Start Date: Completion Date: Station Location: Country: Participants Names (printed) Company Customer Acceptance Signature Please read and sign the statement below: I have witnessed and/or accepted the successful installation...
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Appendix A: Installation troubleshooting Overview ..............................................Purpose This chapter provides basic installation troubleshooting information for the 1675 LambdaUnite MSS system. Contents Procedure A-1: Power failure Procedure A-2: Fan unit test failure Procedure A-3: NE synchronization failure Procedure A-4: CTL failure Procedure A-5: CTL protection test failure A-10 Procedure A-6: XC protection test failure...
Installation troubleshooting Procedure A-1: Power failure ..............................................Overview The procedures described below should be performed if the subrack powering procedure was unsuccessful. Procedure 1 must be used if the measured voltage at the termination blocks of the PDP does not lie between -40.5 and -72 V. Procedure 2 must be used if the “PWR ON”...
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Installation troubleshooting Procedure A-1: Power failure ........................................Replace all affected shelf power cables between the PDP and the power connectors of the Power Interfaces. Make sure that the cables are tight afterwards........................................Switch all circuit breakers on the subrack backplane to the ON position (=“I”). IF ...
Installation troubleshooting Procedure A-2: Fan unit test failure ..............................................Overview The procedure described below should be performed if one of the following failures can be observed: • The “PWR ON” LED does not light up on the fan unit. Procedure 1 must be used in this case. •...
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Installation troubleshooting Procedure A-2: Fan unit test failure Procedure 2 Proceed as follows if not all fans are running or if the air flow direction is not from bottom to top: ........................................Switch all circuit breakers on the subrack backplane (see chapter 5, Figure 5-1, “PI/100 switching”...
Installation troubleshooting Procedure A-3: NE synchronization failure ..............................................Overview The procedure described below should be performed if no valid timing reference signal is received at the respective external synchronization input (see chapter 8, section Procedure 8-3: “NE synchronization test” (p. 8-8)).
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Installation troubleshooting Procedure A-3: NE synchronization failure ........................................Replace the currently active Timing Generator Unit. IF ... THEN ... the NE does not synchronize to the proceed to Step 5. external clock source, the NE synchronizes to the END OF STEPS external clock source, ........................................
Installation troubleshooting Procedure A-4: CTL failure ..............................................Overview The procedure described below should be performed if a CTL failure occurs (see chapter 5, section Procedure 5-6: “Mounting the circuit packs” (p. 5-54), Step Procedure Proceed as follows in the case of a CTL failure: ........................................
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Installation troubleshooting Procedure A-4: CTL failure 4. Press CTRL+A. 5. Move the mouse over the selected folders, click the right mouse button and select Delete ........................................IF ... THEN ... the failure is not solved, proceed to Step 5. the failure is solved, END OF STEPS ........................................
Installation troubleshooting Procedure A-5: CTL protection test failure ..............................................Overview The procedure described below should be performed if the LED behavior described in chapter 8, section “CTL protection test” (p. 8-43), steps 1 and 2) cannot be observed. Procedure Proceed as follows in the case of a CTL protection test failure: ........................................
Installation troubleshooting Procedure A-6: XC protection test failure ..............................................Overview The procedure described below should be performed if the LED behavior described in chapter 8, section “XC protection test” (p. 8-40), steps 17 and 18) cannot be observed. Procedure Proceed as follows in the case of an XC protection test failure: ........................................
Installation troubleshooting Procedure A-7: Circuit pack alarm handling ..............................................Overview The procedure described below should be performed if the “Fault” LED is flashing on ® one or more circuit packs or if circuit pack alarms are displayed in the WaveStar alarm list after a system reset.
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Installation troubleshooting Procedure A-7: Circuit pack alarm handling A circuit pack reset is performed. Result: ........................................After about two minutes the “Active” LED must be illuminated. Click the Alarm List button and check that there are no alarms related to the reset circuit pack. IF ...
Installation troubleshooting Procedure A-8: LED test failure ..............................................Overview The procedure described below should be performed if some LEDs do not light up during an LED test (see chapter 8, section Procedure 8-1: “LED test” (p. 8-2)). Procedure Proceed as follows in the case of an LED test failure: ........................................
Installation troubleshooting Procedure A-8: LED test failure Figure A-2 User Panel screws ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary A-15 Issue 2, June 2009 See notice on first page...
Installation troubleshooting Procedure A-9: Remote login failure ..............................................Overview The procedure described below should be performed if no remote login is possible (see ® chapter 10, section Procedure 10-3: “WaveStar CIT remote login test via DCC” 10-15)). Procedure Proceed as follows in the case of a remote login failure: ........................................
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Installation troubleshooting Procedure A-9: Remote login failure ........................................™ Perform a reload of the NE software to the CompactFlash card of the near-end NE (see Procedure 5-5: “NE software installation” (p. 5-19)). IF ... THEN ... a remote login is not possible, proceed to Step 5.
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Installation troubleshooting Procedure A-9: Remote login failure IF ... THEN ... a remote login is possible, END OF STEPS ........................................Replace the CTL unit of the far-end NE. S T E P S ...................................................................................... Alcatel-Lucent - Proprietary 365-374-179R10.0 A-18 See notice on first page Issue 2, June 2009...
Procedure Proceed as follows in the case of active alarms: ........................................Note all active alarms........................................Follow the trouble clearing tasks described in the “1675 LambdaUnite MSS Alarm Messages and Trouble Clearing Guide”. S T E P S ......................................................................................
Installation troubleshooting Procedure A-11: Switching off an NE ..............................................Overview ™ In order to avoid damage to the NE database stored on the CompactFlash card, it is of great importance to follow a special procedure for switching off an NE. Procedure Proceed as follows to switch off an NE: ........................................
Installation troubleshooting Procedure A-12: Fiber cleaning ..............................................Overview This procedure describes the Alcatel-Lucent recommended method for the cleaning and inspection of optical connectors using specific tools and materials that have been proven to be effective in the assembly and testing of optical transmission equipment. It is critical that the connector endfaces are clean and free from particular contamination to assure proper performance and reliability of lightwave systems.
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Installation troubleshooting Procedure A-12: Fiber cleaning Connectors If impurities are discovered, the optical connector must be cleaned in accordance with the following rules: ........................................Wipe off the connector face lengthwise (not with a circular motion!) using a smooth tissue (moistened with isopropanol)........................................
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Installation troubleshooting Procedure A-12: Fiber cleaning Important! Lightguide Build-Outs (LBOs) may be damaged when compressed air is used for drying. Therefore, do not use compressed air for drying LBOs. S T E P S ...................................................................................... 365-374-179R10.0 Alcatel-Lucent - Proprietary A-23 Issue 2, June 2009 See notice on first page...
Installation troubleshooting Procedure A-13: Replacing LC-type LBOs ..............................................Overview This chapter provides a procedure for replacing LC-type LBOs. Procedure Proceed as follows to replace LC-type LBOs: ........................................Depress both beams (upper and lower) simultaneously and remove the LBO........................................Insert the new LBO until a small “click” is heard. Pay attention to the correct direction as shown in the figure below.
Installation troubleshooting Procedure A-14: Removing the SFP modules ..............................................Overview The procedures described below provide removal instructions for the following SFP types: • MSA latch (type 1) • MSA latch (type 2) • Bail latch “bottom up” (= type 1) •...
Installation troubleshooting Procedure A-14: Removing the SFP modules Figure Figure A-4 Unlocking a MSA latch (type 1) SFP MSA latch (type 2) Proceed as follows to remove this type of SFP: ........................................Put the fibers away from the transceiver........................................Press on top of the locking device (see figure below) and pull the SFP out with your fingers.
Installation troubleshooting Procedure A-14: Removing the SFP modules Figure Figure A-5 Unlocking a MSA latch (type 2) SFP Bail latch (type 1) Proceed as follows to remove this type of SFP: ........................................Put the fibers away from the transceiver........................................Move the bail downwards (see figure below).
Installation troubleshooting Procedure A-14: Removing the SFP modules Figure Figure A-6 Unlocking a bail latch (type 1) SFP Bail latch (type 2) Proceed as follows to remove this type of SFP: ........................................Put the fibers away from the transceiver........................................Move the bail upwards (see figure below).
Appendix B: Passive WDM (OEM equipment) Overview ..............................................Purpose This appendix provides the relevant facts about the passive WDM (PWDM/CWDM) equipment. Contents Hardware items Technical data Procedure B-1: Carrier mounting Arrangements Cabling B-10 ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
Passive WDM (OEM equipment) Hardware items ..............................................Material For a complete and up-to-date list of all passive WDM hardware items with the respective comcodes please refer to the Engineering Drawings ED8C948-10 and ED8C948-20, that you can: • find appended at the end of this document, correct at the time of going to print (if they were ordered from the Customer Information Center (CIC)) •...
Passive WDM (OEM equipment) Technical data ..............................................Specifications Table B-1 DWDM/CWDM specifications Item Range/Size Operating temperature –5°C to +60°C Dimensions (DWDM carrier, 378 mm [14.882”] x 498 mm [19.606”] x 74 mm [2.913”] DxWxH) Dimensions (CWDM carrier, 265 mm [10.433”] x 439.5 mm [17.303”] x 43 mm [1.693”] DxWxH) ..............................................
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Passive WDM (OEM equipment) Procedure B-1: Carrier mounting ..............................................Before you begin The DWDM and CWDM carriers can be mounted into all ETS 300 119-3 compliant racks (e.g. ETSI-2 or NEBS-2000). The position within the rack should be below the DCM carrier (if used at all) or below the lowest subrack.
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Passive WDM (OEM equipment) Procedure B-1: Carrier mounting ........................................Slide the DWDM (item 3) into the shell holder until the DWDM locks. The DWDM can be released by pushing the buttons on each side simultaneously........................................Mount the bracket (DC1005065, item 4) and fiber clip (DC1000680, item 5) in a position that is close to the passive DWDM so that the cables are laid properly within the racks.
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Passive WDM (OEM equipment) Procedure B-1: Carrier mounting Ground wire (2000 mm [6.562 ft]) — CC848828174 or ground wire (3000 mm [9.843 ft]) — CC848828182 CWDM installation The CWDM installation must be done similar to the DWDM installation. The type of rack frame defines the type of the mounting brackets and their mounting positions.
Passive WDM (OEM equipment) Procedure B-1: Carrier mounting Figure B-2 CWDM carrier with label Side label CWDM carrier Mounting bracket (Position for ETSI-2 or NEBS-2000 rack) (Top view) Fiber management area ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
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Passive WDM (OEM equipment) Cabling ..............................................Cables Important! Only the fiber cables with listed comcode (see Engineering Drawings) are allowed to be used, otherwise the proper functioning of the system cannot be guaranteed. The optical cables that are used for the passive WDM on the DMUX/MUX connector plate should connect with the following connectors: •...
DCM (OEM equipment) Procedure C-1: DCM mounting ..............................................Dimensions The DCM carrier has the following dimensions: 500 mm [19.685”] x 304.5 mm [11.988”] x 259 mm [10.197”] (WxHxD). Installation procedure Proceed as follows to mount the DCM carrier: ........................................Install the mounting brackets (item 2) to the DCM carrier (item 1) as shown in the figure below.
DCM (OEM equipment) DCM arrangements ..............................................Layout Figure C-2 Arrangements of the DCM pack positions ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary Issue 2, June 2009 See notice on first page...
DCM (OEM equipment) DCM cabling ..............................................Cables Important! Only the fiber cables with listed comcodes (see Engineering Drawings) are to be used, otherwise the proper functioning of the system can not be guaranteed. The optical cables that are used for the DCM modules should have an LC connector with a 45°...
DCM (OEM equipment) DCM module interface Figure C-5 STG CPL Fiber storage method Determine the distance (A and B) between the reel entrance and the two connection interfaces of the fiber end. Loop half of the fiber storage length through the reel, but keep the distance relationship of A and B close together.
Overview ..............................................Purpose This appendix provides instructions for mounting a 1675 LambdaUnite MSS subrack together with one or two 1663 ADMu subrack(s) within one ETSI-2 rack. NOTE: It is highly recommended to use a rack extension (width) for this application (see chapter 3, section Procedure 3-4: “Rack extension (width)”...
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Mixed configuration: 1675 LambdaUnite MSS and 1663 Overview ADMu Result D-15 ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
Mixed configuration: 1675 LambdaUnite MSS and 1663 ADMu Procedure D-1: Mounting the 1663 ADMu PDP ..............................................Location The 1663 ADMu PDP (CC848862330) must be mounted at the front side of the rack. Procedure Proceed as follows to mount the PDP: ........................................
Mixed configuration: 1675 LambdaUnite MSS and 1663 Procedure D-1: Mounting the 1663 ADMu PDP ADMu Result Figure D-1 Fixing the 1663 ADMu PDP Figure D-2 Mounted PDP ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
Mixed configuration: 1675 LambdaUnite MSS and 1663 ADMu Procedure D-2: Mounting the 1663 ADMu subrack(s) ..............................................Before you begin The procedure below describes the mounting of the 1663 ADMu subrack(s). A maximum of two subracks can be mounted, one at the front and one at the back side of the rack.
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Mixed configuration: 1675 LambdaUnite MSS and 1663 Procedure D-2: Mounting the 1663 ADMu subrack(s) ADMu Result Figure D-3 1663 ADMu subrack mounting 87.5mm 275mm 175mm 300mm 87.5mm ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
Mixed configuration: 1675 LambdaUnite MSS and 1663 ADMu Procedure D-3: Mounting a fan unit ..............................................Before you begin The procedure described below (“Fan unit mounting”) must only be performed if an additional fan unit is required (2 fan units in one 1663 ADMu subrack). In that case the additional fan unit (CC848862355) and an additional filter (CC848904108) must be ordered separately.
Mixed configuration: 1675 LambdaUnite MSS and 1663 Procedure D-3: Mounting a fan unit ADMu Result Figure D-4 Fan unit mounting ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
Procedure D-4: Mounting the airguide ..............................................Before you begin The airguide (CC848920534) described below prevents air flow from the MADM subrack into the 1675 LambdaUnite MSS subrack. It is part of the mixed configuration kit (CC848914271). Procedure Proceed as follows to mount the airguide: ........................................
Procedure D-5: Mounting the 1675 LambdaUnite MSS subrack ..............................................Procedure Proceed as follows to mount the 1675 LambdaUnite MSS subrack: ........................................Temporarily remove the front mounting brackets (DC1003774, item 1 and DC1003775, item 2) from the subrack. The rear brackets should not be removed.
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Mixed configuration: 1675 LambdaUnite MSS and 1663 Procedure D-5: Mounting the 1675 LambdaUnite MSS ADMu subrack ........................................IF ... THEN ... a rack extension (width) proceed with the next step. is not used a rack extension (width) is used mount the special fiber guides (see chapter 3, section “Mounting of special fiber guides”...
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Mixed configuration: 1675 LambdaUnite MSS and 1663 Procedure D-5: Mounting the 1675 LambdaUnite MSS ADMu subrack Result Figure D-6 1675 LambdaUnite MSS subrack mounting ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 D-12 See notice on first page Issue 2, June 2009...
Mixed configuration: 1675 LambdaUnite MSS and 1663 ADMu Procedure D-6: Mounting the circuit breakers ..............................................Procedure Proceed as follows to mount the circuit breakers (CC700158603): ........................................Plug all required 20 A circuit breakers (item 1) in the circuit breaker holder of the PDP as shown in the figure below.
Mixed configuration: 1675 LambdaUnite MSS and 1663 ADMu Procedure D-7: Mounting the anti-recirculation plate ..............................................Procedure Proceed as follows to mount the anti-recirculation plate (CC848914180): ........................................Fasten the anti-recirculation plate (item 1) to the cable guide brackets (items 2 and 3) using the two M4x10 screws, which are also part of the mixed configuration kit (CC848914271), as shown in the figures below.
Mounting positions The figure below shows the result of the described mounting procedures and provides information about the positions of the screws. Figure D-10 Mounting positions (1675 LambdaUnite MSS and 1663 ADMu) ETSI-2 Rack Anti Recirculation Plate 1675 LambdaUnite MSS...
Overview ..............................................Purpose This appendix provides instructions for mounting a 1675 LambdaUnite MSS subrack together with one 1665 DMX (High Capacity) subrack within one NEBS-2000 rack. For establishing this application an orderable mounting kit (CC848856514) is needed which contains the following parts: •...
Otherwise there is a risk that the shelf will be put out of shape and that it will not be possible to insert the XC circuit packs in the slots. Proceed as follows to mount the 1675 LambdaUnite MSS subrack: ........................................
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Mixed configuration: 1675 LambdaUnite MSS and 1665 Procedure E-1: Mounting the 1675 LambdaUnite MSS DMX (High Capacity) subrack ........................................Mount the front mounting brackets (with mounted fiber clips) loosely on the subrack using M4x8 screws (DC1002976, item 7)........................................Mount the subrack on the front rack frame using M6x16 screws (CC901331421, item 4) with 7 ±...
Mixed configuration: 1675 LambdaUnite MSS and 1665 Procedure E-1: Mounting the 1675 LambdaUnite MSS DMX (High Capacity) subrack Result Figure E-2 Mounting the subrack ..............................................Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
Mixed configuration: 1675 LambdaUnite MSS and 1665 DMX (High Capacity) Procedure E-2: Mounting the heat baffle ..............................................Purpose The heat baffle is necessary to lead the heated air out of the rack. Mounting Proceed as follows to mount the heat baffle: ........................................
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Mixed configuration: 1675 LambdaUnite MSS and 1665 DMX (High Capacity) ® Procedure E-3: Mounting the Metropolis DMX (High Capacity) subrack ..............................................Procedure ® Proceed as follows to mount the Metropolis DMX (High Capacity) subrack: ........................................There is a switch on the fan controller board. The switch is labeled “CF ALM ON”...
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........................................Place the anti-recirculation plate (DC1006435, item 1) at the rack rear side between the rack bottom and the 1675 LambdaUnite MSS subrack. Important! The top of the anti-recirculation plate must partly be placed into the airinlet of the 1675 LambdaUnite MSS subrack.
Mixed configuration: 1675 LambdaUnite MSS and 1665 Procedure E-4: Mounting the anti-recirculation plate DMX (High Capacity) Figure E-4 Mounting the anti-recirculation plate S T E P S ...................................................................................... Alcatel-Lucent - Proprietary 365-374-179R10.0 See notice on first page Issue 2, June 2009...
..............................................Mounting positions The figure below shows the result of the described mounting procedures and provides information about the positions of the screws. Figure E-5 Mounting positions (1675 LambdaUnite MSS and 1665 DMX) NEBS-2000 Rack 1665 DMX Subrack (High Capacity)
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Glossary ..............................................AID (Access Identifier) A technical specification for explicitly naming entities (both physical and logical) of an NE using a grammar comprised of ASCII text, keywords, and grammar rules. Alarm Severity An attribute defining the priority of the alarm message. The way that alarms are processed depends on the severity.
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Glossary The CE marking indicates that the products conform to relevant European Community (EC) Directives CH SCR Cheese Head Screw Channel A sub-unit of transmission capacity within a defined higher level of transmission capacity. CI-CTL Customer Interface of the Controller Circuit A set of transmission channels through one or more network elements that provides transmission of signals between two points, to support a single communications path.
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Glossary fiber. DCMs are necessary for very-long-haul applications and high bit rates. Data Communications Network DCrtn Direct Current return Default An operation or value that the system or application assumes, unless a user makes an explicit choice. Disassembly Splitting up a signal into its constituents as payload data and overhead (an indication of the direction of a signal).
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Glossary Electrostatic Discharge Electrostatic Protection ETSI European Telecommunications Standards Institute ..............................................Free Running An operating condition of a clock in which its local oscillator is not locked to an internal synchronization reference and is using no storage techniques to sustain its accuracy.
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Glossary Hardware Hertz ..............................................Input/Output IAO LAN Intraoffice Local Area Network Identifier International Electrotechnical Commission IEEE Institute of Electrical and Electronics Engineers Receive Insert To physically insert a circuit pack into a slot, thus causing a system initiated restore of an entity into service and/or creation of an entity and associated attributes.
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Glossary transmits data at a very rapid speed. LAPD (Link Access Procedure D-bytes) Protocol used on Data Link Layer (OSI layer two) according to ITU-T Q.921. LBO (Lightguide Build-Out ) An attenuating (signal-reducing) element used to keep an optical output signal strength within desired limits.
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Glossary Multi-Mode Fiber Multiplexer Section Millisecond MS-SPRing (Multiplexer Section Shared Protection Ring) A protection method used in Add/Drop Multiplexer Network Elements. MSP (Multiplexer Section Protection) Provides a capability for switching a signal from a working section to a protection section..............................................
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Glossary between network elements. The words “port” and “line” may often be used synonymously. “Port” emphasizes the physical interface, and “line” emphasizes the interconnection. Either may be used to identify the signal being carried. Printed Wiring Board PWDM Passive Wavelength Division Multiplexing Power PWR ON Power On...
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Glossary partitioning of the network, and trouble-shooting. Receive/IN ..............................................Signaling Communication Network Screw SDH (Synchronous Digital Hierarchy) A hierarchical set of digital transport structures, standardized for the transport of suitable adapted payloads over transmission networks. SDH Equipment Clock Small Form Factor Pluggable Slot A physical position in a shelf designed for holding a circuit pack and connecting it to the backplane.
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Glossary Span An uninterrupted bidirectional fiber section between two network elements. Station Clock Input An external clock may be connected to a Station Clock Input. Synchronous Transport Module (SDH) STM-N (Synchronous Transport Module, Level N) A building block information structure that supports SDH section layer connections, where N represents a multiple of 155.52 Mbit/s.
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Glossary ..............................................The UL marking indicates that the products conform to relevant American Directives. User Panel UPSR Unidirectional Path-Switched Ring The UR marking indicates that the products conform to relevant American Directives. User Privilege Permissions that a user must have on the computer system on which the system software runs.
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Glossary ..............................................Cross Connect ..............................................365-374-179R10.0 Alcatel-Lucent - Proprietary GL-13 Issue 2, June 2009 See notice on first page...
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Index Numerics APS test setup, 10-24 Ground wiring, 4-21 1+1 MSP test setup, 10-24 Attenuators, 10-6 LAN cables, 4-72 1+1 APS test setup, 10-24 MDI/MDO cables, 4-53 ............. 1+1 MSP protection group, Network cabling, 10-5 Barred-hand symbol, 1-20 10-25 OP10 circuit pack, 4-82 Battery Distribution and Fuse 1+1 APS protection group,...