RBS 2206 Testing for Engineer

RBS 2206 Testing & Maintenance

ASP Assistance Center Training Sehari

�EID/Z/I- 05:xxx Uen Rev PA1 �Limited Internal �2005-08-19�2

Training Agenda

� ASP Licensing Flow Process� RBS 2206/2106 Hardware Overview� RBS Acceptance Form

RBS 2206/2106 Hardware Overview


Licensing Process Flow


RBS 2206� Indoor design� Temperature: +5°C up to +40°C� Size: 1850 x 600 x 400 mm� Weight: 230 kg� Power Input: 110-230 VAC, -72--39 VDC , +24 VDC� External power backup with up to 8h of battery backup� Power Consumption: max 3200/5700 W with AC Voltage� Transmission 75/120/100 ohm� Capacity of 12 transceivers� GSM 800, GSM 900, GSM 1800 or GSM 1900� Output power: max 45,5 dBm 900 MHz, 44,5 dBm 1800

MHz� Sensitivity –111,5 dBm� 16 External alarm inputs� Optical indicators on the door on early versions only


RBS 2106� Outdoor Cabinet� Temperature (-33°C up to +45°C)� Size: 1617 x 1300 x 925 mm� Weight: 685 kg with batteries� AC Input Power: max 6600W, 230 VAC� Transmission 75/120/100 ohm� Capacity of 12 transceivers� GSM 800, GSM 900, GSM 1800 or

GSM 1900� Output power: 45 dBm 900 MHz, � 44 dBm 1800 MHz� Sensitivity –111 dBm� Weatherproof/vandalproof design� Integrated 1 hour power backup

or external battery cabinet, optional� 16 External alarm inputs, optional


RBS 2106 RBS 2206

RBS 2106/2206 Replaceable Unit Overview


C

X

U

Mains Supply

PSU

BFU

Batteries

FCU

Fans

EPC Bus

CDU

CDU

CDU

dTRU

dTRU

dTRU

dTRU

dTRU

dTRU

RBS 2206 Hardware overview

Y

LINK

OMT

Interface

PCM A

PCM B

PCM C

PCM D

External Alarms

(16)

DXU

21

ESB

(TG Sync)


Y

LINK

C

X

U

CDU

CDU

CDU

dTRU

dTRU

dTRU

dTRU

dTRU

dTRU

OMT

Interface

PCM A

PCM B

PCM C

PCM D

External Alarms

(16)

DXU

21

ESB

(TG Sync)

Mains Supply

PSU

BFU

Batteries

FCU

Fans

ACCU

Air Conditioning

AC Connection Box

EPC Bus

RBS 2106 Hardware overview


� Ready for EDGE� High throughput (max 13Mb/s)� Replaces Timing Bus, Local Bus and X Bus� Point-to-point interface between DXU & TRUs� Based on LVDS, Low Voltage Differential Signalling)

interface� Backplane connector on DXU with compatibility

of 2102/2202 cabinets� Each dTRU has two Y links (one for each

transciver)� Each Y link is divided into two interfaces:

� Y1: TX control data� TX burst data (X Bus data)

� Y2: Traffic data UL & DL� O&M Data� Timing

Y 7-12

Y 1-6

Y-Links


• Optical Cable Bus

• Replaces Power Communication Loop

• Connects DXU to PSU’s, BFU and FCU for RBS 2206

• Connects DXU to PSU’s, BFU, FCU, A/C and ACCU for RBS 2106

• Bitrate min. 40 Kb/s

• Advanteges: provides galvanic isolation between unitsprotected from EMI

Environment & Power Control BusEPC Bus


CDU-Tx ControlBus A

CDU-Tx ControlBus B

CDU-Tx ControlBus C

IOM Bus A

IOM Bus B

IOM Bus C

C

X

U

1

C

X

U

2

O

X

U

5

OXU 4

OXU 3

OXU 2

OXU 1

Backplane

(Cabinet)

Memory

DXU

21

dTRU

dTRU

dTRU

dTRU

dTRU

dTRU

CDU

CDU

CDU

CDU Buses


•Consists of 2 Buses: CDU-TX Control Bus and IOM Bus

CDU-TX Control Bus• one RS-485 interface

• Links CDU with dTRUs

• Sends VSWR measurements

• Responsible for Combiner Control (CDU F)

IOM Bus• Consists of three I2C Interfaces

• Links DXU, CDUs, CXU, OXUs as well as Backplane (Cabinet) memory

• Responsible for RX supervision in CDUs, including temperature, LED, cable & LNA supervision in CDU

• Responsible for crossconnection & cable supervision in CXU

CDU Bus


• 4 fans located on the top of the cabinet

• One FCU (Fan Control Unit)

• Temperature sensors in DXU, TRU, CDU & PSU

• Climate supervision performed by DXU

• fans 1 & 2 cool DXU-PSU rack

• fans 3 & 4 cool CDUs and dTRUs

• Normal and Desired Temperature Range

Climate System RBS 2106


• 4 fans located on the top of the cabinet

• One FCU (Fan Control Unit)

• Temperature sensors in DXU, TRU, CDU & PSU

• Climate supervision performed by DXU

• All fans work together, but:

� fans 1 & 4 mainly cool DXU-PSU rack

� fans 2 & 3 mainly cool CDUs and dTRUs

• Normal and Desired Temperature Range

Climate System RBS 2206


• allows to synchronize up to 2 RBSes to work in the same cell•1/1 frequency network

Transceiver Group Synchronisation


• The transmission interface:- Supporting four 2 Mbit E1 or 1.5Mbit T1 ports- Total Capacity of up to 8 Mbit/s Abis transmission

• Removable Flash Card for easy load of BTS SW• Support for External Synchronization Bus, ESB• Built in indoor EC-functionality(No need for ECU in RBS 2x06)• HW Prepared to support EDGE modulation on up to 12 TRXs

Distribution Switch Unit, DXU 21


DXU 21 Block diagram


• Two transceivers in one unit of the same size as thecurrent single TRU• Two versions, one for GMSK only and one for 8-PSK (EDGE) and GMSK• Four versions with frequency bands GSM 800, E-GSM 900, GSM 1800, or GSM 1900• Built in by-passable hybrid for TX combiningtogether with CDU-G• Supports Software Power Boost•Automatic selection of correct ciphering algorithm A5/1 or A5/2• HW Prepared to support:

- Extended Range (2 slot, 121 km) - Four-branch RX Diversity

Double Transceiver Unit, dTRU


dTRU Block Diagram


CDU F


• FC – Filter Combiner

• CC – Combiner Controller

• MR – Measurement Receiver

• DPX – Duplex Filter

• CNU – Combiner Network Unit

• MCU – Measurement CouplerUnit

• LNA – Low Noise Amplifier

• RxBP – Rx Band Pass Filter

• TxLP – Tx Low Pass Filter

CDU F


CDU G


CDU G


• Frequency independent• Distributes RX from the CDUs to the dTRUs• Built up with SW controlled switches• Makes it possible to expand and reconfigure a RBS 2x06without moving or replacing any RX cables, almost.• Only one set of RX cables to cover all configurations• Only one type of CXU to cover all configurationswith CDU-F, CDU-G

Connection Switch Unit, CXU


CXU 10 Block Diagram


• Maximum 5 OXUs• OXU 1-4 located in the DXU-PSU rack• OXU 5 is the Antenna Sharing Unit above the CXUs• OXUs:

• TMA CM (Control Module)• 2 card DXX (max 8 PCM ports)• 1 card DXX (max 4 PCM ports)• MiniDXC (5 PCM ports)• ASU (Antenna Sharing Unit)

Optional eXpansion Units, OXU


Input voltage 120 – 250 VPower Consumption 1446 VA MaxHeat Generation246 W

PSU AC


PSU AC Block Diagram


Input voltage –72 – 39 VPower Consumption 1411 WHeat Generation211 W

PSU DC


PSU DC Block Diagram


RBS 2206 Connection Fields


Alternating Current Connection UnitACCU


Direct Current Connection UnitDCCU


Internal Distribution Module, IDM


6.6 kW6.0 kW

Max. power consumption(without active cooler)

200-250 V AC

Power supply voltageRBS 2106 cabinet

(fully equipped)

50A32A

Fuse Rating, 1 phase3 phase

RBS 2106 Power Consumption


RBS 2106 Power System


2.7 kW3.2 kW3.9/5.7 kW

Maximum power consumption

+24 V DC-48 V DC230 V AC

Power supply voltageRBS 2206 cabinet(fully equipped)

200A4 x 35 A4 x 16AFuse Rating

RBS 2206 Power Consumption


230 V AC

+24 V DC

-48 V DC

RBS 2206 Power Supply Connection


RBS 2206 Power System


� The Battery Backup System will consist of one or more racks depending on the number or RBS Cabinets and necessary backup time

Battery Backup SystemBBS 2000


BBS 2000 Connections• Two, + & -, 95/150 mm²battery cables between the BBS and RBS

•Two optical cables between BFU and RBS for control purposes


BFU - 22 BFU - 21Battery Fuse Units, BFU


• BFU controls the battery system by:

• Measuring battery voltage and current

• Measuring battery temperature

• Measuring RBS load voltage

• BFU will disconnect the batteries from the RBS when:

• Battery voltage drops below 21.0 V or,

• Battery temperature rises above 65 °C (149F)

• BFU will disconnect the batteries from the TM when:

• Battery voltage drops below 20.8 V

• BFU will reconnect the batteries when:

• System voltage rises above 25.5 V and,

• Battery temperature falls below 55 °C (131F)

•These settings are possible to change with the OMT!

Battery Fuse Unit, BFU


Battery Backup operating

Antenna Configuration


3x2 or 3x4 Configuration 3x2 or 3x4 Configurationdd TMA used

CDU G


• 4 TRX/cell configuration

• Maximum 3 cells in one RBS(2+2+2 or 4+4+4)

CXU


1x8 Configuration1x8 Configurationdd TMA used

CDU G



• Maximium 2 cells in one RBS(8+4+0 or 4+8+0)

CXU


1x12 Configuration

1x12 Configurationdd TMA used

CDU G



• Maximium 1 cells in one RBS(12+0+0)

CXU


2x6 Configurationdd TMA used2x6 Configuration

CDU G



• Maximium 2 cells in one RBS(6+6+0)

CXU


CDU G Cable Wirings

RBS Acceptance Form


RBS 2206 Acceptance Test

SITE DATASITE NAME : DATE OF ACCEPTANCE :

Acceptance from Contractor to CNI Excelcom

SITE NUMBER : Handover from CNI to Field Operations

SITE ADDRESS : Acceptance from Vendor to FOPs Excelcom

RADIO BASE STATION1 Type & Serial Number of RBS : Eng.Design(NBWO)

2 CDU Type : Eng.Design(NBWO)

3 Number of Cabinet : Eng.Design(NBWO)

4 Installed TRU Configuration :5 Operated TRU Configuration :

Any difference specification, please refer to Engineering Design or NBWO

Document No. : FRM/NFOP/100001

ACCEPTANCE TEST PROCESS FORM

Type of Equipment + Serial Number (on every * mark)

RADIO BASE STATION

Ericsson BaseCamp

AB1234Jl. Metro Pondok Indah Blok BA.

18 August 2005

��

RBS 2206 – Serial NumberCDU-G

1 unit4+4+44+4+4

Kel. Gandaria Utara Kec. Kebayoran baru JakSel 12310


RBS 2206 Hardware

� RBS type � RBS 2206, 2202, 2106, 2309, etc.� CDU type � CDU-F, CDU-G, CDU C+, CDU-J� Installed TRU config. � TRU installed on cabinet� Operated TRU config. �TRU operating configuration


6.1 Type of Antennas is correct *

a Antenna Cell A �� Eng. Design(related NBWO)

b Antenna Cell B �� Eng. Design(related NBWO)

c Antenna Cell C �� Eng. Design(related NBWO)

6.2

a Antenna Cell A :_____ m �� Eng. Design(related NBWO)b Antenna Cell B :_____ m �� Eng. Design(related NBWO)c Antenna Cell C :_____ m �� Eng. Design(related NBWO)

6.3 Direction of Antennas is correcta Antenna Cell A �� Eng. Design(related NBWO)b Antenna Cell B �� Eng. Design(related NBWO)c Antenna Cell C �� Eng. Design(related NBWO)

6.4 Mechanical Down Tilt is correcta Antenna Cell A �� Eng. Design(related NBWO)b Antenna Cell B �� Eng. Design(related NBWO)c Antenna Cell C �� Eng. Design(related NBWO)

6.5 Eletrical Down Tilt is correcta Antenna Cell A �� Eng. Design(related NBWO)b Antenna Cell B �� Eng. Design(related NBWO)c Antenna Cell C �� Eng. Design(related NBWO)

6.6 RBS Antennas bolts and nutsaBolts and nuts are completely installed ��

Engineering Design,RBS GII section 2.1

bBolts and nuts are properly installed ��

Engineering Design,RBS GII section 2.1

Position/height of Antennas is correct.

Items ReferenceOK Not OK Remarks

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Kathrein – Serial Number



55

55

55

Locking nut on antenna bracket


6.7 Antennas cable and feeder

a The connections are correctEngineering Design,Cabinet Installation Instruction(CII), section 5.7.7

Correct Antennas are connected to correct TRUs

��

b The connections are secured

b.1 No loose connectors �� Engineering Design, CII sect. 5.7.7

b.2 The connector type is correct �� Engineering Design

b.3 The connectors are tightened for �� Engineering Design, CII sect. 5.7.7

b.4All coaxial cable from CDU to antenna doesn't have any leakage

�� Engineering Design, CII sect. 5.7.7

b.5 No broken cable �� Engineering Design, CII sect. 5.7.7

b.6 Cable is not bending too much �� Engineering Design, CII sect. 5.7.7

For 7/8 inch , r<250mm Eng.Design(NBWO)

For 1/2 inch, r <125mm Eng.Design(NBWO)

b.7 Within 30cm from upper end, feeder cable is perpendicular

��

c Feeders running and lying on cable ladder are not in strain.It properly fixed ��

d Feeder fixing and clamping d.1 Tightened and fixed �� Eng.Design(NBWO)

d.2 Correctly installed �� Eng.Design(NBWO)

e Feeder clamps in tower are in correct locations

�� Eng.Design(NBWO)

f Earthing kit on feeders outdoor is connected to grounding system and tightened to grounding earth cable. And the angles is not exceeding 45'

��

Eng.Design(NBWO)

g Indoor earthing kits are properly mounted on the feeder connectors


g.1 All screws are tightened �� Eng.Design(NBWO)


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6.8 ALNA and TMAa TMA is properly installed (on the same support) ��

Eng.Design;Installation Instruction for TMA 1800/1900 (1531-NTM/KRY 112 10

b ALNA is properly installed (on the same support) ��

Eng.Design;Installation Instruction for TMA 1800/1900 (1531-NTM/KRY 112 10

c ALNA has proper current and voltage (refer to the type of tower ) ��

Eng.Design;Installation Instruction for TMA 1800/1900 (1531-NTM/KRY 112 10, Tower type

6.9 Outdoor and Indoor runs(ladders) and other feeder support are properly and completely installed

�� Eng.Design;GII Section 7 & 8

6.10 Outdoor and Indoor runs(ladders) and other feeder support are properly and completely grounded

�� Eng.Design;GII Section 7 & 8

6.11 Drip-loop on the feeder cables is available ��

6.12 Antenna Feeder Swap Checka For Antenna X - Pole Type (Cross Pole) and CDU C+

a.1 Feeder Connection TxRx connected to Antenna +45 (Dx 1)

��

b For Antenna Space Diversity and CDU C+b.1 Cell A = Dx 1 and Dx 2 �� b.2 Cell B = Dx 1 and Dx 2 �� b.3 Cell C = Dx 1 and Dx 2 ��

6.13 Drip-loop on the feeder cables is available��


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7.JUMPERS7.1 The jumpers are not short with the

antenna or cabinet��

Eng.Design;RBS GII Section 2.4

7.2 NO CORROTION AT ANY PARTS OF ANTENNAS, CONNECTORS, BOLTS, NUTS, BOOMS, ETC

��

Engineering Design

7.3 Antenna jumpers fixing and clampingAll antenna jumpers are tightened and correctly fixed

��

8. LABELS 8.1 All labels are correctly attacheda Correct labels at antenna cables �� Engineering Design

b Correct labels at jumpers, connectors, feeders

�� Engineering Design

8.2 All labels are easy to read (not blocked)��

Engineering Design

8.3 No labels are peel, tear off at the major parts

�� Engineering Design

Use galvanized materials


9. CABINETS

9.1Cabinets with base frame is at the proper location

�� Eng. Design(related NBWO)

a Door Filter are not dirty and properly installed ��

b Magazines and modules installation are complete with all screw are tightened

��

c Neat runs, no mechanical tension and the connectors are tightened

��

d Power/Fuse panel connection are properly connected

��

9.2 Radio Cabinet and Base frame are properly mounted:a With 3 or 4 anchor bolts �� Eng.Design;CII sect. 5.6.2

b Tightened screws �� Eng.Design;CII sect. 5.6.2

c The Cabinets have properly earthings �� Eng.Design,GII EN/LZB 119 2693/1

9.3 NO CORROTION AT ANY PARTS OF CABINETS ��

9.4 DXUa Configuration of IDB - all units are active


b IDB Diskette is available ��

c External alarms on system overview (OMT) are correct


d The configuration is match with actual configuration (all units must be active) ��

Eng.Design(NBWO)


9.5a Fiber optic(opto cable) is connected properly


b No scratch(es) �� Eng.Design(NBWO)

c No sharp bending �� Eng.Design(NBWO)

9.6 EXTERNAL ALARMa All cable external alarm in DDF and external alarm box are tightened


b With OMT software, the connection is assured �� Eng.Design(NBWO)

c DDF external alarm at Transmission rack is correct, without any ID looping


d Function test for external alarm

d.1 Door Open Alarm �� Eng.Design(NBWO)

d.2 L1, L2, L3 Alarm �� Eng.Design(NBWO)

d.3 Smoke Detector Alarm �� Eng.Design(NBWO)

d.4 MSP Alarm �� Eng.Design(NBWO)

d.5 DC fan Alarm �� Eng.Design(NBWO)

d.6 Grounding Cable Cut �� Eng.Design(NBWO)

d.7 AC Removed Alarm �� Eng.Design(NBWO)

d.8 Genset Run Alarm only for site w/ stand by genset


d.9 Genset Fail Alarm only for site w/ running genset


d.10 Rectifier Fail Alarm (if available) �� Eng.Design(NBWO)

d.11 Fence Break (if available, depend on location) �� Eng.Design(NBWO)

Fiber optic from BFU to PSU


9.7 TEMPERATURE SENSORa Temperature sensor is working properly �� Eng.Design(NBWO)

9.8 DC POWER SYSTEMSa -48VDC is properly connected �� Eng.Design, CII, sect. 5.8.2

b -48VDC is correctly connected �� Eng.Design, CII, sect. 5.8.2

c -48VDC is protected from sharp edges��

Eng.Design, CII, sect. 5.8.2

d +24 VDC is properly connected �� Eng.Design, CII, sect. 5.8.3

e +24 VDC is correctly connected �� Eng.Design, CII, sect. 5.8.3

f +24 VDC is protected from sharp edges��

Eng.Design, CII, sect. 5.8.3

g Distribution Frame is properly installed and connected ��

Engineering Drawing, CII section 5.10

h No Damage is detected �� Engineering Design

I Input DC/DC converter is> 24 V �� Eng.Design(NBWO)j Output DC/DC converter is > 48V �� Eng.Design(NBWO)

k Battery voltage is > 6 voltDC �� Eng.Design(NBWO)l Total batteries voltage > 24 volt DC �� Eng.Design(NBWO)

m Read LED indicator on BFU, DC/DC Converter, DFU (operational function should be on, and fail indicator should be off)


n Discharged batteries condition, each battery voltage after 1 hour while main power cut-off > 6 volt DC



9.8 DC POWER SYSTEMSo Discharged batteries condition, each battery voltage after 1 hour while main power cut-off > 24 volt DC for each bank


p Battery condition is clean �� Eng.Design(NBWO)

p.1 Batteries poles are protected �� Eng.Design(NBWO)

p.2 No corrotion on the batteries poles and nuts��

Eng.Design(NBWO)

q There is no leakage at the battery �� Eng.Design(NBWO)r DC Cable connectors are properly terminated and tightened.No damages to insulation ��

Eng.Design(NBWO)

s Power cable inside extension battery rack is tightened and fixed ��

Eng.Design(NBWO)

t Protection cover of plastic (or equal) on DC power collection bar is available ��

Eng.Design(NBWO)


9.9 FANSa Temperature sensor is work properly (The temperature sensor which tested is sensor at the front of DXU)


b Response and verify four fans are working properly �� Eng. Design(related NBWO)

c The fans are working properly

c.1 - Fan 1 & 2 ( at top rack) �� Eng. Design(related NBWO)c.2 - Fan 3 & 4 ( at bottom rack) �� Eng. Design(related NBWO)d Fans power connector to RBS Cabinet are

correctly installed �� Eng. Design(related NBWO)

9.10 GROUNDINGa RBS cabinet grounding Neutral should be connected to power ground �� Eng. Design(related NBWO)

bRBS battery racks grounding should be connected to power ground �� Eng. Design(related NBWO)

cAll the connections are correctly tightened


9.11 Cable Ladder. All cable ladders are mounted and assembled in correct way �� Eng. Design(related NBWO)


9.12 CLEANNESS AND TIDINESS

No trash or garbage left after acceptance process��

9.13 SAFETY

a No hazardous voltage is exposed for the personal��

b No risk for short circuits in electrical installation��


10. STAND ALONE TEST10.1 SOFTWARE/DATABASE USED :

a DXUa.1 Basea.2 Maina.3 TRUa.4 ECUb TRU

b.1 Baseb.2 Mainc ECU

c.1 Basec.2 Main

10.2 VOLTAGE TEST (IDM measurement)a DC-Voltage Measured Engineering Spec

a.1 Cabinet 1, MC ��

a.2 Cabinet 2, EXT ��

Stand Alone Test


10.3 DC-Voltagea Cabinet 1, MC Measured Engineering Spec

a.1 PSU1 �� 26.7V - 28V a.2 PSU2 �� 26.7V - 28V a.3 PSU3 �� 26.7V - 28V a.4 PSU4 �� 26.7V - 28V

b Cabinet 2, EXT Measured Engineering Specb.1 PSU1 �� 26.7V - 28V b.2 PSU2 �� 26.7V - 28V b.3 PSU3 �� 26.7V - 28V b.4 PSU4 �� 26.7V - 28V

c Input voltage PSU on the top of RBS rack (normal voltage 220V + 10%)

c.1 PSU1 �� Eng.Design(NBWO)




d Compare PSU voltage with BFU voltage. PSU voltage must be bigger then BFU voltage


e Compare PSU current with BFU current. PSU current must be bigger then BFU current



f Incoming AC Power Measured Engineering Specf.1 L1 ��

f.2 L2 ��

f.3 L3 ��

g DC-DC Converter Measured Engineering Specg.1 Converter 1 (output 1) ��

g.2 Converter 1 (output 2) ��

g.3 Converter 2 (output 3) ��

g.4 Converter 2 (output 4) �� 10.4 ACTIVATION OF TRU

a Cabinet 1 a.1 TRU1 (CDU1) �� *TRU Serial #

a.2 TRU2 (CDU1) �� *

a.3 TRU3 (CDU2) �� *

a.4 TRU4 (CDU2) �� *

a.5 TRU5 (CDU3) �� *

a.6 TRU6 (CDU3) �� *

b Cabinet 2 b.1 TRU7 (CDU4) �� * *

b.2 TRU8 (CDU4) �� * *

b.3 TRU9 (CDU5) �� * *

b.4 TRU10 (CDU5) �� * *

b.5 TRU11 (CDU6) �� * *

b.6 TRU12 (CDU6) �� * *


10.5 TEST OF SYSTEM ANTENNAVSWR for Kathrein 739639 is <1.4Other type of antenna, VSWR≤ 1.3

10.5.1 CELL Aa TDR Tests

a.1 Feeder Length (DX1) ______ m �� Eng.Design(NBWO)a.2 Feeder Length (DX2) ______ m �� Eng.Design(NBWO)b SWR Tests

b.1 Return Loss (DX1) ______ dB �� Eng.Design(NBWO)b.2 Return Loss (DX2) ______ dB �� Eng.Design(NBWO)b.3 SWR (DX1) _____ �� Eng.Design(NBWO)b.4 SWR (DX2) _____ �� Eng.Design(NBWO)

10.5.2 CELL Ba TDR Tests



10.5.3 CELL Ca TDR Tests




11. INTEGRATION TEST11.1 TRU (please indicates whether it's 900MHz or 1800MHz)

For 900MHz, Tx Frq is (88< freq <124)

11.2 NETWORK INTEGRATION TESTSA CDU1

A.1Receive Signal Stregth

Level(dBm) Engineering Spec

a Channel Number :_________ ��

b TS0-TS7 (all time slot) �� TS 0 :�� TS 1 :

�� TS 2 :�� TS 3 :�� TS 4 :�� TS 5 :�� TS 6 :

�� TS 7 :

A.2 TRU2 (use TEMS for Testing) Receive Signal Stregth Level(dBm) Engineering Spec

a Channel Number :_________ ��

b TS0-TS7 (all time slot) �� TS 0 :

�� TS 1 :

�� TS 2 :

�� TS 3 :

�� TS 4 :

�� TS 5 :

�� TS 6 :

�� TS 7 :

NOTES: IF TIMESLOTS ARE DIFFICULT TO OCCUPIED/TESTED, PLEASE CONFIRM TO NOC, TO CHECK WHETHER THE CONCERNED TIMESLOTS ARE OCCUPIED BY CUSTOMERS

NOTES: IF TIMESLOTS ARE DIFFICULT TO OCCUPIED/TESTED, PLEASE CONFIRM TO NOC, TO CHECK WHETHER THE CONCERNED TIMESLOTS ARE OCCUPIED BY CUSTOMERS

TRU1 (use TEMS for Testing)

Integration Test


11.3 CALL TEST to MS(one call per cell)a Cell A �� b Cell B �� c Cell C ��

11.4 HANDOVER TEST (use Full TEMS to perform this test)a Handover on site for Cell A to B �� b Handover on site for Cell A to C �� c Handover on site for Cell B to A �� d Handover on site for Cell B to C �� e Handover on site for Cell C to A �� f Handover on site for Cell C to B ��

11.5 Functional test for external alarm (shall be confirmed with NOC to monitor the result of alarm test)

1 Door Open Alarm �� Eng.Design(NBWO)

2 L1, L2, L3 Alarm �� Eng.Design(NBWO)

3 Smoke Detector Alarm �� Eng.Design(NBWO)

4 MSP Alarm �� Eng.Design(NBWO)

5 DC fan Alarm �� Eng.Design(NBWO) Run/work properly

6 Grounding Cable Cut �� Eng.Design(NBWO) Run/work properly

7 AC Removed Alarm �� Eng.Design(NBWO) Run/work properly

8 Genset Run Alarm only for site w/ stand by genset �� Eng.Design(NBWO) Run/work properly

9 Genset Fail Alarm only for site w/ running genset �� Eng.Design(NBWO) Run/work properly

10 Rectifier Fail Alarm (if available) �� Eng.Design(NBWO) Run/work properly

11 Fence Break (if available, depend on location) �� Eng.Design(NBWO) Run/work properly


11.6 TRU Alarm Test (put TRU in local Mode and check with NOC for Alarm. Put TRU back to operational Mode,ensure it work fine.Confirm with NOC)

a TRU1a.1 Local Mode �� Alarm occur at NOC

a.2 Operation Mode �� Alarm clear at NOC

b TRU2b.1 Local Mode �� Alarm occur at NOC

b.2 Operation Mode �� Alarm clear at NOC

c TRU3c.1 Local Mode �� Alarm occur at NOC

c.2 Operation Mode �� Alarm clear at NOC


NAME of NOC Person that confirmed the test :________________________________

PENDING ITEMSPlease list down all the pending items and timeline to complete it

No. ITEMS DATE OF COMPLETION CONTACT NO.PERSON IN CHARGE


ACCEPTANCE PROCESS BY : VERIFIED AND APPROVED BY EXCELCOM :VENDOR : ________________

NAME: signature

FIELD OPERATIONS (for handover from CNI, ATP with vendor)

NAME & DATE NAME: signature

CONSTRUCTIONS&INSTALLATION(for ATP with contractor & handover to FOP)

ADDITIONAL NOTES


Documents

RBS 2206 Testing for Engineer