NODE-B WCDMA ERICSSON.doc

NODE-B WCDMA ERICSSON

FOR

How to collect RBS Type in Node-B using moshell...4

How to collect board position information in Node-B using moshell...5

How to change the board:...7

Here are Node-B Ericsson types:...10

RBS 3518 ...11

Cabinet Overview...11

Hardware Units...12

Connection Interfaces...13

Site LAN Interface including Local O&M...13

OIL Interface...14

Transmission Interfaces...15

External Alarm Interface...16

ESD Interface...17

Earth Grounding Interface...18

Power Interface...18 RBS 3518 Climate System...19 RBS 3206M...20 Hardware Units...20 RBS 3206F...21 Hardware Units...21 RBS 3206E...23 Hardware Units...23 Connection Interfaces...25

Site Local Area Network (Optional) (position A)...26

Transmission Interface (Position C)...27

Power interfaces (Position D)...30

External Alarm Interface (Position E)...32

Antenna Interface (Position G)...33

Cabinet overview...35 RRU overview...36 Hardware Units...37 OIL...38 Connection Interfaces...39 Transmission Interface...41 OIL Interface...42

Site LAN Interface Including Local O&M...43

Power Interface...44

External Alarms Interface...45

RBS 3202...46

Cabinet Overview...46

Hardware Units...48

Connection Interface...50

Power Connection Interface...51

Antenna Connection Infterfaces...51

Transmission Interface...52

Site LAN Interface...53

How to collect RBS Type in Node-B using moshell

2. type moshell command: get 0

CYLB6700> get 0

090925-10:13:07 CYLB6700 7.0y RBS_NODE_MODEL_K_2_3 stopfile=/tmp/17952

0 ManagedElement=1 ===================================================================== ManagedElementId 1 applicationConfiguration t[0] = faultTolerantCoreStates s[1] = ManagedElement=1,Equipment=1,Subrack=1,Slot=1,PlugInUnit=1;Active logicalName 1067001 mimInfo Struct{3} >>> 1.mimName = RBS_NODE_MODEL_K >>> 2.mimVersion = 2.3 >>> 3.mimRelease = mimName RBS_NODE_MODEL_K productName RBS3206 productNumber 11/COH1092069 productRevision -productType Node site CYLB6700 userLabel CYLB6700

How to collect board position information in Node-B using moshell

2. type moshell command: cabx

CYLB6700> cabx

090925-10:22:20 CYLB6700 7.0y RBS_NODE_MODEL_K_2_3 stopfile=/tmp/17952 Please enter Node Password:

...

=====================================================================

=====================================================================

0 1 CBU1 ON 16HZ OFF ROJ 119 2209/1 R5G 20080116 TU8G099829 +31C Active* 0 7 RAX ON 16HZ OFF R1D 20090529 TU8GB69142

0 8 RAX11 ON 16HZ OFF R1B 20071205 TU8G053748 0 9 RAX11 ON 16HZ OFF ROJ 119 2187/8 20080103 TU8G085404 0 10 TX6HS-03 ON 16HZ OFF ROJ 119 2254/7 R1D 20071117 AE56156374 0 11 TX6HS-03 ON 16HZ OFF ROJ 119 2254/7 R1D 20080120 AE56659891 0 12 RUIF ON 16HZ OFF ROJ 119 2245/2 R2A 20080112 AE56598745

---================================================================ SMN ProductNr Rev Name Date SerialNr

================================================================ 0 ROJ 605 116/1 R1A Subrack 20040101 Baseband

0 ROJ 605 116/1 R1B BACKPLANE 20071204 TY11991700

---=====================================================================

SMN APN PORT BOARD GREEN YELLOW RED PRODUCT NR REV DATE SERIAL NR =====================================================================

0 12 port_0_dev_5 RU21 steady 16hz off KRC 118 16/3 R2A 20080107 AE56548926 0 12 port_0_dev_5 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080118 TU8F319901 0 12 port_10_dev_10 RU21 steady 16hz off KRC 118 16/2 R2A/A 20080204 AE56764152 0 12 port_10_dev_10 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080131 TU8F326710 0 12 port_2_dev_6 RU21 steady 16hz off KRC 118 16/2 R2A/A 20080204 AE56764155 0 12 port_2_dev_6 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080131 TU8F326650 0 12 port_4_dev_7 RU21 steady 16hz off KRC 118 16/3 R2A 20080108 AE56555388 0 12 port_4_dev_7 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080118 TU8F319913 0 12 port_6_dev_8 RU21 steady 16hz off KRC 118 16/2 R2A/A 20060810 AE53184109 0 12 port_6_dev_8 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080131 TU8F326687 0 12 port_8_dev_9 RU21 steady 16hz off KRC 118 16/3 R2A 20080108 AE56555359 0 12 port_8_dev_9 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080118 TU8F319819

How to change the board:

1. Login to Node-B with moshell or EMAS 2. run moshell command cabx

CYLB6700> cabx

090925-10:22:20 CYLB6700 7.0y RBS_NODE_MODEL_K_2_3 stopfile=/tmp/17952 Please enter Node Password:

...

=====================================================================

SMN APN BOARD GREEN YELLOW RED PRODUCT NR REV DATE SERIAL NR TEMP COREMGR =====================================================================

0 1 CBU1 ON 16HZ OFF ROJ 119 2209/1 R5G 20080116 TU8G099829 +31C Active* 0 7 RAX ON 16HZ OFF R1D 20090529 TU8GB69142

0 8 RAX11 ON 16HZ OFF R1B 20071205 TU8G053748 0 9 RAX11 ON 16HZ OFF ROJ 119 2187/8 20080103 TU8G085404

0 10 TX6HS-03 ON 16HZ OFF ROJ 119 2254/7 R1D 20071117 AE56156374

0 11 TX6HS-03 ON 16HZ OFF ROJ 119 2254/7 R1D 20080120 AE56659891 0 12 RUIF ON 16HZ OFF ROJ 119 2245/2 R2A 20080112 AE56598745

---================================================================ SMN ProductNr Rev Name Date SerialNr

================================================================ 0 ROJ 605 116/1 R1A Subrack 20040101 Baseband

0 ROJ 605 116/1 R1B BACKPLANE 20071204 TY11991700

---=====================================================================

SMN APN PORT BOARD GREEN YELLOW RED PRODUCT NR REV DATE SERIAL NR =====================================================================

0 12 port_0_dev_5 RU21 steady 16hz off KRC 118 16/3 R2A 20080107 AE56548926 0 12 port_0_dev_5 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080118 TU8F319901 0 12 port_10_dev_10 RU21 steady 16hz off KRC 118 16/2 R2A/A 20080204 AE56764152

0 12 port_10_dev_10 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080131 TU8F326710 0 12 port_2_dev_6 RU21 steady 16hz off KRC 118 16/2 R2A/A 20080204 AE56764155 0 12 port_2_dev_6 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080131 TU8F326650 0 12 port_4_dev_7 RU21 steady 16hz off KRC 118 16/3 R2A 20080108 AE56555388 0 12 port_4_dev_7 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080118 TU8F319913 0 12 port_6_dev_8 RU21 steady 16hz off KRC 118 16/2 R2A/A 20060810 AE53184109 0 12 port_6_dev_8 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080131 TU8F326687 0 12 port_8_dev_9 RU21 steady 16hz off KRC 118 16/3 R2A 20080108 AE56555359 0 12 port_8_dev_9 FU12 ON 16Hz OFF KRC 118 17/1 R2F 20080118 TU8F319819 3. lock the board where the board want to replace it by command: bl 001000

Logging to file: /home/gnoc/moshell_logfiles/logs_moshell/tempfiles/20090925-165054_26346/boLog26346 ... Log close: /home/gnoc/moshell_logfiles/logs_moshell/tempfiles/20090925-165054_26346/boLog26346 Created following board-groups: all, allp, mp, bp, tu, coremp, ommp, scx, xp, rax, tx, tx6, ru, ru[0-6]. >>> Type "bp" to view available board-groups and "bp <group>" to view group contents.

Block following MOs ?

=================================================================================== 115 Equipment=1,Subrack=1,Slot=10,PlugInUnit=1

=================================================================================== Are you Sure [y/n] ?

4. Replace the board CBU, RAX, TX6HS-03 a. Remove the board.

i. Put on the ESD wrist strap and connect the cable to the earth grounding point or the ESD button, if available. ii. Check the subrack slot number against the work order.

iii. Note the positions of any cables connected to the board (CBU). iv. Starting from the top, disconnect the cables from the board (CBU)

NOTE: ALWAYS HANDLE BOARDS BY THE FRONT, EDGE, OR BACK FRAME AND DO NOT TOUCH THE CIRCUIT

PATTERN OR PINS

vi. Place the board in an antistatic bag and reuse the packing from the replacement board. b. Installing the board

i. Unpack the board and check that it is undamaged.

iii. Insert the replacement board into position and ensure that the locking clamps engage the subrack locking rails, in accordance with above picture.

iv. Lock the board by simultaneously pushing both locking clamps towards the board.

v. Tighten the screws to a standard torque using a torque driver and a 50 mm (or longer) T8 Torx bit. Ensure that the bit is correctly engaged in the head of the lcoking clamp screw before starting.

5. After finish the installing the board tell to the Front office to do unlocking the board. 6. Unlocking the board by command: deb 001000 (xxyy00  xx= subrack, yy=slot )

Here are Node-B Ericsson types:

RBS 3518

Cabinet Overview

Hardware Unit Slot Pos. No. of Units

CBU 1 1 ET-MC1 board 2 0-1 ET-M4 board ET-M3 board ET-MC41s board ET-PSW board 2 or 3 (1) _0-1 ET-MFX board 2 0-1 RAX 3-6 1-4 (2) (3)(4) TX board 7, 8 1-2 (5) OBIF 9 1 (6)

PDU N/A 1

RRU11 N/A 1-6

RRU22 N/A 1-6

Connection Interfaces

Position Unit

1 Site LAN interface 2 OIL interfaces

3 Transmission connection interfaces 4 External alarm interfaces

5 ESD interface

6 Earth grounding interface (underneath the cabinet) 7 Power interface

8 GPS (optional)

Table 11 RBS 3518 Internal Connection Interfaces

Position Unit

A External alarm interface

B Transmission: E1/T1/J1 or STM-1 (unchannelized)

A site LAN is used to communicate with the RBS Element Manager (RBS EM) or Moshell, which in turn can be used to connect a thin client to the RBS3518 for configuration and service purposes.

To connect to the site LAN, route a crossed transmission cable through the cable sealing module at the bottom of the RBS 3518 and plug its RJ-45 cable connector into the cable inlet located above the Surge Protection Device(SPD). See beside picture.

The OIL interface carries traffic and timing signals between the RBS 3518 and each RRU. The OIL cable is routed to the OBIF2 (or OBIF4) board through the cable sealing modules at the bottom of the RBS 3518. see the beside picture.

The connection interface at the bottom in the RBS 3518 is equipped with a plate of cable sealing modules, with each module intended for sealing three cables. As the cables to be used can be of various diameters, it is possible to change the diameter of the hole in each module.

The external alarm interface is a push-in connector. As shown in beside picture. Two OVP modules are used to make the external alarms available.

ESD Interface

The Electrostatis Discharge (ESD) interface provides a connection point for the ESD wrist strap, which protects boards and units from being damaged by electrostatic discharge from anyone working with them.

Earth Grounding Interface

The single earth grounding point for the RBS 3518 is the threaded stud.

The power interface accepts cables with a cross-sectional area of up to 4 mm2_{, and a minimum of 2.5 mm}2 _{is recommended. Only multistrand}

cables can be used. The power is connected to the PDU through the SPD. The SPD and Connection Field are covered, as picture beside.

RBS 3518 Climate System

Position Unit

A External fan unit

B Internal Fan Unit, controlling the heaters during cold start, and cold operation

C Heat Exchanger (HEX) D Heaters

RBS 3206M

Hardware Units

Position Description

A Connection Field (CF) B Fan

C Fan Control Unit (FCU)

D Power Distribution Unit (PDU) E Filter subrack

The filter subrack contains the following: Filter Unit (FU) F The radio subrack contains the following: Radio Unit (RU)

Radio subrack also includes the digital casette, see below G

Digital cassette:

• Control Base Unit (CBU)

• Random Access and Receiver (RAX) board

• Transmitter (TX) board

• Radio Unit Interface (RUIF)

RBS 3206F

Position Description

A Connection Field (CF) B Fan

C Fan Control Unit (FCU)

D Type 1cabinet: DC filter or +24 V DC Connection Unit (DCCU)

Type 2 cabinet: Alternating Current Connection Unit (ACCU) or three-wire -48 V DCCU (1) _{or Power Distribution}

Unit 03 (PDU-03) (2)

E Filter subrack

The filter subrack contains the following: Filter Unit

(FU) & Dummy board

F Radio subrack

The radio subrack contains the following: Radio Unit

(RU) & Power Distribution Unit (PDU)

G Digital subrack which contains the following:

Control Base Unit (CBU)

Exchange Terminal (ET) board

Random Access and Receiver (RAX) board Transmitter (TX) board

H Power subrack or space for optional equipment J Busbar

K Type 1 cabinet: Alternating Current Connection Unit (ACCU) or three-wire -48 V DCCU

Type 2 cabinet: DC filter or +24 V DC Connection Unit (DCCU) (1)

RBS 3206E

Position Description

A Connection Field (CF)

B Fan

C Fan Control Unit (FCU)

D DC filter or +24 V DC Connection Unit (DCCU) E Filter subrack, which contains the following:

Power Distribution Unit (PDU) Filter Unit (FU)

F Radio subrack 6RU, which contains the following:

Power Distribution Unit (PDU) Radio Unit (RU)

G Digital subrack, which contains the following:

Control Base Unit (CBU)

Exchange Terminal (ET) board

Random Access and Receiver (RAX) board Transmitter (TX) board

Radio Unit Interface (RUIF)

H Radio subrack 3RU, which contains RUs J Power subrack, which contains the following:

Auxiliary Unit Hub (AUH) Power Supply Unit (PSU)

K Busbar

L Alternating Current Connection Unit (ACCU) or three-wire -48 V DCCU

Position Description

A Site Local Area Network (LAN) (optional)

B Global Positioning System (GPS) interface (optional) C Transmission interface

D Power connection interface E External alarm interface F Earthing grounding interface G Antenna interface

H Electrostatic Discharge (ESD) interface J Co-siting interface

Site LAN is used to communicate with the Base Station Element Manager (BEM). A Thin Client can be connected to the CF or directly to the Control Base Unit (CBU), for configuration and service

purposes through the BEM. The Site LAN interface in the CF can occupy two positions: M1 and M2. The interface in the CF consists of an RJ-45 connector. A specific adapter is required to connect the Thin Client directly to the CBU

The connection interface in the CF can be equipped with up to 32 female RJ-45 connectors, see the figure below. Internal connections are made between the connection interface and the CBU and between the connection interface and any optional ET-MC1 boards in the digital subrack

The STM-1/OC-3c and STM-1/OC-3 connection interface in the CF is equipped with four optical SC connectors. An internal connection is made between the CF and the optional ET-M4, or ET-MC41s board in the digital subrack.

The ET-MFX or ET-PSW connection interface in the CF is equipped with RJ-45 female connectors. An internal connection is made between the CF and the ET-MFX or the ET-PSW board in the digital subrack

Power interfaces (Position D)

RBS 3206M The incoming two-wire -48 V DC power is connected by screw terminals to a PDU-03. The power cable must be multistranded and have a cross-sectional area of 35-70 mm

RBS 3206F The incoming -48 V DC prioritized power is connected by screw terminals to a PDU-03. The power cable must be multistranded and have a cross-sectional area of 35-70 mm

RBS 3206F and RBS 3206E The incoming two-wire -48 V DC power is connected by screw terminals to a DC filter. The power cable must be multistranded and have a cross-sectional area of at least 35 mm .

The external alarm interface to the EACU is located on the Fan Control Unit (FCU) and consists of a 10-pin RJ-45 connector. The interface contains both power and control connections.

The antenna jumpers are routed through the antenna jumper inlet and connected directly to the Filter Units (FU). The antenna connection interface on the FU consists of a 7/16 connector.

Configuration 3x1 for RBS 3206M Configuration 3x1 and 6x1 for RBS 3206F and 3206E

FU / FU Connector Sector / Antenna Connector

FU 1 / A Sector 1 / A

FU 1 / B Sector 1 / B

FU 2 / A Sector 2 / A

FU 2 / B Sector 2 / B

FU 3 / A Sector 3 / A

FU / FU Connector Sector / Antenna Connector

FU 1 / A Sector 1 / A

FU 1 / B Sector 1 / B

FU 3 / A Sector 2 / A

FU 3 / B Sector 3 / B FU 5 / A Sector 3 / A FU 5 / B Sector 3 / B FU 2 / A Sector 4 / A FU 2 / B Sector 4 / B FU 4 / A Sector 5 / A FU 4 / B Sector 5 / B FU 6 / A Sector 6 / A FU 6 / B Sector 6 / B

RBS 3402

The Main Unit (MU) consists of the following parts:  Main Unit (MU) Subrack

 Switch Control Board (SCB)  Timing Unit Board (TUB)  Exchange Terminal (ET) board

 General Purpose Processor Board (GPB)  Transmitter (TX) board

 Random Access and Receiver (RAX) board  Optical Baseband Interface (OBIF) board  Capacitor Unit and External Alarm (CUX) unit  Remote Radio Unit (RRU)

The Radio Remote Unit (RRU) contains all radio equipment and is a field-replaceable unit. No parts of the RRU can be replaced separately.

A Fan Unit

B Capacitor Unit and External Alarm Unit (CUX) C

MU (Main Unit) subrack

The MU subrack typically consists of the following components:

• Switch Core Board (SCB)

• Timing Unit Board (TUB)

• Exchange Terminal (ET) board

• General Purpose Processor Board (GPB)

• Transmitter (TX) board

• Random Access Receiver (RAX) board

• Dummy Board/second RAX board

• Optical Baseband Interface (OBIF) board D Connection Interfaces

The connection between the MU and the RRU is made by an Optical Interface Link (OIL). There are several different lengths available for the OIL cables: 20, 70, 150, 250, 350 and 500 m. The OIL must have zero-dispersion in the wave length range 1302 – 1322 nm. For longer distances between MU and RRU an already installed optical fiber transmission network, e.g. Dark Fiber, can be leased and used to increase the total length of the OIL. The OIL cable(s) is connected to the leased optical fiber transmission network by a connection box.

The maximum length of the OIL (OIL cable, or OIL cable and leased optical fiber) is 15000 m.

It is important that the leased optical fiber has a fixed delay and that the uplink and downlink fiber have the same delay, within 8 ns. This corresponds to less than 1.5 m difference between uplink and downlink fiber.

The total delay for the entire OIL connection must be less than 75 µs in each direction. This corresponds to 15 km fiber in each direction.

The total optical attenuation for the entire OIL connection must be less than 15 dB, in each direction

A Transmission: E1, T1, J1 100 – 120 , or STM-1, electrical and optical Ethernet 1 Gbit/s (view of E1, T1, J1 100 – 120

)

B Transmission: E1 75 C Grounding interface D OIL interface

E GPS (optional)

F SiteLAN interface including local O&M G Power interface

H External alarm interface J ESD interface

Transmission Interface

E1 or Ethernet

The connection interface on the top of the MU is equipped with eight female RJ-45 connectors, see the figure below. An internal connection is made from the connection interface to the ET-MC1 or ET-MFX board in the MU subrack.

To support the 75 cable impedance, the MU can be delivered with one or two transmission adapters (Miniwift) installed on the top of the cabinet. The transmission adapter, consisting of eight BNC connectors, is a converter between the 75 coaxial interface and the 120 twisted pair aimed for the E1 interface. The signal is transformed to 120 in the transmission adapter, and distributed to the 120 transmission connector panel and then further to the ET board.

The OIL interface carries traffic and timing signals between the MU and each RRU. The OIL cable is routed to the OBIF board through up to three holes on the top of the MU.

SiteLAN is used for communication with the Base station Element Manager (BEM). A Thin Client can be connected to the MU for configuration and service purposes by using the BEM. The interface consists of an RJ-45 connector.

The power interface is protected by a plastic cover. The cables can be connected without removing the cover. The power interface accepts cables with an area up to 6 mm , a minimum cable area of 2.5 mm is recommended. The cable should be a multi strand cable. The power is connected directly to the CUX board using the DC input terminals.

The external alarm interface consists of a 37 poled female D-sub connector

RBS 3202

Hardware Units

A Left and right antenna connection interface B Earth grounding points

C Power connection interface D Connection Field (CF) E Capacitor Unit (CU) F

Baseband (BB) subrack and fan unit

The BB subrack typically consists of the following components:

• Baseband Interface (BBIF) Board

• Exchange Terminal (ET) Board

• General Purpose Processor Board (GPB)

• Random Access Receiver (RAX) Board

• Switch Core Board (SCB)

• Transmitter (TX) Board

• Dummy Board G

Radio Frequency (RF) subrack and fan unit

The RF subrack typically consists of the following components:

• Antenna Interface Unit (AIU)

• Radio Frequency Interface (RFIF) Board

• Switch Core Board (SCB)

• Transceiver (TRX) Board

• Dummy Board H

Multicarrier Power Amplifier (MCPA) subrack

The MCPA subrack typically consists of the following components:

• MCPA

• MCPA hub

• Dummy MCPA J Base frame

Connection Interface

Top View Cabinet

This section provides information about the interfaces on the RBS. The Connection Field (CF), the interfaces for earth grounding, power and antennas are located on the RBS cabinet top. The CF includes 22 slots beginning from the left.

The CF is used as the interface to the cabinet boards. The CF is modular and contains the interfaces for transmission, local Operation and Maintenance (O&M) and Auxiliary Unit Hub (AU-Hub).

1 Earth grounding interfaces 2 Power interface

3 Antenna interfaces

4 Transmission interface, ET-M1, ET-MC1 5 Transmission interface, ET-M4

6 Transmission adapter

8 Auxiliary Unit Hub (AU-Hub) interface 9 ESD interface

Power Connection Interface

The power connection interface is located on the cabinet top in a black protective box, called DCCU (DC Connection Unit). The maximum dimensions for each power cable is 70 mm and the power connectors are two M8 screws with washers and M8 cable lugs.

The antenna connection interfaces are located on the cabinet top; three antenna feeder connectors on each side. The connectors are 7/16 IEC-169-4 female connectors.

The connectors are labelled H1 to H3 and J1 to J3, see beside picture.

The antenna cables must be connected as follows:  Sector 1A to position J1  Sector 1B to position H1  Sector 2A to position J2  Sector 2B to position H2  Sector 3A to position J3  Sector 3B to position H3 Transmission Interface E1

The E1, T1, J1 connection interface in the CF is equipped with eight female RJ-45 connectors for the ET board cables, see beside picture. The ET-M1 board and the ET-MC1 board each has support for up to eight T1, J1, or E1 transmission lines connected in four RPV 431 connectors in the board front

STM-1

The STM-1 connection interface, located in the CF in positions T09 and T11, is equipped with two pairs of female SC connectors. An internal connection is made from the CF to the ET-M4 or ET-MC41s board in the BB Subrack.

The connector for local O&M is an 8-pin, non-keyed, female RJ-45 connector located in the CF in position T17A. See beside picture. Ethernet cables can be connected to the O&M interface. The connector in position T17B is provided for redundancy

AU-Hub Interface

Interface

Type Cable Type Cable Product Number Cable Position in CF

PCU Balanced lines TSR 482 0248/15m 22A XALM Balanced lines TSR 482 0243/15m 22C