Data Configuration Procedure

7/27/2019 Data Configuration Procedure

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Data Configuration Procedure

Prerequisites

The following requirements must be met before data configuration:

Operators must familiarize themselves with the base station system (BSS) and bewell trained.

The software of the LMT and the OMU (on the GBAM) are installed.

Configuration Procedure

Figure 1 shows the basic procedure for data configuration.

BSC configuration-BTS ConfigurationTRX configuration --Cell configuration.

Figure 1 Basic procedure for data configuration

BSC configuration, consisting of configuration of BSC basic Attributes, device

data configuration, and link configuration.

BTS configuration, consisting of configuration of BTS basic Attributes, deviceconfiguration, and timeslot configuration.

Cell configuration, consisting of cell attributes configuration, neighboring cell

configuration, and import and export of network optimization parameters.

TRX configuration, consisting of channel attributes configuration and TRX

attributes configuration.

Number ConfigurationItem

Description

1SS7 signalingpoints

The SS7 signaling points consist of the OSP, DSP,and STP. For details, refer to section " ConfiguringSS7 Signaling Points ."

2 Cabinet

The cabinet is of two types: local cabinet and remotecabinet.

For details, refer to section "Adding a Cabinet ."

3 Subrack

The subrack is of two types: GEPS and GTCS.

For details, refer to section "Adding a Subrack ."

4Powerdistribution box

For details, refer to section "Adding a PowerDistribution Box ."

5Subrack-OSPmapping

A subrack should be configured with signaling points.

For details, refer to section " Configuring theSubrack-OSP Mapping ."


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6 BSC board

The BM subrack must be configured with theGE(O)IUB and the GE(O)IUT.

The TC subrack must be configured with theGE(O)IUA, GE(O)IUT, and GDPUC.

For details, refer to section "Adding a Board ."

The links on the Ater interface are configured on theE(O)IUT. These links connect the GMPS with theGTCS.

The GMPS should be configured with the followinglinks:

Ater connection path For details, refer tosection " Configuring an Ater Connection

Path ." Ater OML (configured when the GTCS is

placed on the MSC side). For details, refer tosection "Adding an Ater OML ."

The GTCS should be configured with the Atersignaling link when the GTCS is placed on the MSCside. For details, refer to section Adding an AterSignaling Link ."

7Transmissionlinks

The links on the A interface are configured on theGE(O)IUA. These links consist of the following:

E 1 on the A interface For details, refer tosection Configuring an E1 on the A Interface."

SS7 signaling link For details, refer to "Configuring an SS7 Signaling Link ."

Line clock

For details, refer to section " Configuring the LineClock ."

System clock

For details, refer to section " Configuring the SystemClock ."

9 Clock

8K reference clock

For details, refer to section " Configuring the 8KReference Clock ."

10 BTS For details, refer to section "Adding a BTS ."


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1. Configuring SS7 Signaling Points

Task Description

Purpose To add the SS7 signaling points

Mandatory or

OptionalMandatory

Prerequisites None

Remarks

The BSC6000 can be configured with a maximum of four

Originating Signaling Points (OSPs) and one Destination

Signaling Point (DSP).

The OSP must be configured before the DSP is configured.

The OSP must be configured before the Signaling TransferPoint (STP) is configured

The names and codes of signaling points must be unique.

Procedure

Table 1 lists an example of the configurations of the SS7 signaling points.

Table 1 Example of the configurations of the SS7 signaling points

Parameter Configuration Source

OSP Name 11 BSC internal planning

OPC (Hex) 11 Network planning

Encoding Scheme 14 Network planning

Network Indicator NATB Network planning

DSP Name C1 BSC internal planning

DSP (Hex) C1 Network planning

Using STP Yes Network planning

STP (Hex) D1 Network planning

Configuring an OSP

To configure an OSP, do as follows:

Step 1 On the Management Tree tab page, right-clickBSC6000.


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A shortcut menu is displayed, as shown in Figure 1 .

Figure 1 Choosing Configure SS7 Signaling Point

Step 2 Choose Configure SS7 Signaling Point.

The Configure SS7 Signaling Point dialog box is displayed, as shown in Figure 2 .

Figure 2 OSP tab page

Step 3 ClickAdd OSP.

The Add SS7 OSP dialog box is displayed, as shown in Figure 3 .


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Figure 3 Adding an SS7 OSP

NOTE:

If an OSP already exists before you add an OSP, Encoding Scheme andNetwork

Indicator for the OSP to be added are the same as that for the existing OSP..

Table 2 describes the parameters in the Add SS7 OSP dialog box.

Table 2 Parameters in the Add SS7 OSP dialog box

Parameter Default Value Description

Osp Name 1 Name of the OSP

OPC (Hex) -

The originating signaling point code is of two

types.

If NI is set to INT, the range of the 14-bitsignaling point code is 0x1-0x3FF0, and the

range of the 24-bit signaling point code is

0x1-0xFFFFF0. If NI is set to other values, the range of the

14-bit signaling point code is 0x1-0x3FFF,

and the range of the 24-bit signaling point

code is 0x1-0xFFFFFF.

EncodingScheme

24

Coding scheme used by the originating signaling

point.


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The network structure has two options: 24-bit

signaling point code and 14-bit signaling point

code.

NetworkIndicator

INT

Network indicator of the OSP

The network indicator identifies the network where

the OSP is located.

The SS7 signaling network is of four types.

INT: International Network

INTB: International Standby Network

NAT: National Network

NATB: National Standby Network

Step 4 Set the parameters, and then clickOK to return to the Configure SS7 Signaling

Point dialog box.

Step 5 Click Finish.

----End

NOTE:

After adding an OSP, you can modify or delete it.

Configuring a DSP

To configure a DSP, do as follows:

Step 1 After configuring a OSP, click the DSP tab in the Configure SS7 Signaling Point

dialog box.

The DSP tab page is displayed, as shown in Figure 4.


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Figure 4 DSP tab page

Step 2 ClickAdd DSP.

The Add SS7 DSP dialog box is displayed, as shown in Figure 5 .

Figure 5 Adding an SS7 DSP

NOTE:


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If an STP exists, you can set Using STP to Yes.

Table 3 describes the parameters in the Add SS7 DSP dialog box.

Table 3 Parameters in the Add SS7 DSP dialog box

Parameter DefaultValue

Description

Dsp Name - Name of the DSP

DPC (Hex) -

The destination signaling point code (DPC) is of

two types.

If NI is set to INT, the range of the 14-bit

signaling point code is 0x1-0x3FF0, andthe range of the 24-bit signaling point code

is 0x1-0xFFFFF0.

If NI is set to other values, the range ofthe 14-bit signaling point code is 0x1-

0x3FFF, and the range of the 24-bit

signaling point code is 0x1-0xFFFFFF.

Using STP No

Determines whether the SS7 signaling transmits

through the signal transfer point (STP)

This parameter is set on the basis of the networkplanning.


Point dialog box.

Step 4 ClickFinish.

----End

NOTE:

After adding an DSP, you can modify or delete it.

Configuring an STP

NOTE:

Before configuring an STP, ensure that the OSP already exists. The number of STPs

should not exceed three.

To configure an STP, do as follows:


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Step 1 After configuring an OSP, click the STP tab. The STP tab page is displayed, as

shown in Figure 6.

Figure 6 STP tab page

Step 2 Click Add STP.

The Add STP dialog box is displayed, as shown in Figure 7.

Figure 7 Adding an STP


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Table 4 describes the parameters in the Add SS7 STP dialog box.

Table 4 Parameters in the Add SS7 STP dialog box

Parameter Description

STP Name Name of the signaling transfer point

STPC (Hex)The code of the STP must be the same as that of the signaling

point on the peer end.

Name of the signaling

point transferred to

Name of the DSP transferred by the STP This parameteridentifies the destination to which the signaling point is

transferred

Step 3 Configure the related parameters, and then click OK to return to the STP tab

page.

Step 4 Click Finish.

2. Adding a Cabinet

Task Description

Purpose To add a BSC cabinet

Mandatory or

OptionalMandatory

Prerequisites NoneRemarks None

Procedure

Table 1 lists an example of the configurations of a BSC cabinet.

Table 1 Example of the configurations of a BSC cabinet


Cabinet No. 1 BSC internal planning

Cabinet Type Remote Cabinet BSC internal planning

To add a cabinet, do as follows:




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Figure 1 Choosing Add BSC Cabinet

Step 2 Choose Add BSC Cabinet.

The Add Cabinet dialog box is displayed, as shown in Figure 2 .

Figure 2 Adding a cabinet

Table 2 describes the parameters in the Add Cabinet dialog box.

Table 2 Parameters in the Add Cabinet dialog box


Cabinet No. - Logical number of the cabinet

Cabinet Type Local CabinetCabinet Type consists ofLocal Cabinet andRemote

Cabinet.


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Step 3 Set the parameters, and then clickFinish.

----End

Adding a Subrack

Task Description

Purpose To add a subrack

Mandatory or

OptionalMandatory

Prerequisites

The cabinet where the subrack is to be added is alreadyconfigured.

The BSC has at least one Originating Signaling Point

(OSP).

Remarks None

Procedure

Table 1 lists an example of the configurations of a subrack.

Table 1 Example of the configurations of a subrack


Subrack Type GTCS BSC internal planning

OPC 11 Network planning

Note

This topic describes how to add a subrack for a local cabinet.

A local cabinet can be configured with all types of subracks.

A remote cabinet, placed on the MSC side, can be configured with only the GTCS

subrack.

To add a subrack, do as follows:

Step 1 On the BSC Device Panel tab page, select the cabinet where the subrack is to be

added from the Current Cabinet drop-down list.

Step 2 Right-click in the area where the subrack is to be added in the cabinet.



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Figure 1 Choosing Add Subrack

Step 3 Choose Add Subrack.

The Add Subrack dialog box is displayed, as shown in Figure 2 .

Figure 2 Adding a subrack

Table 2 describes the parameters in the Add Subrack dialog box.

Table 2 Parameters in the Add Subrack dialog box

ParameterDefault

ValueDescription

Subrack Type -

Type of subrack

The options are GEPS and GTCS.

OPC - Originating signaling Point Code


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Step 4 Set Subrack Type andOPC, and then clickFinish.

----End

Verification

Additional Information

The BSC6000 subrack consists of the GMPS, GEPS, and GTCS. The principles of

subrack configuration are as follows:

The GMPS, GEPS, and GTCS are configured in sequence.

At least one GMPS and one GTCS must be configured.

All the GTCSs must be configured in the local cabinet or in the remote cabinet.

Each subrack must be configured with a fan box..

3. Adding a Power Distribution Box

Task Description

Purpose To add a power distribution box

Mandatory orOptional

Mandatory

PrerequisitesThe subrack that controls the power distribution box is already

configured.

Remarks None

Procedure

Table 1 lists an example of the configurations of a power distribution box.

Table 1 Example of the configurations of a power distribution box


Cabinet No. 0 BSC internal planning

Management

Subrack No.0 BSC internal planning

To add a power distribution box, do as follows:


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Step 1 On the BSC Device Panel tab page, select a cabinet from the Current Cabinet

drop-down list.

Step 2 Right-click in the POWER BOX area.


Figure 1 Choosing Add Power

Step 3 Choose Add Power.

The Add PowerBox dialog box is displayed, as shown in Figure 2 .

Figure 2 Adding a power distribution box


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Table 2 describes the parameters in the Add PowerBox dialog box.

Table 2 Parameters in the Add Power Box dialog box


Cabinet No. Current cabinet number Number of the cabinet where the currbox is located

Management Subrack No.

Minimum serial number ofthe subrack among all the

subracks in the current

cabinet

Number of the subrack that manages t

box

Step 4 Set Cabinet No. andManage Subrack No., and then clickFinish.

----End

Verification


Each cabinet is configured with a power distribution box. The power distribution box

provides lightning protection and overcurrent protection for the two -48 V power inputs.It also provides six groups of -48 V and RTN power outputs for the functional modules in

the cabinet. One -48 V output and one RTN output form a group.

The power distribution box detects the input voltage and the output power, and generates

an alarm when a fault occurs.

4. Configuring the Subrack-OSP Mapping

Task Description

Purpose To configure an OSP for a subrack

Mandatory or

OptionalMandatory

Prerequisites The OSPs exist.

Remarks The OSP must be configured on the basis of the OSP planning.

Procedure

Table 1 lists an example of the configurations of the subrack-OSP mapping.

Table 1 Example of the configurations of the subrack-OSP mapping


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Subrack No. 0 BSC internal planning

OSP 11 Network planning

Note

You must configure the SS7 signaling points before configuring the subrack-OSP

mapping.

For details, refer to Configuring SS7 Signaling Points.

To configure the subrack communication link, do as follows:



Figure 1 Choosing Configure Subrack-OSP Mapping

Step 2 Choose Configure Subrack-OSP Mapping.

The Configure Subrack-OSP Mapping is displayed, as shown in Figure 2 .


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Figure 2 Configuring the subrack-OSP mapping

Step 3 Select an OSP, and then clickFinish

5. Adding a Board

Task Description

Purpose To add a board

Mandatory or

OptionalMandatory

PrerequisitesThe subrack where a board is to be added exists and the subrack

has empty slots.

Remarks None

Procedure

Table 1 lists an example of the configurations of a BSC board.

Table 1 Example of the configurations of a BSC board



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Board Type GEIUB BSC internal planning

Active/Standby

ModeSelected BSC internal planning

Caution:

You can delete a board and then add a board to modify the active/standby attribute of a

board. You need to pay attention to the following:

When the BSC6000 internal network is normal, you need to synchronize data if

the data does not take effect after you add a board. For details, refer to section"Checking Data Consistency and Synchronizing Data."

When the BSC6000 internal network is disrupted or the Ethernet cable is not

installed, you need to check data consistency if the network restores after youdelete a board and then add a board. If the data is inconsistent, you have to reset

the board.

NOTE:

This topic describes how to add a board in the GMPS.

To add a board in the GMPS, do as follows:

Step 1 On the BSC Device Panel tab page, select a cabinet from the Current Cabinet

drop-down list.

Step 2 Right-click an empty slot in the subrack area.


Figure 1 Choosing Add Board

Step 3 Choose Add Board.

The Add Board dialog box is displayed, as shown in Figure 2 .


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Figure 2 Adding a board

NOTE:

The boards displayed in the Add Board dialog box depend on the boards already configured in the

neighbor slots.

Table 2 describes the parameters in the Add Board dialog box.

Table 2 Parameters in the Add Board dialog box


Board Type -

The GMPS supports three types of boards:

GEIUB/GEIUB, GEIUP/GEIUP, and

GEIUT/GEIUT.

Active/Standby

Mode

Selected

When the check box is selected, itindicates that two boards are added.

The board in the even number slot is

the active board and the board in the

odd number slot that follows the even

number slot is the standby board. When the check box is deselected, it

indicates that only one board is added

in the selected slot.

Step 4 Set Board Type andActive/Standby Mode, and then clickFinish.

----End


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Verification


Table 2 describes the BSC6000 board configuration.

Table 2 Board configuration

Board Configuration

GGCUConfigured in slots 12 and 13 of the GMPSWorking in

active/standby mode

GSCUConfigured in slots 6 and 7 of the GMPS, GEPS, or

GTCSWorking in active/standby mode

GTNUConfigured in slots 4 and 5 of the GMPS, GEPS, or

GTCSWorking in active/standby mode

GXPUM Configured in slots 0 and 1 of the GMPS or GEPS

GXPUC Configured in slots 8 and 9 of the GMPS

GEIUB/GOIUB Configured in slots 18C27 of the GMPS or GEPS

GEIUP/GOIUP Configured in slots 14 and 15 of the GMPS or GEPS

GEIUT/GOIUTConfigured in slots 16 and 17 of the GMPS or GEPS, and slots

14C17 of the GTCS

GEIUA/GOIUA Configured in slots 18C25 of the GTCS

GDPUC

If the GTCS contains optical interface boards, the GDPUC can

be configured in slots 0C3 and 8C13 of the GTCS.If the GTCScontains E1/T1 interface boards, the GDPUC can be configured

in slots 9C13.

The principles of board configuration are as follows:

The GGCU, GTNU, and GSCU can be deleted only when their subracks are

deleted.

The boards in the GMPS, GEPS, and GTCS are configured in sequence.

The GMPS or GEPS requires at least two GXPUMs, two GEIUBs or two

GOIUBs, and two GEIUTs or two /GOIUTs.

The GTCS requires at least two GDPUCs, two GEIUTs or two GOIUTs, and two

GEIUAs or two GOIUAs.


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6. Configuring an Ater Connection Path

Task Description

Purpose To configure an Ater connection path

Mandatory or

OptionalMandatory

Prerequisites

The subrack where the Ater connection path is to beestablished exists.

The GEIUT or GEIOT of the GMPS or GEPS exists.

The GEIUT or GOIUT of the GTCS exists.

The signaling points of the GMPS or GEPS are configured.

RemarksThe configuration of the Ater connection path can be started only

on the GEIUT or GEIOT of the GMPS or GEPS.

Procedure

Table 1 lists an example of the configurations of an Ater connection path for your

reference.

Table 1 Example of the configurations of an Ater connection path


BM Subrack No. 0 BSC internal planning

BM Slot No. 14 BSC internal planning

BM Port No. 0 BSC internal planning

TC Subrack No. 3 BSC internal planning

TC Slot No. 14 BSC internal planning

TC Port No. 0 BSC internal planning

NOTE:

This topic describes how to start the configuration of the Ater connection path on the

GEIUT.

To configure an Ater connection path, do as follows:

Step 1 On the BSC Device Panel tab page, right-click the target GEIUT in the GMPS or

GEPS.



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Figure 1 Choosing Configure Ater Connection Path

Step 2 Choose Configure Ater Connection Path.

The Configure Ater Connection Path dialog box is displayed, as shown in Figure 2 .

Figure 2 Configure Ater Connection Path dialog box

Step 3 ClickAdd.

The Add Ater Connection Path dialog box is displayed, as shown in Figure 3 .


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Figure 3 Adding an Ater connection path

Table 2 describes the parameters in the Add Ater Connection Path dialog box.

Table 2 Parameters in the Add Ater Connection Path dialog box


BM Subrack No.Number of the subrack where the Ater connection path is

to be established

BM Slot No.Slot number of the GEIUT/GOIUT where the Ater

connection path is to be configured

BM Port No.Port number of the GEIUT/GOIUT on the GMPS or

GEPS side

TC Subrack No. Number of the TC subrack

TC Slot No.Slot number of the GEIUT/GOIUT on the TC subrackside

TC Port No.Port number of the GEIUT/GOIUT on the TC subrack

side

Step 4 Set the parameters, and then clickOK to return to the Configure Ater

Connection Path dialog box.

Step 5 ClickFinish.


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7. Adding an Ater OML

Task Description

Purpose To configure an Ater Operation and Maintenance Link (OML)

Mandatory or

OptionalMandatory

Prerequisites

The GTCS is configured on the MSC side..

The Ater connection path is already configured.

Remarks

The Ater OML is not required when the GTCS is

configured on the BSC side.

The configuration of the Ater OML can be started only on

the GEIUT or the GOIUT of the local GMPS.

The entire BSC requires an active and a standby AterOMLs. The timeslot masks of the two OMLs must be the

same.

Procedure

Table 1 lists an example of the configurations of an Ater OML for your reference.

Table 1 Example of the configurations of an Ater OML


Logical Group No. 0 BSC internal planning

Ater Connection Path

Index0 BSC internal planning

BM Subrack No. of

Ater ConnectionPath

0 BSC internal planning

Timeslot Mask TS1, TS2-TS17 BSC internal planning

NOTE:

This topic describes how to start the configuration of the Ater OML on the GEIUT.

To configure an Ater OML, do as follows:

Step 1 On the BSC Device Panel tab page, right-click the target GEIUT in the GMPS.



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Figure 1 Choosing Configure Ater OML

Step 2 Choose Configure Ater OML.

The Configure Ater OML dialog box is displayed, as shown in Figure 2 .

Figure 2 Configure Ater OML dialog box

Step 3 ClickAdd.

The Add Ater OML dialog box is displayed, as shown in Figure 3 .


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Figure 3 Adding an Ater OML

NOTE:

The recommended principle for selecting timeslots is as follows:

If no more than two BM subracks are configured, select TS1 and any 16 consecutive

timeslots.

If more than two BM subracks are configured, select 31 timeslots except TS0.

Table 2 describes the parameters in the Add Ater OML dialog box.

Table 2 Parameters in the Add Ater OML dialog box


Logical Group No. 0 Number of the logical group

Ater Connection Path IndexIndex of the first Ater connection

path configured in the current

GEIUT

Index of the connection path of the

Ater OML

BM Subrack No. of Ater

Connection PathFlexible

Number of the BM subrack where

the Ater connection path is located

Timeslot Mask -

Timeslot mask of the Ater OML

The number of timeslots is directly

proportional to the system loading

rate. The number of timeslots can

be regulated if necessary.


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NOTE:

For the description of the parameters in the Add Ater OML dialog box, refer to the

HUAWEI BSC6000 Base Station Controller Data Configuration Reference.

Step 4 Set the parameters, and then clickOK to return to the Configure Ater OMLdialog box.

Step 5 ClickFinish.

8. Adding an Ater Signaling Link

Task Description

Purpose To add an Ater signaling link

Mandatory or

OptionalMandatory

Prerequisites

The GTCS is configured on the MSC side..

The Ater connection path is already configured.

The DSP exists.

The GXPUM in the GMPS or GEPS exists.

Remarks

The Ater signaling link is not required when the GTCS isconfigured on the BSC side.

The configuration of the Ater signaling link can be started

only on the GEIUT or GOIUTof the GTCS.

Each signaling point can be configured with a maximum ofsixteen 64 kbit/s Ater signaling links.

The 64 kbit/s Ater signaling link and the 2 Mbit/s Ater

signaling link cannot coexist. You have to select one of

them.

Each GEIUTor GOIUT can be configured with a maximum

of eight 2 Mbit/s Ater signaling links. The total bandwidth

cannot exceed 4 Mbit/s. The rate of the Ater signaling must be the same as that of

the SS7.

Procedure

Table 1 lists an example of the configurations of an Ater signaling link for your

reference.


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Table 1 Example of the configurations of an Ater signaling link



Index


BM Subrack No. of

Ater ConnectionPath


Rate Type 64 kbit/sNegotiated with the peer

end

Satellite Flag No BSC internal planning

Timeslot Mask TS9 BSC internal planning

CAUTION:

If the rate type of the Ater signaling link is changed, the Ater interface board GEIUT or

GOIUT of the GMPS, GEPS, and GTCS must be reset.

NOTE:

This topic describes how to start the configuration on the GEIUT.

To add an Ater signaling link, do as follows:

Step 1 On the BSC Device Panel tab page, right-click the target GEIUT in the GTCS.


Figure 1 Choosing Add Ater Signaling Link

Step 2 Choose Add Ater Signaling Link.

The Add Ater Signaling Link dialog box is displayed, as shown in Figure 2 .


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Figure 2 Add Ater Signaling Link dialog box

Step 3 ClickAdd.

The Add Ater Signaling Link dialog box the updated information, as shown in Figure 3

.

Figure 3 Adding an Ater signaling link


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NOTE:

The added Ater signaling link can be configured with only one timeslot.

Table 2 describes the parameters in the Add Ater Signaling Link dialog box.

Table 2 Parameters in the Add Ater Signaling Link dialog box



Index

Index of the first Ater

connection path configured in

the current GEIUT

Index of the connection path of

the Ater signaling link

BM Subrack No. of

Ater Connection PathFlexible

Number of the BM subrack

where the Ater connection pathis located

Rate Type 64 kbit/s or 2 Mbit/s Rate type of the Ater signalinglink

Support Satellite Flag No

Whether the satellite flag is

supported or not

The default value indicates thatsatellite transmission is not

supported.

Timeslot Mask -Timeslot mask of the Atersignaling link

NOTE:

For the description of the parameters in the Add Ater Signaling Link dialog box, refer to

theHUAWEI BSC6000 Base Station Controller Data Configuration Reference.

Step 4 Set the parameters, and then OK to return to the Add Ater Signaling Link dialog

box.

The Add Ater Signaling Link dialog box displays the information, as shown in Figure 4


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Figure 4 Added Ater signaling link

Step 5 ClickFinish.

----End

9. Configuring an E1 on the A Interface

Task Description

Purpose To configure an E1 on the A interface

Mandatory or

OptionalMandatory

PrerequisitesThe GEIUA or GOIUA where the E1 is to be added is already

configured.

Remarks The configuration of an E1 on the A interface can be started only


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on the GEIUA or GOIUA of the GTCS.

Procedure

Table 1 lists an example of the configurations of an E1 on the A interface.

Table 1 Example of the configurations of an E1 on the A interface


Subrack No. 1 BSC internal planning

Slot No. 21 BSC internal planning

Port No. 0Negotiated with the peer

end

The Starting CIC 0 BSC internal planning

To configure an E1 on the A interface, do as follows:

Step 1 On the BSC Device Panel tab page, right-click the target GEIUA in the GTCS.


Figure 1 Choosing Configure A Interface E1

Step 2 Choose Configure A Interface E1.

The Configure A Interface E1 dialog box is displayed, as shown in Figure 2 .


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Figure 2 Configure A Interface E1 dialog box

Step 3 ClickAdd.

The Add A Interface E1 dialog box is displayed, as shown in Figure 3 .

Figure 3 Adding an E1 on the A interface

Table 2 describes the parameters in the Add A Interface E1 dialog box.


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Table 2 Parameters in the Add A Interface E1 dialog box


Subrack No.Number of the subrack

where the GEIUA islocated

Number of the subrack where the E1 on

the A interface is located

Slot No.

Number of the slot

where the GEIUA is

located

Number of the slot where the E1 on theA interface is located

Port No. -Number of the port assigned to the E1 onthe A interface

The Starting CIC -

The starting CIC identifies timeslot 0 of

the E1.

If you select Auto Calculate CIC, the

starting CIC plus one successivelyidentifies timeslots 1-31 of the E1. Forexample, the starting CIC plus one

identifies timeslot 1 and the starting CIC

plus two identifies timeslot 2.

If you deselect Auto Calculate CIC, you

can specify a CIC number.

NOTE:

For the description of the parameters in the Add A Interface E1, refer to theHUAWEI

BSC6000 Base Station Controller Data Configuration Reference.

Step 4 Set the parameters in the Add A Interface E1 dialog box.

Step 5 Click the CIC Prop tab.

The CIC Prop tab page is displayed, as shown in Figure 4 .


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Figure 4 Configuring the CIC Attributes

Step 6 Set the parameters, and then clickOK to return to the Configure A Interface E1

dialog box.

Step 7 ClickFinish.

----End

10. Configuring an SS7 Signaling Link

Task Description

Purpose To configure an SS7 signaling link

Mandatory or

OptionalMandatory

Prerequisites

The SS7 signaling points, Ater connection path, and an E1 on the

A interface are already configured.

The GXPUM in the GMPS or GEPS to which the SS7 signalinglink connects is already configured.

Remarks

The configuration of the SS7 signaling link can be started only on

the GEIUA or GOIUA of the GTCS.

Each signaling point can be configured with a maximum of

sixteen 64 kbit/s SS7 signaling links.

Each GMPS or GEPS can be configured with a maximum of

eight 2 Mbit/s SS7 signaling links.


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The rate of the SS7 must be the same as that of the Ater signaling.

Procedure

Table 1 lists an example of the configurations of an SS7 signaling link.

Table 1 Example of the configurations of an SS7 signaling link



Index1 BSC internal planning

BM Subrack No. ofAter Connection Path


Rate Type 64 kbit/s Negotiated with the peerend

A Subrack No. 3 BSC internal planning

A Slot No. 21 BSC internal planning

A Port No. 0Negotiated with the peer

end

Ater Timeslot Mask TS10 BSC internal planning

A Timeslot Mask TS1Negotiated with the peer

end

SLC 1Negotiated with the peer

end

SLC Send 1Negotiated with the peerend

CAUTION:

If the rate type of the SS7 signaling link is changed, the Ater interface board GEIUT or

GOIUT of the GMPS, GEPS, and GTCS must be reset.

NOTE:

This topic describes how to start the configuration on the GEIUA.

It is recommended that the number of the timeslots of each 2 Mbit/s SS7 signaling link is

the same, thus achieving optimal load sharing

To configure an SS7 signaling link, do as follows:


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Step 1 On the BSC Device Panel tab page, right-click the target GEIUA in the GTCS.


Figure 1 Choosing Configure SS7 Signaling Link

Step 2 Choose Configure SS7 Signaling Link.

The Configure SS7 Signaling Link dialog box is displayed, as shown in Figure 2 .

Figure 2 Configure SS7 Signaling Link dialog box

Step 3 ClickAdd.


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The Add SS7 Signaling Link dialog box is displayed, as shown in Figure 3 .

Figure 3 Adding an SS7 signaling link

NOTE:

The number of timeslots on the A interface must be the same as that on the Ater interface.

Table 2 describes the parameters in the Add SS7 Signaling Link dialog box.

Table 2 Parameters in the Add SS7 Signaling Link dialog box


Ater Connection

Path Index

Ater connection path

index configured inthe current TC subrack

The index of the first Ater connection

path connecting to the GMPS or GEPS

BM Subrack No. of

Ater ConnectionPath

FlexibleNumber of the BM subrack where theAter connection path is located

Rate TypeRate of the configured

Ater signaling linkRate type of the SS7 signaling link

A Subrack No. Subrack number of the Number of the subrack where the GEIUA


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GEIUA/GOIUA is located

A Slot No.Slot number of the

GEIUA/GOIUA

Number of the slot where the GEIUA is

located

A Port No.

First E1 port

configured on the Ainterface

Port number of the GEIUA

Ater TS Set -Ater interface timeslots used by the SS7

signaling link

A TS Set -A interface timeslots used by the SS7

signaling link

NOTE:

For the description of the parameters in the Add SS7 Signaling Link, refer to the

HUAWEI BSC6000 Base Station Controller Data Configuration Reference.

Step 4 Set the parameters in the Add SS7 Signaling Link dialog box.

Step 5 Click the MTP3 tab.

The MTP3 tab page is displayed, as shown in Figure 4 .


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Figure 4 MTP3 tab page

Table 3 describes the parameters on the MTP3 tab page.

Table 3 Parameters on the MTP3 tab page


GXPUM Slot No. 0 Slot number of the GXPUM

SLC - Signaling Link Code

Satellite Flag No

Whether satellite transmission is

supported .

The default value indicates that

satellite transmission is not supported.

SLC Send - Sending the SLC

Priority 0 -

Congestion Start Thrsh. 80 Start threshold of congestion

Congestion End Thrsh 70 End threshold of congestion

Test Code 165 -

Test Code Length 6 Length of the test code

NOTE:

For the description of the parameters in the MTP3, refer to theHUAWEI BSC6000 BaseStation Controller Data Configuration Reference.


Link dialog box.

Step 7 ClickFinish.


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11. Configuring the Line Clock

Task Description

Purpose

To configure the line clock for a subrack

For the TC subrack, the line clock extracted on the A

interface is used as the reference clock of this subrack.

For the GMPS subrack, the line clock extracted on the Ater

interface is used as the reference clock of this subrack or the

system clock.

Mandatory or

Optional

When the GTCS is placed on the BSC side: optional .

When the GTCS is placed on the MSC side: mandatory.

Prerequisites

The subrack is already configured with the required interfaceboard.

The interface board has a sub board.

Before configuring the line clock for the GTCS subrack, you

need to configure the GEIUA or GOIUA interface board.

Before configuring the line clock for the GMPS subrack,

you need to configure the GEIUT or GOIUT interface board.

Remarks None

Procedure

Table 1 lists an example of the configurations of the line clock parameters for yourreference.

Table 1 Example of the configurations of line clock parameters


Line No. LINE0 BSC internal planning

Line Clock Type 8K BSC internal planningBoard Slot No. 26 BSC internal planning

Board Port No. 11 BSC internal planning

NOTE:

This topic describes how to configure the line clock for the GTCS.Before configuring theline clock for the GTCS subrack, you need to configure the GEIUA or GOIUA interface

board


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The line clock of a GMPS subrack must be configured on the Ater connection path of this

subrack.

The line clock of a GTCS subrack must be configured on the A interface E1 of this

subrack.

The E1 interface board can be configured with two line clocks: line 0 and line 1. The

optical interface board can be configured with only one line clock and the line clock must

be configured on port 0.

To configure the line clock for the GTCS, do as follows:

Step 1 On the BSC Device Panel tab page, right-click the edge of the GTCS.

A shortcut menu is displayed, as shown in Figure 1.

Figure 1 Choosing Configure Line Clock

Step 2 Choose Configure Line Clock.

The Configure Line Clock dialog box is displayed, as shown in Figure 2.

Figure 2 Configuring the line clock


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Table 2describes the parameters in the Configure Line Clock dialog box.

Table 2 Parameters in the Configure Line Clock dialog box


Line No. LINE0 Number of the line clock

Board Slot No.

Minimum number of

the slot in which theGEIU or GOIU is

located

Number of the slot where the interface

board in which the line clock is configured

resides

Board Port No. 0Number of the port on the interface board

This port is used as the port of the lineclock.

Backup Port No. 1

Number of the backup port on the

interface board .

This port is used as the backup port of the

line clock.

Step 3 Set the parameters, and then clickAdd.

NOTE:

The Add button changes into the Delete button. You can clickDelete to delete a line

clock.

----End

Verification

On the BSC Device Panel tab page, double-click the interface board to check whetherthe board Attributes, such as Line0 Port No., Line1 Port No., Line0 Bkp Port No., and

Line1 Bkp Port No., are consistent with the required settings.


The principles of line clock configuration are as follows:

One subrack can be configured with a maximum of two line clocks. Huawei recommends that the line clock be configured in a cascade interface

board.

The active port and standby port of each line clock cannot be the same one.

Do not configure line clocks for GEPS subrack.


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12.Configuring the System Clock

Task Description

Purpose To configure the system clock

Mandatory or

OptionalMandatory

Prerequisites

The GGCU is functional.

The GMPS is configured with the line clock.

Remarks All the configured data takes effect in the GGCU.

Procedure

Table 1 lists an example of the configurations of system clock parameters for yourreference.

Table 1 Example of the configurations of system clock parameters


Source No. 1 BSC internal planning

Source Type LINE0 BSC internal planning

Source Sub-type 8K_HZ BSC internal planning

To configure the system clock, do as follows:



Figure 1 Choosing Configure System Clock


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Step 2 Choose Configure System Clock.

The Configure System Clock dialog box is displayed, as shown in Figure 2.

Figure 2 Configuring the system clock

Caution

Do no set Source Type and Work Mode in one operation.

After setting Source Type, click Finish to exist, and then enter the Configure System

Clock dialog box again to set Work Mode.

Table 1 describes the parameters in the Configure System Clock dialog box.

Table 1 Parameters in the Configure System Clock dialog box

Parameter Default Value DescriptionSource No. 1234 Number of the clock source

Source Type NONE

Type of the clock source Source Type

consists ofBITS0, BITS1, LINE0, and

LINE1. NONE means that this parameter

is not configured.

Source Sub-type NONE IfSource Type is set to BITS0 or

BITS1, the options ofSource


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SubType are 2M_HZ and

2M_Bps.

IfSource Type is set to LINE0 orLINE1, the option ofSource

SubType is 8K_HZ.

NONE means that this parameter isnot configured.

Work Mode AutomaticConsists ofAutomatic, Manual, andFree

Run

Priority - Consists of1, 2, 3, and4

Step 3 Set the related parameters, and then clickFinish.

----End

Verification

Enter the Configure System Clock dialog box again, and the configured data isdisplayed. Check the data.


Clock Source

The BSC6000 provides two types of clock source.

Building Integrated Timing Supply (BITS) clock

Line clock

Table 2 describes the clock source.

Table 2 Clock source

Clock Source Description

BITS0

BITS1

Consists of2M_HZ and2M_Bps The anti-interference ability of2M_Bps is higher

than that of2M_HZ.

LINE0

LINE1

The clock extracted from the A interface is 8K_HZ. The8K_HZ signal transmits through the backplane of the

GGCU.

Priority of the Clock Source


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The BSC6000 provides four levels of clock source priority. Level 1 clock source has the

highest priority.

When configuring the clock source, pay attention to the following:

There is a one-to-one relationship between the clock source and the priority. The priority of a BITS clock is usually higher than that of a line clock.

If the system clock uses a line clock, the GMPS must have been configured with

the corresponding line clock.

The BSC6000 usually uses the line clock.

Current Clock Source and Clock Switch Policies

The BSC6000 requires only one clock source during operation. If the current clock

source fails, it has to be switched to a normal clock source. The clock source has three

work modes: AUTO, Manual, andFree Run.

Automatic: The system automatically selects the clock source that has the highest

priority.

For example, if the level 3 clock source fails, the level 4 clock source is used. When the

level 3 clock source recovers, the system automatically switches to the level 3 clocksource. If all the clock sources fail, the system retains the current state and switches to

AUTO mode after the clock sources recover.

Manual: The user specifies a clock source.

The system is not allowed to switch the clock resource even if the current clock sourcefails.

Free Run: initial work status of the system clock

13. Configuring the 8K Reference Clock

Task Description

Purpose To configure a reference clock for a subrack

Mandatory or

OptionalMandatory

Prerequisites

The GSCU exists.

The related line clock is configured.

The GTCS is configured with an A interface board and an A

interface E1.


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Remarks

A reference clock must be configured after the GSCU in a

subrack is configured. If the clock is not configured, the

services on the subrack will be affected.

The configuration of the 8K reference clock is based on the

network planning.

Procedure

Table 1 lists an example of the configuration of the 8K reference clock for your

reference..

Table 1 Example of the configuration of the 8K reference clock


8K Reference Clock

Type

GGCUBackplane

BSC

internal planning

NOTE:

This topic describes how to configure the 8K reference clock for the GMPS.

To configure the 8K reference clock for the GMPS, do as follows:

Step 1 On the BSC Device Panel tab page, right-click the edge of the GMPS.


Figure 1 Choosing Configure 8K Reference Clock


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Step 2 Choose Configure 8K Reference Clock.

The Configure GSCU 8K Reference Clock dialog box is displayed, as shown in Figure

2.

Figure 2 Configuring the GSCU 8K reference clock

Step 3 Set 8K Reference ClockType, and then clickFinish.

----End

Verification

On the BSC Device Panel tab page, double-click the GSCU to check the setting of the8K reference clock.


Different subracks have different 8K reference clocks.

Table 2 lists the subracks and their 8K reference clocks.

Table 2 Subracks and their 8K reference clocks

Subrack 8K Reference Clock

Local GMPS GGCU BACK

Local GEPS GGCU FACE

Remote GTCS Line clock configured in the subrack

When configuring the 8K reference clock for the TC subrack, you can select Invalid orLINE CLOCK. If you select LINE CLOCK, none of the line clocks can be deleted.


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Adding BTS

Task Description

Purpose To add a BTS

Mandatory or

OptionalMandatory

Prerequisites

The upper-level BTS must have idle ports.

IIf you want to add a BTS on the GEIUB or GOIUB boards

of the BSC, the GEIUB or GOIUB boards must beconfigured on the BSC and there must be idle ports on the

GEIUB or GOIUB boards. In addition, the subrack where

the GEIUB boards are located must have GXPUM boards,and the subrack must be configured with original signaling

points (OSPs).

Remarks

The number of BTS levels cannot exceed seven.

The number of cells under a BTS cannot exceed 12. A cell

supports a maximum of 24 TRXs.

The maximum number of TRXs that a BTS supports varies

with the BTS type.

Procedure

Table 1 lists an example of the configurations of a BTS for your reference.

Table 1 Example of the configurations of a BTS


Site Name BTS1 Network planning

Site Type BTS3012 Network planning

Upper-Level PortNo.

1 Network planning

Multiplexing Mode 4:1 Network planning

Site Attributes

Configuredaccording to

actual

situations

Network planning

Cell Name Cell1 Network planning


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Frequency Band GSM900 Network planning

MCC 460 Network planning

MNC 10 Network planning

LAC 6 Network planningCI 123 Network planning

BCC 0 Network planning

NCC 0 Network planning

Cell ExtType Normal Cell Network planning

Cell Type Normal Cell Network planning

Freq Config 2, 3 Network planning

TRX ConfigTRX 1, TRX

22 Network planning

Frequency Hopping No FH Network planning

8PSK Power Level 0 Network planning

NOTE:

This topic describes how to add a BTS3012 BTS1 on the GEIUB board.

To add a BTS, do as follows:

Step 1 Log in to the BSC6000 Local Maintenance Terminal in online mode.

The BSC6000 Local Maintenance Terminal window is displayed.

Step 2 On the Management Tree tab page, right-click a BTS.



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Figure 1 Choosing Add Site (1)

NOTE:

You can also right-click a GEIUB/GOIUB board and choose Add Site on the shortcut

menu to add a BTS, as shown in Figure 2 .

Figure 2 Choosing Add Site (2)

Step 3 Choose Site Operation > Add Site.

The Add Site dialog box is displayed, as shown in Figure 3 .

Figure 3 Add Site dialog box

Step 4 ClickAdd Site.

The Add New Site dialog box is displayed, as shown in Figure 4 .


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Figure 4 Add New Site dialog box

Table 2 describes the parameters in the Add New Site dialog box.

Table 2 Parameters in the Add New Site dialog box


Site IndexAn unique integer

ranging from 0 to 2047

A unique index number of the BTS

under the BSC

The number cannot be modified.

Site Name None

A unique name of the BTS under the

BSC

The name contains a maximum of 33

characters and the name can be

modified.

Site Type BTS30

There are nine BTS types: BTS30,

BTS312, BTS3012A, BTS3001C,BTS3002C, BTS3012, BTS3012AE,

BTS3006C and BTS3006A. The BTS

type cannot be modified after setup.

Upper-Level Port

No.GEIUB/GOIUB port 1

Indicates the idle ports of the upper-level object, that is, the GEIUB/GOIUB

ports or the ports of the upper-level

BTS.

MultiplexingMode

4:1There are four multiplexing modes: 1:1,2:1, 3:1, and 4:1.


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NOTE:

Generally, you need to set only Site Name andSite Type. For other parameters, retain

the default settings.

Step 5 Set the parameters.

NOTE:

For example, type BTS1 in the Site Name textbox and set the Site Type to BTS3012, as

shown in Figure 5 .

Figure 5 Setting parameters

Step 6 ClickOK.

The Add Site dialog box displays the updated information, as shown in Figure 6 .


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Figure 6 Added BTS in the Site View box

Step 7 ClickNext.

The Add Site Wizard dialog box displays the updated information, as shown in Figure 7

.

Figure 7 Updated information in the Add Site dialog box


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Step 8 Select BTS1 and clickAdd Cell.

The Add New Cell dialog box is displayed.

Step 9 Set the parameters according to the actual situation.

NOTE:

Generally, you need to set only Cell Name andCell Type.

For example, set Cell Name to Cell1 andCell Type to GSM900. For other parameters,

retain the default settings, as shown in Figure 8 .

Figure 8 To add more than one cell at a time, set Number of Cells.

NOTE:

To add more than one cell at a time, set Number of Cells.

Step 10 ClickOK.



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Figure 9 Added cell in the Cell View box

Step 11 ClickNext.

The Add Site dialog box displays the Cell List box, as shown in Figure 10 .

Figure 10 Configuring cell attributes

Step 12 ClickCell Attributes.


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The Set Attributes of Cell dialog box is displayed, as shown in Figure 11 .

Figure 11 Set Attributes of Cell dialog box

Step 13 Set the parameters.

NOTE:

For example, set the Cell Identity (CI) ofCell1 to 123, add two TRXs (TRX 1 andTRX

22) to Cell1, and assign frequencies 2 and3 to TRX 1 and TRX 22 respectively. Figure12 shows the Set CellAttributes dialog box after the previous settings.

The CI of a cell in a BTS must be unique.

For the settings of TRXs and frequencies, refer to Cell Data Configuration.

If you select GPRS Support, you must ensure that the PCU is configured. If the BTS

version does not support the GPRS or the GPRS service is not available, do no select

GPRS Support.


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Figure 12 Adding TRXs

Step 14 ClickOK to return to the Add Site dialog box.

Step 15 ClickNext.



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Figure 13 Added site in the Site List box

NOTE:

For details about configuring secondary chains, refer to "Adding or Deleting a

Secondary Chain."

For details about configuring timeslots manually, refer to "Assigning Abis Timeslots

Manually."

Step 16 Select a BTS from the Site List box, and then clickSite Attributes.

The Site Device Attributes dialog box is displayed, as shown in Figure 14 .


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Figure 14 Site Device Attributes dialog box

NOTE:

The downlink TRXs of the DDPU must be configured. For combined cabinets or cabinet

groups, the BTS inner connections must be configured.

In the Site Device Attributes dialog box, you can configure BTS inner connections and

BTS attributes, add or delete boards, and configure board attributes.

For details about adding or deleting boards, refer to "Adding or Deleting a BTS

Board."

For details about configuring board attributes, refer to "Configuring BTS BoardAttributes."

For details about configuring BTS inner connection, refer to "Establishing

Connections Between BTS Cabinet Groups."

For details about configuring BTS attributes, refer to "Configuring BTS

Attributes."


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Step 17 Set the related attributes, and then clickOK to return to the Add Site Wizard

dialog box.

Step 18 ClickFinish.

The GBAM checks the configured data.

If the data passes the check, the data takes effect on each service board.

If the check fails, error information is displayed. You can modify the settings

according to the error information.

----End

Verification

To verify the configuration, do as follows:

Step 1 On the Management Tree tab page, click the root node ofBSC6000.

The added BTS is displayed.

Step 2 Click the added BTS.

The Site Device Panel tab page is displayed.

Step 3 Check whether the displayed configurations meet your requirements.

----End


You can refer to the following documents or sections when adding a BTS.

To configure cell attributes, refer to "configure cell Attributes."

To configure TRX attributes, refer to "Adding TRXs"

For the details about manual assignment of Abis timeslots, refer to "Assigning

Abis Timeslots Manually."

Adding or Deleting a Secondary Chain

Task Description

Purpose To add or delete an secondary chain for a BTS

Mandatory or

OptionalOptional


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Prerequisites

The BTS has idle ports.

The GEIUB or GOIUB board of the BSC or the upper-level

BTS has idle ports..

Remarks Secondary chains cannot be added between the BTSs that areestablished on the GEIUB or GOIUB board in different subracks.

Procedure

Adding a Secondary Chain

Table 1 lists an example of the configurations of a site chain for your reference.

Table 1 Example of the configurations of a site chain


GE(O)IUB Subrack

No.0 BSC internal planning

GE(O)IUB Slot No. 16 BSC internal planning

GE(O)IUB Port No. 0 BSC internal planning

Site Port No. 1 BSC internal planning

NOTE:

This topic describes how to add a secondary chain to the GEIUB board ofBTS1.

To add a secondary chain, do as follows:

Step 1 On the Management Tree tab page, right-click a BTS.



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Figure 1 Choosing Add or Delete Site Multiple Chain

Step 2 Choose Add or Delete Site Multiple Chain.

The Add & Delete Site Chain dialog box is displayed, as shown in Figure 2 .

Figure 2 Add & Delete Site Chain dialog box

Step 3 Select the BTS, and then clickAdd Delete Chain.

The Add and Delete Site Chain dialog box is displayed, as shown in Figure 3 .


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Figure 3 Add and Delete Site Chain dialog box

Step 4 ClickNew Port.

NOTE:

The Site Port button and the GEIUB Port button are not available in this operation.

To configure the site port and the GEIUB port, refer to "Adding a BTS."

The Add Site Slave Chain dialog box is displayed, as shown in Figure 4 .

Figure 4 Add Site Slave Chain dialog box

NOTE:

The first-level BTS can be connected to only the GEIUB board of the BSC.

A non-first-level BTS can be connected to the idle ports of only a single GEIUB

board.

Step 5 Set GEIUB Port No. andSite Port No., and then clickOK.

The Add and Delete Site Chain displays the updated information, as shown in Figure 5 .


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Figure 5 Adding a secondary chain

Step 6 ClickOK to return to the Add & Delete Site Chain dialog box.

Step 7 ClickFinish.

----End

Deleting a Secondary Chain

NOTE:

This topic describes how to delete SitePort 1 shown in Figure 5.

To delete a secondary chain, do as follows:

Step 1 Perform steps 1 through 3 described in Adding a Secondary Chain.

Step 2 In the Add and Delete Site Chain dialog box, select SitePort 1 from the Site

Port List box, and then clickDelete Port.

An information box is displayed.

Step 3 ClickYes.

----End

Verification



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Step 1 Perform steps 1 through 3 described in Adding a Secondary Chain.

The Add and Delete Site Chain dialog box is displayed.

Step 2 In the Site Port List box, check whether the added port is displayed.

----End

Assigning Abis Timeslots Manually

Task Description

Purpose To manually assign Abis timeslots

Mandatory orOptional Optional

Prerequisites

Each BTS cabinet has in-port objects.

There are required timeslot resources.

RemarksYou need to reset the BTS after clearing the timeslots that are

assigned manually.

Procedure

Table 1 lists an example of the configurations of the Abis timeslots.

Table 1 Example of the configurations of the Abis timeslots


Timeslot No. 10 BSC internal planning

Sub-Timeslot No. 2 BSC internal planning

NOTE:

This topic describes how to manually assign the timeslots of TCH2 forBTS1.

To manually assign Abis timeslots, do as follows:

Step 1 On the Management Tree tab page, right-clickBTS1.



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Figure 1 Choosing Manually Assign Site Abis Timeslot

Step 2 Choose Manually Assign Site Abis Timeslot.

The Manual Allocate TS dialog box is displayed, as shown in Figure 2 .

Figure 2 Manual Allocate TS dialog box

Step 3 Select BTS1, and then clickManually Assign Timeslots.

The Manually Set Site TS dialog box is displayed, as shown in Figure 3 .


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Figure 3 Manually Set site TS dialog box (1)

Step 4 Click the root node ofRSL1.

RSL1 expands, as shown in Figure 4 .


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Figure 4 Manually Set site TS dialog box (2)

NOTE:

TCH0 andTCH1 are concealed because they are occupied by a BCCH and SDCCHrespectively.

The general principles of BTS timeslot assignment are as follows:

Timeslots 0C7 of in-ports cannot be used.

The timeslots of different BTSs cannot be assigned in one continuous 64 kbit/s

bandwidth.

Table 2 lists the detailed principles of BTS timeslot distribution.

Table 2 BTS timeslots and their assignment principlesTimeslot

TypeAssignment Principle

OML

Operation and maintenance linkOne BTS is assigned with one 64 kbit/s

OML. The OML timeslot in a cabinet group is always set to timeslot

248 on port 0. The OML can be multiplexed with the RSL only.

RSLRadio signaling linkOne TRX is assigned with one 64 kbit/s RSLTheRSL can be multiplexed with OML and RSL in a cabinet group. The


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RSL always connects to the in-port of the cabinet where the TRX

resides.

TCHTraffic channelRate: 16 kbit/sIn transparent transmission, the positions

of TCH timeslots in a 64 kbit/s link must be consistent.

Idle Idle timeslotRate: 16 kbit/sIdle timeslots and TCH timeslots can beassigned in a 64 kbit/s bandwidth.

SemiMonitor timeslot Rate: 8 kbit/s, 16 kbit/s, 32 kbit/s, or 64 kbit/sMonitor

timeslots cannot be multiplexed.

Step 5 Select TCH2, and then clickManual Set.

The Set TS: TRX No. [1] Channel No. [2], TS Type: TCH, as shown in Figure 5 .

Figure 5 Setting the OML (1)

Step 6 Set Timeslot No. to 10 and set Sub-Timeslot No. to 2, as shown in Figure 6 .


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Figure 6 Setting the OML (2)

NOTE:

If the timeslot that you select is occupied, a system message will be displayed.

Step 7 ClickAssign Timeslot..

Step 8 ClickOK to return to the Manually Assign Site Timeslot dialog box.

Step 9 ClickOK to return to the Manually Assign Site Abis Timeslot dialog box.

Step 10 ClickFinish.

----End

Verification


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After the previous setup is complete, repeat steps 1 through 2 to display the Manually

Assign Site Abis Timeslot dialog box. Then check whether the settings of the manually

assigned timeslots are consistent with your requirements.


After the timeslots are manually assigned, browse the configured timeslots as follows:

Step 1 In the Manually Assign Site Timeslot dialog box, select TCH2 and clickBrowse

Timeslot,

The Set TS: TRX No. [1] Channel No. [2], TS Type: TCH, as shown in Figure 7.

Figure 7 Browsing all the BTS timeslots

Step 2 View the settings of the timeslot.

Step 3 ClickOK to return to the Manually Assign Site Timeslot dialog box.

Step 4 ClickBrowse All Timeslot to view all the timeslots.


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The Browse All Site's Timeslot dialog box is displayed, as shown in Figure 8

.

Figure 8 Browsing BTS port timeslots

Step 5 Select Port 0 ofTS and clickBrowse Port Timeslots.

The Site Port TS Browse dialog box is displayed, as shown in Figure 9.

Figure 9 Browsing BTS port timeslots

Table 3 describes the parameters in the Site Port TS Browse dialog box.

Table 3 Parameters in the Site Port TS Browse dialog box


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Index Index of a timeslot on the E1 portValue range: 0C255

Belong Site BTS where a timeslot belongs

Port No. Number of a BTSTS No. Number of a timeslot on the E1 port (in 64 kbit/s)

SubTS No. Number of a sub-timeslot (in 8 kbit/s) under a 64 kbit/s timeslot

TRX No. Number of a TRX255 stands for a non-TRX object.

Chan No. Number of a channel255 stands for a non-channel object.

OUT Port No. Number of an out-port255 stands for an invalid parameter.

OUT TS No. Number of a timeslot on an out-port

TS TypeConsists of the following:TCH: Traffic ChannelOML: Operation

and Maintenance LinkRSL: Radio Signaling LinkSemi: monitortimeslotIdle: idle timeslot

Vol Type Rate type of a timeslotUnit: kbit/s

Abis Mode Consists of manual mode and auto mode.

----End

Establishing Connections between BTS Cabinet Groups

Task Description

Purpose To establish connections between BTS cabinet groups

Mandatory or

OptionalMandatory

Prerequisites The BTS has at least two cabinet groups.

Remarks

For cabinet groups, the inner connection of the BTS is required.

For combined cabinets, the inner connection of the BTS is not

required.

Each cabinet group has at least one idle E1 port.

Procedure

Table 1 lists examples of the configurations of the connections between BTS cabinet

groups.

Table 1 Examples of the configurations of the connections between BTS cabinet groups


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Out-Port/In-Port 2/8 BSC internal planning

Out-Port/In-Port 3/10 BSC internal planning

Out-Port/In-Port 4/16 BSC internal planningOut-Port/In-Port 5/17 BSC internal planning

NOTE:

The configuration principle for internal connections is as follows:

The cabinet groups are connected in one-to-one port mode.

The connections are led from the main cabinet group to the extension cabinet group.

At least one connection must be established between the main cabinet group and each

extension cabinet group.

To establish connections between cabinet groups in a BTS, do as follows:

Step 1 In the Site Device Attributes dialog box refer to , clickSite Inn Connect.

Note

If the added TRXs are in different cabinet groups, you must configure the inner

connection of the cabinet groups.

When adding TRXs, you can clickSite Inner Connection in the Site Device Attributes

dialog box to configure the inner connection.

If the added TRXs are in different cabinet groups, you must configure the innerconnection of the cabinet groups. When adding TRXs, you can click Site Inner

Connection in the Site Device Attributes dialog box to configure the inner connection.

The Configure cabinet connection dialog box is displayed, as shown in Figure 1 .


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Figure 1 Establishing internal connections

NOTE:

You can also clickInner Connection in the Add and Delete Site Chain dialog box

shown in Figure 1 to establish internal connections.

NOTE:

The Out Port andIn Port drop-down list boxes list all the idle ports in the main cabinet

group and in the extension cabinet group respectively.

The main control board of the BTS decides the ports of the inner connection.

Step 2 Select a port number from the Out Port drop-down list box, as shown in Figure 2

.

Figure 2 Selecting an output port

NOTE:

The figure shown in Figure 1-30 stands for the port number of the cabinet group.

Step 3 Select a port number from the In Port drop-down list box, as shown in Figure 3 .


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Figure 3 Selecting an input port

NOTE:

If you want to establish multiple connections, repeat steps 2 and 3.

For example, establish four connections, as shown in Figure 4 .

Figure 4 Establishing multiple connections

NOTE:

If you want to delete connections, select None from the In Port drop-down list box.

Step 4 ClickOK.

----End


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Verification


Step 1 On the Management Tree tab page, click the added BTS.

The Site Device Panel tab page is displayed.

Step 2 ClickInn Connect Browse to check whether the established connections meet

your requirements.

----End


BTS inner connections are configured in cabinet groups. Each cabinet group of the BTSmust have at least one incoming port that connects the inside or outside of the BTS. The

BSC6000 supports eight types of BTSs.

Table 2 lists the distribution of ports in different types of cabinet groups.

Table 2 Distribution of ports in cabinet groups

BTS Type Cabinet Group 0 Cabinet Group 1 Cabinet Group 2

BTS30 0C7 8C11 16-19

BTS312 0C7 8C11 16-19

BTS3012A 0C4 8C11 16-19BTS3001C 0C1 - -

BTS3002C 0C1 - -

BTS3012 0C7 8C15 16C23

BTS3012AE 0C7 8C15 16C23

BTS3006C 4C7 12C15 20C23

Documents

Data Configuration Procedure