Download - RBS 6000 WCDMA Baseband Product Description

RBS 6000 WCDMA Baseband Product Description


© Ericsson AB 2016 All rights reserved. The information in this document is the property of Ericsson. Except as specifically authorized in writing by Ericsson, the receiver of this document shall keep the information contained herein confidential and shall protect the same in whole or in part from disclosure and dissemination to third parties. Disclosure and disseminations to the receiver's employees shall only be made on a strict need to know basis. The information in this document is subject to change without notice and Ericsson assumes no responsibility for factual inaccuracies or typographical errors.


1/221 01-FGB1010529 Uen Rev A 2016-07-06 Ericsson AB 2016 3 (69) Commercial in confidence

Contents

1 .................. Introduction ..................................................................................... 4 1.1 ............... Channel element (CE) ...................................................................... 9

............ Definition of CE ................................................................................. 9 1.1.1 ............ Normalization of 1 CE ....................................................................... 9 1.1.2 ............ Net and Gross CE ............................................................................. 9 1.1.3 ............ Static, Dynamic and Total EUL CE in Uplink (UL) ............................ 9 1.1.4

2 .................. HW Structure ................................................................................. 10

3 .................. SW Structure ................................................................................. 11

4 .................. Technical Specification ................................................................ 12 4.1 ............... Uplink .............................................................................................. 12 4.2 ............... Downlink ......................................................................................... 16

............ Number of EUL users and resource pooling ................................... 19 4.2.1 ............ Number of HSDPA users and resource pooling ............................. 20 4.2.2 ............ Reservation of A-DCH and F-DPCH resources .............................. 21 4.2.3

4.3 ............... DUW 10 .......................................................................................... 23 4.4 ............... DUW 20 .......................................................................................... 28 4.5 ............... DUW 30 .......................................................................................... 37 4.6 ............... RBS 6302 (WCDMA) ...................................................................... 47 4.7 ............... DUW 11 .......................................................................................... 48 4.8 ............... DUW 31 .......................................................................................... 51 4.9 ............... DUW 41 .......................................................................................... 54 4.10 ............. RBS 6501 (WCDMA) ...................................................................... 57

5 .................. Hardware Activation Codes (HWAC) .......................................... 58

6 .................. Large Configurations ................................................................... 59

7 .................. Transport network interfaces ...................................................... 60

8 .................. Radio Unit Interface ...................................................................... 64

9 .................. Acronyms and Abbreviations ...................................................... 65

10 ................ References .................................................................................... 66

11 ................ Appendix A – Combined Cell ....................................................... 67



1 Introduction

This version of the RBS 6000 Baseband Product Description is applicable to WRAN release W16B. The RBS 6000 base station family is designed to meet the increasingly complex challenges facing operators today. RBS 6000 is built with tomorrow’s technology and at the same time provide backwards-compatibility with the highly successful RBS 2000 and RBS 3000 product lines. RBS 6000 base stations offer a seamless, integrated and environmentally friendly solution and a safe, smart and sound roadmap for whatever tomorrow holds.

Figure 1 Overview of the RBS 6000 family

RBS 6000 Series Key Features:

• Path to sustainability: The RBS 6000 Series ensures a smooth migration to new functionality and new technologies with existing sites and cabinets, thus providing a path to sustained revenues and profits.

• Power on demand: Reengineering the power supply and fully integrating it into the system were key objectives in designing the RBS 6000 series. The intelligent power supply provides power on demand that is exactly matched to what is needed at any given moment, thus ensuring that power consumption is kept to an absolute minimum.

• Multi-standard: All RBS 6000 base stations support multiple radio technologies.



• Integrated simplicity: New multi-purpose cabinets, an innovative common building practice for all components, modular design and an extremely high level of integration bring the functionality and capacity of an entire site down to the size of a cabinet

All RBS 6000 base stations support multiple radio technologies and the radio shelves can be equipped with virtually any combination of GSM, WCDMA and LTE. The RBS 6000 family provides a complete multi-standard site in a single cabinet, including radio, RAN transport, operation and maintenance and site power.

Figure 2 Overview of the RBS 6201

The flexible hardware architecture of the RBS 6000 family enables a variety of site deployments and consists of the following main components:

• Radio shelf – combination of Radio Units (RU) and Digital Units (DU)

• Power shelf – Power Supply Units (PSU) dimensioned for the specific site

• Transport shelf – for transport network equipment up to 4U high

• Enclosure – including climate system

Enclosure

Radio technology

RAN Transport

O&M

Site Power



Radio Shelve

Power Shelf

Transmission Shelf

Climate control

Radio Units

Digital Units /Baseband Units

Radio Shelve

RBS 6201

Figure 3 RBS 6201, Hardware Architecture

The RBS 6000 family uses the following main components for GSM, WCDMA and LTE:

RU – Radio Unit: • Transceiver (TRX) • Transmitter (TX) amplification • Transmitter/Receiver (TX/RX) duplexing • TX/RX filtering • Voltage Standing Wave Ratio (VSWR) support

DU – Digital Processing Unit: • Control processing • Clock distribution • Synchronization from transport network i/f or GPS • Baseband processing • Transport network interface • RU interconnects • Site Local Area Network (LAN) and maintenance interface



Figure 4 The Radio Shelf

The radio shelf in RBS 6000 base stations supports a wide variety of Radio Unit for all main frequency bands and any combination of Radio Frequency (RF) technologies (GSM, WCDMA, or LTE).

The radio shelf in RBS 6000 base stations supports different types of Digital Units, to provide for maximum flexibility, modularity and capacity variation options to give customers the most cost-effective solutions.

• Digital Unit GSM (DUG).

• Digital Unit WCDMA (DUW)

• Digital Unit LTE (DUL, DUS)

The purpose of this document is to describe the Digital Unit WCDMA. The Digital Unit WCDMA or DUW provides:

• Base-band processing for the uplink and downlink • The interfaces between the radio network controller and node B (lub) and

the O&M interface for the node (Mub) • Synchronization from the transport network connection or external GPS



• IP and ATM connectivity1

The DUW has the same modularity as the rest of the RBS 6000 system, thus with maximum flexibility and an extremely high level of integration, it is possible in RBS 6000 to bring the functionality and capacity of an entire site down to the size of a single cabinet.

The DUW is also backwards compatible with the existing RBS 3000 product family. As new features are made available, customers can opt to simply upgrading the entire node B with a DUW, keeping the existing radio units, cabinet, power supply, antenna system etc. for major improvements of capabilities and capacity.

In a nodeB logical node, it is possible to have up to two DUWs, serving up to 18 cell carriers (e.g. 3x4+3x2 or 6x3) 2. The primary DUW can handle 12 cell carriers (each baseband pool in the primary DUW handles 6 cell-carrier) while the secondary DUW can handle 6 cell carriers belonging to a third baseband pool., The DUWs share a common Iub interface.

In an RBS 6000 node, it is possible to have one or more logical nodes, of the same standard or multi standard, e.g. it is possible have a nodeB (WCDMA) logical node together with an eNodeB (LTE) logical node in the same RBS 6000 cabinet.

1 DUW31 only IP 2 To configure a logical node with more than 12 cell-carriers it is required that FAJ 121 3928 Increased Cell-Carrier Support for DUW is configured and that primary DUW is a DUW30, DUW31 or DUW41.



1.1 Channel element (CE)

Definition of CE 1.1.1• CE is a measure of board capacity and radio bearer (RB) capacity cost • CE is an unit less entity

Normalization of 1 CE 1.1.2• Downlink (DL): One AMR 12.2 kbps with SF=128 • Uplink (UL): One AMR 12.2 kbps with SF=64

Net and Gross CE 1.1.3

“Net” and “Gross” CE are defined as follows. • Net CE: Dedicated Channel (DCH) resources available in the

system. • Gross CE: Resources available in the system including Dedicated

Channel (DCH), Common Channel (CCH) and Softer Handover (Softer HO).

Static, Dynamic and Total EUL CE in Uplink (UL) 1.1.4

Static Uplink CE can be used for both R99 DCH and EUL. Each Radio Access Bearer Service has a static cost corresponding to its minimum bitrate. Static UL CE is used for admission control in the RNC and sets the limit for max number of users.

Dynamic UL CE is the CE cost above the minimum CE allocation for EUL, used to grant higher bit rate by the EUL scheduler (in the Baseband). The extra Dynamic UL CE beyond Static UL CE can only be used for EUL.

Total EUL CE is the sum of the Static UL CE and Dynamic UL CE.



2 HW Structure The DUW consists of three main functional areas:

• Board Processor • Base band processing resources • Radio interface

RadioI/F

BoardProcessor Baseband

processingCPU

SFP

SFP

CPRI link to radio unit

E1

Power

Ethernet

E1/J1/T1

LAN /LMTEC Bus

GPS

-48VDC

UARTUART

Encoder

MOD

Random access

Decoder

DEMSTM-1STM-1

SFP

SFP

SFP

SFP

SFP

Figure 5 Overview of the DUW hardware structure

The board processor handles the Iub control signaling to/from the board, the Iub transmission interfaces, synchronization signal from the transport network connection or external GPS and operation and maintenance of the node.

The baseband processing resources consist of: • Decoder • Demodulator (DEM) • Random Access (RA) • Encoder • Modulation and spreading (MOD)



The decoder (DEC) provides the functionality for de-interleaving and decoding and DCH&E-DCH handling.

The DEM provides the functionality for the RAKE receiver with optional Interference Suppression, channel estimation and maximum ratio combining (MRC).

The RA is a random access detector.

The encoder (ENC) generates the cyclic redundancy check, concatenates the transport blocks, segments the coding blocks, convolutional coding or turbo coding, matches rates, interleaving and DCH, HSDPA&EUL handling.

The MOD provides the functionality for modulation, spreading and weighting, with power information for the downlink power control, and scrambling.

The radio interface provides up to six CPRI links to the radio units and manages the interface between the digital processors and the Radio Units.

3 SW Structure The RBS is based on the generic RBS 6000 application platform software. The software is down loadable via the OSS-RC interfaces (via the RNC or locally) and is stored in a non-volatile memory in the RBS.

The RBS 6000 family software platform provides generic support for the application software and includes an execution platform with operating system, transport, and O&M infrastructure. RBS Application SW handles the RBS HW, and is built on the platform SW.



4 Technical Specification The level of functionality supported by the baseband HW is connected to the WCDMA RAN release.

4.1 Uplink The uplink processing has the following characteristics per baseband pool:

• DCH R99 (Peak-rate: 384 kbps DCH)

• 6 RACH R99 (support up to 3x2 or 6x1)

• Resources for Softer HO included

• Resources for Compressed Mode included

• Support for EUL (2 and 10 ms TTI) gives higher throughput due to the increased peak-rate of up to 5.76 Mbps with 2 ms TTI

• Support HSDPA (2 ms TTI)

• Support for extended range up to 80 and 200 km

• Support for Continuous Packet Connectivity (CPC)

• Support for 4-way uplink Receive Diversity

• Support for Interference Suppression

• Support for EUL-FACH

• Support for EUL TD Scheduling

• Hardware prepared for 16QAM

• Hardware prepared for EUL Multi Carrier



• CE ladder for DPDCH

SF CE ladder

(default) CE ladder (optional)3

Service (Example)

256 1 1

128 1 1 AMR4.75 AMR5.9

64 1 1 SRB(Stand-alone)13.6 AMR7.95 AMR12.2 AMR12.2+PS0 AMR12.65 PS16 (DCH DL) PS16 (HS)

32 2 1 CS32 PS32 Streaming 16+PS8

16 4 2 CS57 CS64 CS64+PS8 PS64 AMR12.2+PS64

8 8 4 PS128 AMR12.2 + PS128/HS

4 16 8 PS384

3 CE Capacity for HSDPA smartphones, FAJ 121 1673



• CE ladder for E-DPDCH

SF CE ladder

(Default) CE ladder (Optional) 4

TB Bit-rate (2ms TTI)

3GPP Table #0 (kbps) 6


3GPP Table #0 (kbps) W14B enhancement of

FAJ 121 1317 5


3GPP Table #1 (kbps) 6

256 3 1 - -

128 3 1 - -

64 3 1 - -

32 3 1 - 19-37

16 4 2 - 52-71

8 8 4 - 86-155

4 16 8 148-7037 148-6317 170-711

2x4 32 16 729-1399 654-1302 743-1448

2x2 64 32 1451-2886 1350-2589 -

2x2+2x4

96 48 2993-5742 2685-5742 -

4 Default CE Ladder for E-DCH is used in the system. Change to the improved CE Ladder for E-DCH is done with SW feature FAJ 121 1334 “Improved Channel Element Ladder for E-DCH”. 5 Rate including MAC-e headers according to 3GPP TS 25.321, annex B.2. Puncturing limit 0.48. 6 Rate including MAC-e headers according to 3GPP TS 25.321, annex B.2. Puncturing limit 0.44. 7 With feature FAJ 121 1883, Channel Element capacity for EUL Smartphones, the minimum CE consumption is 2CE for 0-20 kbps.



• CE reservation for EUL FACH

The cost in terms of UL CEs for EUL-FACH depends on the configured UL rate NodeBFunction::eulFachInitialRate, number of configured HW decoders RbsLocalCell::eulFachNumOfDecoders and number of cells in RBS. Table shows mapping from eulFachInitialrate to the minimum SF. Combining this with used E-DCH CE ladder and number of cells gives a total reduction of CEs from the licensed CE pool.

Mapping from eulFachInitialrate to Minimum SF

SF CE ladder (Default)

CE ladder (Optional)

eulFachInitialRate value (kbps)

32 3 1 0 - 34

16 4 2 35 - 70

8 8 4 71 - 150

4 16 8 151 - 689

2x4 32 16 690 - 1376

For example, the cost is 1 CE for a HW Decoder with 32 kbps. If eulFachInitialRate is set to a higher value, then the cost increases. Number of HW decoders for EUL-FACH eulFachNumOfDecoders are configured per cell carrier.



4.2 Downlink The downlink processing has the following characteristics:

• Support for DCH R99 (Peak-rate: 384 kbps DCH) • CCH R99 included • Resources for Softer HO included • Resources for Compressed Mode included • Support for TxD

• Support for 2x2MIMO

• Support for 64 QAM

• Support for 64QAM and 2xMIMO simultaneously

• Support for Multi Carrier (2)

• Support for Dual Band Multi Carrier (2)

• Support for HS-FACH

• Support for Continuous Packet connectivity (CPC)

• Support for F-DPCH

• Hardware prepared for Multi Carrier (4)

• Hardware prepared for Dual Band Multi Carrier (4)

• Hardware prepared for Multi Carrier (8) (DUW41/31)



• CE ladder DPDCH

SF CE ladder Service (Example)

2568 1 AMR4.75 AMR5.9

128 1 SRB(Stand-alone)13.6 AMR7.95 AMR12.2 AMR12.2 + PS0 AMR12.65 AMR12.65 + PS0 AMR12.2 + PS128/HS PS16

64 1

32 2 CS57 CS64 CS64+PS8 PS64 AMR12.2+PS64 Streaming 64+PS8

16 4 PS128 Streaming 128+PS8

8 8 PS384

8 SF256 is also used for A-DPCH and F-DPCH without any CE cost.



• CE ladder for MBMS

SF CE ladder Logical Channels

256 1 MICH and MCCH

128 1 N/A

64 1 N/A

32 2 MTCH (64kbps)

16 4 MTCH (128kbps)

8 8 MTCH (256 kbps)

• Support for MBMS

o Supports up to 10 MTCH on separate FACH/S-CCPCH and 1 MCCH on separate FACH/S-CCPCH and 1 MICH per cell carrier

• Support HSDPA (2 ms TTI)

o 16QAM Peak rate: 14.4 Mbps

o 64QAM Peak rate: 21.6 Mbps

o 2xMIMO Peak rate: 28.8 Mbps

o 64QAM+2xMIMO Peak rate: 42 Mbps

o Multi Carrier (2) Peak rate: 42 Mbps

o Multi Carrier (2) + 2xMIMO Peak rate: 84 Mbps

• A-DCH and F-DPCH are included when configured for HSDPA

• Possible to configure for: o Only CCH/DCH R99 o Mix of CCH/DCH R99 and HS

• Cell carrier capability: o Up to 15 HS codes per cell-carrier o Up to 128 HS users per cell-carrier o HS-DSCH + 4 HS-SCCH (for code multiplexing) o QPSK, 16QAM and 64QAM o MIMO

• Support for EUL (2 and 10 ms TTI)

o Up to 96 EUL users per cell-carrier



The DUW has so called Resource_Id’s. Each Resource_Id can be configured with one of the following options:

o 128 CE DCH R99 including CCH, CM and SoHO

o 30/609 HS-PDSCH codes shared between up to 6 cell-carriers

o EUL including the DL channels and the Scheduler

o For multi carrier configurations, each HSDPA processing resource supports the following configurations:

For Multi Carrier users up to 30/60 codes can be shared by up to six cells

For HS users with 16QAM & 64QAM, 30/60 HS-PDSCH codes can be shared by up to six cells, with a maximum of 15 HS-PDSCH codes in one cell

For MIMO users, 30/60 HS-PDSCH codes can be shared by up to six cells, with a maximum of 15 HS-PDSCH codes in one cell

The basic configuration of a Resource_Id is DCH R99, used for R99 traffic. If HSDPA is activated then EUL is also possible to activate. If EUL is activated Multi Carrier is also possible to activate.

Number of EUL users and resource pooling 4.2.1

When EUL is configured for 6 cell carriers pooling of resources is applied. One Resource_id can support a maximum of 256 EUL users. This means in a 3x2 configuration when more than 42 EUL users per cell carrier is configured, for example 96, that the number of EUL users configured per cell carrier is a peak number and not a guaranteed number. The number of EUL users per cell carrier can then vary between 0 and 96; however the total number of EUL users handled by the baseband pool cannot exceed 25610. If there are 256 EUL users already scheduled in the baseband pool and a new EUL user requests a session, then the EUL setup will be rejected and the user will be setup on an R99 DCH connection instead (assuming there are sufficient resources to handle the R99 DCH channel).

9 60 HS codes with Increased HSDPA code capacity on DUW, FAJ 121 2870 10 Max 128 for DUW 10 and DUW 11



Number of HSDPA users and resource pooling11 4.2.2

Each Resource_id with HSDPA supports up to 128 HSDPA users, divided between one to six cells. It is possible to serve up to 128 HSDPA users in all cells configured for one Resource_id and a maximum of 128 users in a single cell.

For example, if a Resource_id has 3 cells configured, it is possible to serve any of the following configurations:

• 48 HSDPA users in cell 1, 48 HSDPA users in cell 2, 32 HSDPA users in cell 3



The maximum number of HSDPA users that a cell can serve is determined by the value of the MOM attribute RbsLocalCell::maxNumHsdpaUsers. The distribution of HSDPA users between cells can be configured by modifying the MO parameter RbsLocalCell::maxNumHsdpaUsers. The value of the MO parameter RbsLocalCell::maxNumHsdpaUsers can be set to any value between 1 and 16, or, if RBS License Key “Number of HSDPA Users per Cell”12 is installed, to any value between 1 and the maximum value determined by the RBS License Key.

Resource pooling of HSDPA users is always applied when the sum of the number of HSDPA users per cell for all cells configured on one Resource_id is larger than 128. For example if there are three cells with the MO parameter RbsLocalCell::maxNumHsdpaUsers = 64, configured on one Resource_id, resource pooling is applied. In this case the number of HSDPA users in a cell can peak at 64, but the total number of HSDPA users on the Resource_id is always less than or equal to 128.

11 Not valid if feature FAJ 121 3249 Combined Cell is activated 12 RBS LK FAJ 121 2721 is required to set RbsLocalCell::maxNumHsdpaUsers above 16 users



Another possibility to apply pooling is by setting the MO parameter DownlinkBasebandPool ::maxNumADchReservation to a lower value than the standard A-DCH and F-DPCH reservation as described in section 4.2.3. For example if HSDPA is configured for three cells on one Resource_id:

• MO parameter RbsLocalCell::maxNumHsdpaUsers=32 for all three cells

• RBS License Key “Number of HSDPA Users per Cell” is installed and set to 32

• MO parameter DownlinkBasebandPool ::maxNumADchReservation = 3 * 16 * 1.3 * 0.5CE = 32 CE, which is the A-DCH reservation for 16 HS users per cell

This means that the number of HSDPA users in one cell can peak at 32. The setting of the MO parameter DownlinkBasebandPool ::maxNumADchReservation limits the total number of HSDPA users to 48.

Reservation of A-DCH and F-DPCH resources13 4.2.3

From P7 MD and onwards the reservation of A-DCH and F-DPCH is determined from:

• The license key “Number of HSDPA users per Cell” • The MO parameter RBSLocalCell:: maxNumHsdpaUsers • The MO parameter DownlinkBasebandPool:: maxNumADchReservation

13 Not valid if feature FAJ 121 3249 Combined Cell is activated



An amount of A-DCH and F-DPCH resources is reserved by default. The amount which is reserved for a Baseband pool is the minimum of 1 and 2 below:

1. 1.3 x sum of the lowest of the values of either the RBS License Key “Number of HSDPA users per Cell” or RbsLocalCell::maxNumHsdpaUsers, determined cell-by-cell For example if 2 cells are configured in the following way: • First cell: RBS License Key “Number of HSDPA users per Cell” = 64 and

MO parameter RBSLocalCell:: maxNumHsdpaUsers =32 • Second cell: RBS License Key “Number of HSDPA users per Cell” = 64

and MO parameter RBSLocalCell:: maxNumHsdpaUsers=64

The sum of these values is 32+64 and the A-DCH and F-DPCH reservation is 96 x 1.3 x 0.5CE = 63 CE

2. 1.3 x number of Resource_id with HS configured x 128

The value 1.3 is used as a factor to include capacity for handover.

For example if 3 cells are configured on one Resource_id with 64 HSDPA users/cell and 10 HSDPA codes/cell, the A-DCH and F-DPCH reservation (licenses not considered) is the minimum of 1 and 2 below:

1. 3 cells x 64 HSDPA users/cell x 1.3 x 0.5 CE = 125 CE

2. 1 Resource_id x HSDPA 128 users x 1.3 x 0.5 CE = 84 CE

In this example 84 CE will be reserved for A-DCH and F-DPCH by default, as it is not necessary to reserve more CE resources for A-DCH and F-DPCH, than what is needed to handle 128 HSDPA users, which is the maximum capacity of a single Resource_id.

If the default amount of A-DCH and F-DPCH reserved is considered too high, the reserved amount can be lowered by setting the value of the MO parameter DownlinkBasebandPool:: maxNumADchReservation.



4.3 DUW 10 The DUW 10 can support the following:

• Uplink CE capacity overview

Net no. of CE 14 CE for EUL 15 Gross no. of CE 16

128 192 17 187 / 251 17

• Downlink CE capacity overview

Net no. of CE 18 Gross no. of CE 19

128 190

In Ψ-coverage, 4-way receive diversity and combined cell solutions DUW 10 can support the following:

• Uplink CE capacity in Ψ-coverage and 4-way receive diversity:


96 128 / 192 23 146 / 242 23

• For a DL capacity overview associated with Combined cell (FAJ 121 3249), please refer to Appendix A – Combined Cell.

14 Net no of CE is equal to static CE for “DCH or EUL” = max number of users. 15 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 16 Gross no of CE is equal to “DCH, CCH and Softer HO”. 17 Including 50% additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required 18 Net no of CE is equal to “DCH only”. 19 Gross no of CE is equal to “DCH, CCH and Softer HO”. 20 Net no of CE is equal to static CE for “DCH or EUL” = max number of users 21 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 22 Gross no of CE is equal to “DCH, CCH and Softer HO”. 23 Including 50% additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required



The DUW 10 supports extended range configurations, i.e. over and above 35 km. For some cell ranges capacity trading (DCH capacity reduction) is used. E.g. DUW10, with 2 way receive diversity, 80km cell range and a 3cc configuration, the net cost is 3CE in uplink (i.e. available static CE is 125 in the uplink for R99 + EUL). Table 1 DUW 10, 2 way receive diversity

The DUW 10 supports extended range configurations with 4-way receive diversity, i.e. over and above 35 km. E.g. DUW10, with 4 way receive diversity, 40km cell range and a 3cc configuration, the net cost is 3CE in uplink (i.e. available static CE is 93 in the uplink for R99 + EUL).

Table 2 DUW 10, 4 way receive diversity

DUW 10 has product number:

DUW 10 01: KDU 127 161/1

The following Table 3 describes the additional downlink CE characteristics for DUW 10. The capacity figures are calculated in the following way:

• Capacity figures with light green fields are calculated with average number of HS users per cell

• Capacity figures with pale blue fields are calculated with resource pooling applied (the given number of HS users/cell is a peak value)

• If DUW10 is configured for more than 30 HS codes then feature Increased HSDPA code capacity on DUW, FAJ 121 2870, is needed. Capacity figures with red font indicate the feature is activated.

Cell Range Net CE cost, 1cc Net CE cost, 2cc Net CE cost, 3cc Net CE cost, 4cc Net CE cost, 5cc Net CE cost, 6cc35 0 0 0 0 0 080 0 0 3 Not Supported Not Supported Not Supported

200 0 19 Not Supported Not Supported Not Supported Not Supported



Table 3 DUW 10 with R99, R99+HS and R99+HS+EUL, R99+HS+EUL+Multi-Carrier

No.1cc 2cc 3cc 4cc 6cc

A1.1 128 128 128 128 128HS E-UL

codes/cc users/ccA2.1 R99+HS+EUL 4 5 4 125 122 120 117 112A2.2 R99+HS+EUL 16 5 4-16 117 107 96 86 65A2.3 R99+HS+EUL 32 5 4-32 107 86 65 44 44A2.4 R99+HS+EUL 48 5 4-48 96 65 44 44 44A2.5 R99+HS+EUL 64 5 4-64 86 44 44 44 44A2.6 R99+HS+EUL 96 5 4-96 65 44 44 44 44A2.7 R99+HS+EUL 128 5 4-128 44 44 44 44 44A2.8 R99+HS+EUL 4 10 4 125 122 120 117 112A2.9 R99+HS+EUL 16 10 4-16 117 107 96 86 65A2.10 R99+HS+EUL 32 10 4-32 107 86 65 44 44A2.11 R99+HS+EUL 48 10 4-48 96 65 44 44 44A2.12 R99+HS+EUL 64 10 4-64 86 44 44 44 44A2.13 R99+HS+EUL 96 10 4-96 65 44 44 44 44A2.14 R99+HS+EUL 128 10 4-128 44 44 44 44 44A2.15 R99+HS+EUL 4 15 4 125 122 120 117 N/AA2.16 R99+HS+EUL 16 15 4-16 117 107 96 86 N/AA2.17 R99+HS+EUL 32 15 4-32 107 86 65 44 N/AA2.18 R99+HS+EUL 48 15 4-48 96 65 44 44 N/AA2.19 R99+HS+EUL 64 15 4-64 86 44 44 44 N/AA2.20 R99+HS+EUL 96 15 4-96 65 44 44 44 N/AA2.21 R99+HS+EUL 128 15 4-128 44 44 44 44 N/AA2.22 R99+HS+EUL 4 30 dyn. 4 N/A 122 120 117 112A2.23 R99+HS+EUL 16 30 dyn. 4-16 N/A 107 96 86 65A2.24 R99+HS+EUL 32 30 dyn. 4-32 N/A 86 65 44 44A2.25 R99+HS+EUL 48 30 dyn. 4-48 N/A 65 44 44 44A2.26 R99+HS+EUL 64 30 dyn. 4-64 N/A 44 44 44 44A2.27 R99+HS+EUL 96 30 dyn. 4-96 N/A 44 44 44 44A2.28 R99+HS+EUL 128 30 dyn. 4-128 N/A 44 44 44 44A2.29 R99+HS+EUL 4 60 dyn. 4 N/A N/A N/A N/A 112A2.30 R99+HS+EUL 16 60 dyn. 4-16 N/A N/A N/A N/A 65A2.31 R99+HS+EUL 32 60 dyn. 4-32 N/A N/A N/A N/A 44A2.32 R99+HS+EUL 48 60 dyn. 4-48 N/A N/A N/A N/A 44A2.33 R99+HS+EUL 64 60 dyn. 4-64 N/A N/A N/A N/A 44A2.34 R99+HS+EUL 96 60 dyn. 4-96 N/A N/A N/A N/A 44A2.35 R99+HS+EUL 128 60 dyn. 4-128 N/A N/A N/A N/A 44

HS users/cc

Configuration HW capacity DCH R99 (CE)

R99



Comments to Table 3 1. The number of CE available for R99 DCH is the same for R99+HS and R99+HS+EUL 2. The number of “HSDPA users” and “HS-PDSCH codes/cc” is always “Up to”. 3. Max 128 users (HSDPA + DCH R99) can be supported 4. “N/A” means that this configuration is not applicable, supported or possible. 5. “Dyn” means that feature “Dynamic Code Allocation” is activated. 30/60 HS-PDSCH

codes can be shared between 2 to 6 cell-carriers 6. A maximum of 128 EUL users in one base band pool is supported regardless of the

number of cell carriers 7. When several cells are configured on one Resource_id the number of HS users per

cells can vary due to resource pooling. 8. Multi-Carrier implies even number of cell-carriers



Graphical illustrations (Examples):

96 CE

5 HS codes

16 HS users

16 HS users

16 HS users

16 EUL users

16 EUL users

16 EUL users

5 HS codes

5 HS codes

• One Resource_id is loaded with HS software• 15 HS codes are distributed over 3 cells.• 5 codes are allocated per cell • 48 HS users can be served over 3 cells• One Resource_id is loaded with EUL software• 48 EUL users can be served over 3 cells. • 96 CE available for R99 DCH shared over 3 cells

A2.2

27 HS codes

96 CE

1 HS code

16 HS users

16 HS users

16 HS users

16 EUL users

16 EUL users

16 EUL users

1 HS code

1 HS code

• One Resource_id is loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 27 codes are dynamically distributed over 3 cells• The number of codes per cell can vary between 1 and 15.• 48 HS users can be served over 3 cells• One Resource_id is loaded with EUL software• 48 EUL users can be served over 3 cells• 96 CE available for R99 DCH shared over 3 cells

A2.23 Cell 2

Cell 2

Cell 3

Cell 3

Cell 1

Cell 1

27 HS codes

Max 128 HS users

44 CE

1 HS code

Peak 64HS users

Peak 64 HS users

Peak 64HS users

1 HS code

1 HS code

• One Resource_id is loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 27 codes are dynamically distributed over 3 cells• The number of codes per cell can vary between 1 and 15• 128 HS users can be served over 3 cells• Each cell can serve a maximum of 64 HS users• The A-DCH reservation is done for a maximum of 128 HS users, as this is the maximum supported on one HS resource, which leaves 44 CE for R99 DCH

A2.26 for 3x1 (3cc) with resource poolingCell 2

Cell 3

Cell 1

54 HS codes

Max 128 HS users

44 CE

1 HS code

Peak 128HS users

Peak 128 HS users

1 HS code• One Resource_id is loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 54 codes are dynamically distributed over 6 cells *• The number of codes per cell can vary between 1 and 15• 128 HS users can be served over 6 cells• Each cell can serve a maximum of 128 HS users• The A-DCH reservation is done for a maximum of 128 HS users, as this is the maximum supported on one HS resource, which leaves 44 CE for R99 DCH

A2.35 for 3x2 or 6x1 (6cc) with resource pooling

Cell 2

Cell 3

Cell 1

Peak 128 HS users

1 HS code

Cell 4Peak 128 HS users

1 HS code

Peak 128HS users

1 HS code

Peak 128 HS users

1 HS codeCell 6

Cell 5

* Using FAJ 121 2870, Increased HSDPA Code Capacity on DUW, for up to 60 HS codes



4.4 DUW 20

The DUW 20 can support the following:



384 576 27 562 / 754 27



384 523




24 Net no of CE is equal to static CE for “DCH or EUL” = max number of users 25 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 26 Gross no of CE is equal to “DCH, CCH and Softer HO”. 27 Including 50% additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required 28 Net no of CE is equal to “DCH only”. 29 Gross no of CE is equal to “DCH, CCH and Softer HO”. 30 Net no of CE is equal to static CE for DCH or EUL = max number of users 31 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 32 Gross no of CE is equal to “DCH, CCH and Softer HO”. 33 Including 50% additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required


288 384 / 576 33 437 / 725 33



The DUW 20 supports extended range configurations, i.e. over and above 35 km. For some cell ranges capacity trading (DCH capacity reduction) is used.

E.g. DUW20, with 2 way receive diversity, 200km cell range and a 6cc configuration, the net cost is 57 CE in uplink (i.e. available static CE is 327 in the uplink for R99 + EUL). Table 4 DUW20, 2 way receive diversity

E.g. DUW20, with 4 way receive diversity, 200km cell range and a 3cc configuration, the net cost is 57 CE in uplink (i.e. available static CE is 231 in the uplink for R99 + EUL).

Table 5 DUW20, 4 way receive diversity


DUW 20 01: KDU 127 161/2

The following Table 6, Table 7 and Table 8 describe the additional downlink CE characteristics for DUW 20. The capacity figures in the tables are calculated in the following way:


• Capacity figures with pale blue fields are calculated with resource pooling applied (the given number of HS users/cell is a peak value

• If a Resource_ID is configured for more than 30 HS codes then feature Increased HSDPA code capacity on DUW, FAJ 121 2870, is needed. Capacity figures in red font indicate the feature is activated.



Table 6 DUW 20 with R99, R99+HS

No. Configuration Pooling applied1cc 2cc 3cc 4cc 6cc 6cc

B1.1 R99 384 384 384 384 384 384HS HS E-UL

users/cc codes/cc users/ccB2.1 R99+HS 4 5 - 381 378 376 373 368 -B2.2 R99+HS 16 5 - 373 363 352 342 321 -B2.3 R99+HS 32 5 - 363 342 321 300 259 300B2.4 R99+HS 48 5 - 352 321 290 259 68 300B2.5 R99+HS 64 5 - 342 300 259 217 6 300B2.6 R99+HS 96 5 - 321 259 68 300 300 -B2.7 R99+HS 128 5 - 300 217 300 300 300 -B2.8 R99+HS 4 10 - 381 378 376 373 368 -B2.9 R99+HS 16 10 - 373 363 352 342 321 -B2.10 R99+HS 32 10 - 363 342 321 300 259 -B2.11 R99+HS 48 10 - 352 321 290 259 68 300B2.12 R99+HS 64 10 - 342 300 259 217 6 300B2.13 R99+HS 96 10 - 321 259 68 300 300 -B2.14 R99+HS 128 10 - 300 217 300 300 300 -B2.15 R99+HS 4 15 - 381 378 376 373 368 -B2.16 R99+HS 16 15 - 373 363 352 342 193 -B2.17 R99+HS 32 15 - 363 342 321 300 131 -B2.18 R99+HS 48 15 - 352 321 290 259 68 -B2.19 R99+HS 64 15 - 342 300 259 217 6 -B2.20 R99+HS 96 15 - 321 259 68 217 217 -B2.21 R99+HS 128 15 - 300 217 217 217 217 -B2.22 R99+HS 4 30 dyn. - N/A 378 376 373 368 -B2.23 R99+HS 16 30 dyn. - N/A 363 352 342 321 -B2.24 R99+HS 32 30 dyn. - N/A 342 321 300 259 300B2.25 R99+HS 48 30 dyn. - N/A 321 290 259 68 300B2.26 R99+HS 64 30 dyn. - N/A 300 259 217 6 300B2.27 R99+HS 96 30 dyn. - N/A 259 68 300 300 -B2.28 R99+HS 128 30 dyn. - N/A 217 300 300 300B2.29 R99+HS 4 60 dyn. - N/A N/A N/A 373 368 -B2.30 R99+HS 16 60 dyn. - N/A N/A N/A 342 321 -B2.31 R99+HS 32 60 dyn. - N/A N/A N/A 300 259 -B2.32 R99+HS 48 60 dyn. - N/A N/A N/A 259 68 300B2.33 R99+HS 64 60 dyn. - N/A N/A N/A 217 6 300B2.34 R99+HS 96 60 dyn. - N/A N/A N/A 300 300 -B2.35 R99+HS 128 60 dyn. - N/A N/A N/A 300 300 -

HW capacity DCH R99 (CE)



Table 7 DUW 20 with R99+HS+EUL, R99+HS+EUL+Multi-Carrier

No. Configuration MC1cc 2cc 3cc 4cc 6cc 3x2cc

HS HS E-UL users/cc codes/cc users/cc

B3.1 R99+HS+EUL 4 5 4 381 378 376 373 368 368B3.2 R99+HS+EUL 16 5 4-16 373 363 352 342 321 321B3.3 R99+HS+EUL 32 5 4-32 363 342 321 300 131 131B3.4 R99+HS+EUL 48 5 4-48 352 321 162 131 300 300B3.5 R99+HS+EUL 64 5 4-64 342 300 131 89 300 300B3.6 R99+HS+EUL 96 5 4-96 321 131 300 300 300 300B3.7 R99+HS+EUL 128 5 4-128 300 89 300 300 300 300B3.8 R99+HS+EUL 4 10 4 381 378 376 373 368 368B3.9 R99+HS+EUL 16 10 4-16 373 363 352 342 321 321B3.10 R99+HS+EUL 32 10 4-32 363 342 321 300 131 131B3.11 R99+HS+EUL 48 10 4-48 352 321 162 131 300 300B3.12 R99+HS+EUL 64 10 4-64 342 300 131 89 300 300B3.13 R99+HS+EUL 96 10 4-96 321 131 300 300 300 300B3.14 R99+HS+EUL 128 10 4-128 300 89 300 300 300 300B3.15 R99+HS+EUL 4 15 4 381 378 376 373 240 240B3.16 R99+HS+EUL 16 15 4-16 373 363 352 342 193 193B3.17 R99+HS+EUL 32 15 4-32 363 342 321 300 131 131B3.18 R99+HS+EUL 48 15 4-48 352 321 162 131 89 89B3.19 R99+HS+EUL 64 15 4-64 342 300 131 89 89 89B3.20 R99+HS+EUL 96 15 4-96 321 131 89 89 89 89B3.21 R99+HS+EUL 128 15 4-128 300 89 89 89 89 89





Comments to Table 6, Table 7 and Table 8 1. The number of “HSDPA users” and “HS-PDSCH codes/cc” is always “Up to”. 2. Max 384 users (HSDPA + DCH R99) can supported 3. “N/A” means that this configuration is not applicable, supported or possible. 4. “Dyn” means that feature “Dynamic Code Allocation” is activated. 30 HS-PDSCH codes can be shared

between up to 2-6 cell-carriers (e.g. 5+5+5+5+5+5, 3+3+3+3+3+15) 5. A maximum of 256 EUL users in one base band pool is supported regardless of the number of cell carriers 6. When several cells are configured on one Resource_id the number of HS users per cells can vary due to

resource pooling. 7. Multi-Carrier implies even number of cell-carriers

No. Configuration MC1cc 2cc 3cc 4cc 6cc 3x2cc


B3.22 R99+HS+EUL 4 30 dyn. 4 N/A 378 376 373 368 368B3.23 R99+HS+EUL 16 30 dyn. 4-16 N/A 363 352 342 321 321B3.24 R99+HS+EUL 32 30 dyn. 4-32 N/A 342 321 300 131 131B3.25 R99+HS+EUL 48 30 dyn. 4-48 N/A 321 162 131 300 300B3.26 R99+HS+EUL 64 30 dyn. 4-64 N/A 300 131 89 300 300B3.27 R99+HS+EUL 96 30 dyn. 4-96 N/A 131 300 300 300 300B3.28 R99+HS+EUL 128 30 dyn. 4-128 N/A 89 300 300 300 300B3.29 R99+HS+EUL 4 60 dyn. 4 N/A N/A N/A 373 368 368B3.30 R99+HS+EUL 16 60 dyn. 4-16 N/A N/A N/A 342 321 321B3.31 R99+HS+EUL 32 60 dyn. 4-32 N/A N/A N/A 300 131 131B3.32 R99+HS+EUL 48 60 dyn. 4-48 N/A N/A N/A 131 300 300B3.33 R99+HS+EUL 64 60 dyn. 4-64 N/A N/A N/A 89 300 300B3.34 R99+HS+EUL 96 60 dyn. 4-96 N/A N/A N/A 300 300 300B3.35 R99+HS+EUL 128 60 dyn. 4-128 N/A N/A N/A 300 300 300B3.36 R99+HS+EUL 4 90 dyn. 4 N/A N/A N/A N/A 240 240B3.37 R99+HS+EUL 16 90 dyn. 4-16 N/A N/A N/A N/A 193 193B3.38 R99+HS+EUL 32 90 dyn. 4-32 N/A N/A N/A N/A 131 131B3.39 R99+HS+EUL 48 90 dyn. 4-48 N/A N/A N/A N/A 89 89B3.40 R99+HS+EUL 64 90 dyn. 4-64 N/A N/A N/A N/A 89 89B3.41 R99+HS+EUL 96 90 dyn. 4-96 N/A N/A N/A N/A 89 89B3.42 R99+HS+EUL 128 90 dyn. 4-128 N/A N/A N/A N/A 89 89





352 CE

10 HS codes

16 HS users

16 HS users

16 HS users

16 EUL users

16 EUL users

16 EUL users

10 HS codes

10 HS codes

• One Resource_id is loaded with HS software• 10 codes are allocated per cell • 48 HS users can be served over 3 cells• One Resource_id is loaded with EUL software• 48 EUL users can be served over 3 cells. • 352 CE available for R99 DCH shared over 3 cells

B3.9

27 HS codes

352 CE

1 HS code

16 HS users

16 HS users

16 HS users

16 EUL users

16 EUL users

16 EUL users

1 HS code

1 HS code


B3.23 Cell 2

Cell 2

Cell 3

Cell 3

Cell 1

Cell 1



131 CE

10 HS codes

64HS users

64 HS users

64HS users

10 HS codes

10 HS codes

• Two Resource_id are loaded with HS software• 10 codes are are allocated per cell • 192 HS users can be served over 3 cells • One Resource_id is loaded with EUL software• 192 EUL users can be served over 3 cells• All cells can serve a maximum of

64 HS / EUL users simultaneously

B3.12Cell 2

Cell 3

Cell 1

Max 128 HS users

300 CE

10 HS codes

Peak 96HS users

Peak 96 HS users

Peak 96HS users

10 HS codes

10 HS codes

• One Resource_id is loaded with HS software• 10 codes are are allocated per cell• 128 HS users can be served over 3 cells• Each cell can serve a maximum of 96 HS users• The A-DPCH reservation is done for a maximum of 128 HS users,

as this is the maximum supported on one HS resource, which leaves 300 CE for R99 DCH

B3.13 for 3x1 (3cc) with resource poolingCell 2

Cell 3

Cell 1

64 EUL users

64 EUL users

32 EUL users

32 EUL users

32 EUL users

64 EUL users



Max 128 HS users

300 CE

5 HS code

Peak 32 HS users

Peak 32 HS users

5 HS code• One Resource_id is loaded with HS software• 5 codes are allocated per cell. • 128 HS users can be served over 6 cells• Each cell can serve a maximum of 32 HS users• One Resource_id is loaded with EUL software• 128 EUL users can be served over 6 cells• The A-DCH reservation is done for a maximum of 128 HS users,

as this is the maximum supported on one HS resource, which leaves 300 CE for R99 DCH• Note: it is also possible to support a peak of 128 HS users per cell,

with the same configuration, as described in B3.7

B3.3 for 3x2 or 6x1 (6cc) with resource pooling

Cell 2

Cell 3

Cell 1

Peak 32 HS users

5 HS code


5 HS code

Peak 32 HS users

5 HS code

Peak 32 HS users

1 HS codeCell 6

Cell 5

131 CE

5 HS code

32 HS users

32 HS users

5 HS code•Two Resource_ids are loaded with HS software• 5 codes are allocated per cell. • 192 HS users can be served over 6 cells• All cells can serve 32 HS users simultaneously• One Resource_id is loaded with EUL software• 192 EUL users can be served over 6 cells• Note: with two resource ids used for HSDPA, it is also

possible to support 10 HS codes per cell,as described in B3.10

B3.3 for 3x2 or 6x1 (6cc)

Cell 2

Cell 3

Cell 1

32 HS users

5 HS code

Cell 432 HS users

5 HS code

32 HS users

5 HS code

32 HS users

5 HS codeCell 6

Cell 5

54 HS codes

Max 128 HS users

300 CE

1 HS code

Peak 32 HS users

Peak 32 HS users

1 HS code

• One Resource_id is loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 54 codes are dynamically distributed over 6 cells*• 128 HS users can be served over 6 cells• Each cell can serve a maximum of 32 HS users• One Resource_id is loaded with EUL software• 128 EUL users can be served over 6 cells• The A-DCH reservation is done for a maximum of 128 HS users,

as this is the maximum supported on one HS resource, which leaves 300 CE for R99 DCH

• Note: it is also possible to support up to a peak of 64 HS users per cell, with the same configuration, as described in B3.35.

B3.31 for 3x2 or 6x1 (6cc) with resource pooling

Cell 2

Cell 3

Cell 1

Peak 32 HS users

1 HS code


1 HS code

Peak 32 HS users

1 HS code

Peak 32 HS users

1 HS codeCell 6

Cell 5

54 HS codes

131 CE

1 HS code

32 HS users

32 HS users

1 HS code • One Resource_ids is loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 54 codes are dynamically distributed over 6 cells* • 192 HS users can be served over 6 cells• All cells can serve 32 HS users simultaneously• One Resource_id is loaded with EUL software• 192 EUL users can be served over 6 cells• *Note: with one resource ids used for HSDPA, it is also

possible to support 60 HS codes divided over 6 cells. Thereforethis configuration is similar to B3.10 for 6cc, except that the60 HS codes are dynamically allocated and shared over all 6cc

B3.31 for 3x2 or 6x1 (6cc) with 60 HS codes dynamic*

Cell 2

Cell 3

Cell 1

32 HS users

1 HS code

Cell 432 HS users

1 HS code

32 HS users

1 HS code

32 HS users

1 HS codeCell 6

Cell 5




300 CE

1 HS code

32 HS users

32 HS users

1 HS code• Two Resource_ids are loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 54 codes are dynamically distributed over 6 cells• Max 28 HS codes over 3 cells and max 15 HS codes in one cell • 192 HS users can be served over 6 cells• All cells can serve 32 HS users simultaneously• One Resource_id is loaded with EUL software• 192 EUL users can be served over 6 cells• 131 CE available for R99 DCH shared over 6 cells

B3.31 for 3x2 or 6x1 (6cc) with 60 HS codes dynamic

Cell 1

Cell 2

Cell 6

32 HS users

1 HS code

Cell 332 HS users

1 HS code

32 HS users

1 HS code

32 HS users

1 HS codeCell 5

Cell 4

131 CE

15 HS codes

32 HS users

32 HS users

15 HS codes • Two Resource_ids are loaded with HS software

• 15 HS codes is allocated per cell. *• 192 HS users can be served over 6 cells• All cells can serve 32 HS users simultaneously• One Resource_id is loaded with EUL software• 192 EUL users can be served over 6 cells

B3.17 for 3x2 or 6x1 (6cc)

Cell 2

Cell 3

Cell 1

32 HS users

15 HS codes

Cell 432 HS users

15 HS codes

32 HS users

15 HS codes

32 HS users

15 HS codesCell 6

Cell 5

131 CE27HS codes

27HS

codes131 CE131 CE131 CE131 CE

300 CE

15 HS codes

Peak 128HS users

Peak 128 HS users

15 HS codes• Two Resource_ids are loaded with HS software• 15 HS codes are allocated per cell. *• 256 HS users can be served over 6 cells• Max 128 HS users in one cell• 256 Multi-Carrier users can be served over 3 sectors

simultaneously• One Resource_id is loaded with EUL software• 256 EUL users can be served over 6 cells• 89 CE available for R99 DCH shared over 6 cells• Note*: Asymmetric user capacity

• 128 HS users over 4 cells and 128 HS users over 2 cells

B3.21 for 3x2 Multi-Carrier (6cc), asymmetric*

Cell 1

Cell 2

Cell 6

Cell 3

Cell 5

Cell 4

321 CE

10 HS codes

16 HS users

16 HS users

10 HS codes

• One Resource_ids is loaded with HS software• 10 HS codes is allocated per cell.* • 96 HS users can be served over 6 cells• All cells can serve 16 HS users simultaneously• 96 Multi-Carrier users can be served over 3 sectors

simultaneously• One Resource_id is loaded with EUL software• 96 EUL users can be served over 6 cells• 321 CE available for R99 DCH shared over 6 cells• Note: with two resource ids used for HSDPA, it is also

possible to support 60 HS codes dynamically shared over 6 cells. Therefore this configuration is similar to B3.30 for 6cc,except that the 60 HS codes are fixed allocated to the 6cc

B3.9 for 3x2 Multi-Carrier (6cc)

Cell 2

Cell 3

Cell 1

16 HS users

10 HS codes

Cell 416 HS users

10 HS codes

16 HS users

10 HS codes

16 HS users

10 HS codesCell 6

Cell 5

89 CEMax128HS

users

15 HS codes

15 HS codes 15 HS codes

15 HS codes

Max128HS

usersPeak 128HS users

Peak 128HS users

Peak 128HS users

Peak 128HS users







512 768 37 750 / 1006 37



768 1022




384 512 / 768 43 583 / 967 43

When Increased Cell-Carrier Support for DUW, FAJ 121 3928, is activated the CE capacity is equally divided between the two baseband pools.


34 Net no of CE is equal to static CE for “DCH or EUL” = max number of users 35 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 36 Gross no of CE is equal to “DCH, CCH and Softer HO”. 37 Including 50% additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required 38 Net no of CE is equal to “DCH only”. 39 Gross no of CE is equal to “DCH, CCH and Softer HO”. 40 Net no of CE is equal to static CE for DCH or EUL = max number of users 41 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 42 Gross no of CE is equal to “DCH, CCH and Softer HO”. 43 Including 50% additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required




When a DUW 30 is configured with two baseband pools capacity trading is performed for each baseband pool separately. The yellow fields indicate that the Increased Cell Carrier feature for DUW, FAJ 121 3928, needs to be activated. If two figures are present in the field, e.g. 6 + 0, then the first figure is valid for the first baseband pool and the second figure for the second baseband pool.

E.g. DUW 30, with 2 way receive diversity, 200km cell range and a 6cc configuration (i.e. a single baseband pool), the net cost is 38 CE in uplink (i.e. 474 static CE available in the uplink for R99 + EUL). Table 9 DUW 30, 2 way receive diversity

E.g. DUW 30, with 4 way receive diversity, 100km cell range and a 6cc configuration, the net cost is 38 CE in uplink in the first baseband pool and the net cost is 38 CE in the second baseband pool (i.e. available static CE is 154 in the uplink for R99 + EUL in the first baseband pool and 154 static CE in the uplink for R99 + EUL in the second baseband pool). Table 10 DUW30, 4 way receive diversity

Cell Range Net CE cost, 3cc Net CE cost, 6cc Net CE cost, 9ccNet CE cost, 12cc35 0 0 0 080 0 0 6 + 0 6 + 6

200 0 38 Not Supported Not Supported

Cell Range Net CE cost, 3cc Net CE cost, 6cc35 0 040 0 080 0 22 + 22

100 0 38 + 38200 57 Not Supported




DUW 30 01: KDU 127 161/3

The following tables describe the additional downlink CE characteristics for DUW 30. The capacity figures in Table 11, Table 12 and Table 13 are calculated in the following way:


• Capacity figures with pale blue fields are calculated with resource pooling applied (the given number of HS users/cell is a peak value)

• If a Resource_ID is configured for more than 30 HS codes then feature Increased HSDPA code capacity on DUW, FAJ 121 2870, is needed. Capacity figures in red font indicate the feature is activated.



Table 11 DUW 30 with R99, R99+HS

No. Configuration Pooling applied1cc 2cc 3cc 4cc 6cc 6cc

C1.1 R99 768 768 768 768 768 768HS HS E-UL

users/cc codes/cc users/ccC2.1 R99+HS 4 5 - 765 762 760 757 752 -C2.2 R99+HS 16 5 - 757 747 736 726 705 -C2.3 R99+HS 32 5 - 747 726 705 684 643 684C2.4 R99+HS 48 5 - 736 705 674 643 452 684C2.5 R99+HS 64 5 - 726 684 643 601 390 684C2.6 R99+HS 96 5 - 705 643 452 262 684 -C2.7 R99+HS 128 5 - 684 601 390 179 684 -C2.8 R99+HS 4 10 - 765 762 760 757 752 -C2.9 R99+HS 16 10 - 757 747 736 726 705 -C2.10 R99+HS 32 10 - 747 726 705 684 643 684C2.11 R99+HS 48 10 - 736 705 674 643 452 684C2.12 R99+HS 64 10 - 726 684 643 601 390 684C2.13 R99+HS 96 10 705 643 452 262 684 -C2.14 R99+HS 128 10 - 684 601 390 179 684 -C2.15 R99+HS 4 15 - 765 762 760 757 624 -C2.16 R99+HS 16 15 - 757 747 736 726 577 601C2.17 R99+HS 32 15 - 747 726 705 684 515 601C2.18 R99+HS 48 15 - 736 705 674 643 452 601C2.19 R99+HS 64 15 - 726 684 643 601 390 601C2.20 R99+HS 96 15 705 643 452 262 601 -C2.21 R99+HS 128 15 - 684 601 390 179 601 -C2.22 R99+HS 4 30 dyn. - N/A 762 760 757 752 -C2.23 R99+HS 16 30 dyn. - N/A 747 736 726 705 -C2.24 R99+HS 32 30 dyn. - N/A 726 705 684 643 684C2.25 R99+HS 48 30 dyn. - N/A 705 674 643 452 684C2.26 R99+HS 64 30 dyn. - N/A 684 643 601 390 684C2.27 R99+HS 96 30 dyn. N/A 643 452 262 684 -C2.28 R99+HS 128 30 dyn. - N/A 601 390 179 684 -C2.29 R99+HS 4 60 dyn. - N/A N/A N/A 757 752 -C2.30 R99+HS 16 60 dyn. - N/A N/A N/A 726 705 -C2.31 R99+HS 32 60 dyn. - N/A N/A N/A 684 643 684C2.32 R99+HS 48 60 dyn. - N/A N/A N/A 643 452 684C2.33 R99+HS 64 60 dyn. - N/A N/A N/A 601 390 684C2.34 R99+HS 96 60 dyn. - N/A N/A N/A 262 684 -C2.35 R99+HS 128 60 dyn. - N/A N/A N/A 179 684 -





No. Configuration Pooling applied MC1cc 2cc 3cc 4cc 6cc 6cc 3x2cc


C3.1 R99+HS+EUL 4 5 4 765 762 760 757 752 - 752C3.2 R99+HS+EUL 16 5 4-16 757 747 736 726 705 - 705C3.3 R99+HS+EUL 32 5 4-32 747 726 705 684 515 684 515C3.4 R99+HS+EUL 48 5 4-48 736 705 546 515 324 684 324C3.5 R99+HS+EUL 64 5 4-64 726 684 515 473 262 684 262C3.6 R99+HS+EUL 96 5 4-96 705 515 324 134 684 - 684C3.7 R99+HS+EUL 128 5 4-128 684 473 262 51 684 - 684C3.8 R99+HS+EUL 4 10 4 765 762 760 757 752 - 752C3.9 R99+HS+EUL 16 10 4-16 757 747 736 726 705 - 705C3.10 R99+HS+EUL 32 10 4-32 747 726 705 684 515 684 515C3.11 R99+HS+EUL 48 10 4-48 736 705 546 515 324 684 324C3.12 R99+HS+EUL 64 10 4-64 726 684 515 473 262 684 262C3.13 R99+HS+EUL 96 10 4-96 705 515 324 134 684 - 684C3.14 R99+HS+EUL 128 10 4-128 684 473 262 51 684 - 684C3.15 R99+HS+EUL 4 15 4 765 762 760 757 624 - 624C3.16 R99+HS+EUL 16 15 4-16 757 747 736 726 577 - 577C3.17 R99+HS+EUL 32 15 4-32 747 726 705 684 515 - 515C3.18 R99+HS+EUL 48 15 4-48 736 705 546 515 324 473 324C3.19 R99+HS+EUL 64 15 4-64 726 684 515 473 262 473 262C3.20 R99+HS+EUL 96 15 4-96 705 515 324 134 473 - 473C3.21 R99+HS+EUL 128 15 4-128 684 473 262 51 473 - 473




Table 13 DUW 30 R99+HS+EUL, R99+HS+EUL+Multi-Carrier

Table 14 DUW 30 with Increased Cell-Carrier Support for DUW, R99+HS+E-UL, R99+HS+E-UL+Multi-Carrier, per BB pool



C3.22 R99+HS+EUL 4 30 dyn. 4 N/A 762 760 757 752 - 752C3.23 R99+HS+EUL 16 30 dyn. 4-16 N/A 747 736 726 705 - 705C3.24 R99+HS+EUL 32 30 dyn. 4-32 N/A 726 705 684 515 684 515C3.25 R99+HS+EUL 48 30 dyn. 4-48 N/A 705 546 515 324 684 324C3.26 R99+HS+EUL 64 30 dyn. 4-64 N/A 684 515 473 262 684 262C3.27 R99+HS+EUL 96 30 dyn. 4-96 N/A 515 324 134 684 - 684C3.28 R99+HS+EUL 128 30 dyn. 4-128 N/A 473 262 51 684 - 684C3.29 R99+HS+EUL 4 60 dyn. 4 N/A N/A N/A 757 752 - 752C3.30 R99+HS+EUL 16 60 dyn. 4-16 N/A N/A N/A 726 705 - 705C3.31 R99+HS+EUL 32 60 dyn. 4-32 N/A N/A N/A 684 515 684 515C3.32 R99+HS+EUL 48 60 dyn. 4-48 N/A N/A N/A 515 324 684 324C3.33 R99+HS+EUL 64 60 dyn. 4-64 N/A N/A N/A 473 262 684 262C3.34 R99+HS+EUL 96 60 dyn. 4-96 N/A N/A N/A 134 684 - 684C3.35 R99+HS+EUL 128 60 dyn. 4-128 N/A N/A N/A 51 684 - 684C3.36 R99+HS+EUL 4 90 dyn. 4 N/A N/A N/A N/A 624 - 624C3.37 R99+HS+EUL 16 90 dyn. 4-16 N/A N/A N/A N/A 577 - 577C3.38 R99+HS+EUL 32 90 dyn. 4-32 N/A N/A N/A N/A 515 - 515C3.39 R99+HS+EUL 48 90 dyn. 4-48 N/A N/A N/A N/A 324 473 324C3.40 R99+HS+EUL 64 90 dyn. 4-64 N/A N/A N/A N/A 262 473 262C3.41 R99+HS+EUL 96 90 dyn. 4-96 N/A N/A N/A N/A 473 - 473C3.42 R99+HS+EUL 128 90 dyn. 4-128 N/A N/A N/A N/A 473 - 473




C3.1 R99+HS+EUL 4 5 4 253 250 248 245 240 - 240C3.2 R99+HS+EUL 16 5 4-16 245 235 224 214 193 - 193C3.3 R99+HS+EUL 32 5 4-32 235 214 193 172 172 172 172C3.4 R99+HS+EUL 48 5 4-48 224 193 172 172 172 - 172C3.5 R99+HS+EUL 64 5 4-64 214 172 172 172 172 - 172C3.6 R99+HS+EUL 96 5 4-96 193 172 172 172 172 - 172C3.7 R99+HS+EUL 128 5 4-128 172 172 172 172 172 - 172C3.8 R99+HS+EUL 4 10 4 253 250 248 245 240 - 240C3.9 R99+HS+EUL 16 10 4-16 245 235 224 214 193 - 193C3.10 R99+HS+EUL 32 10 4-32 235 214 193 172 172 172 172C3.11 R99+HS+EUL 48 10 4-48 224 193 172 172 172 - 172C3.12 R99+HS+EUL 64 10 4-64 214 172 172 172 172 - 172C3.13 R99+HS+EUL 96 10 4-96 193 172 172 172 172 - 172C3.14 R99+HS+EUL 128 10 4-128 172 172 172 172 172 - 172C3.15 R99+HS+EUL 4 15 4 253 250 248 245 N/A - N/AC3.16 R99+HS+EUL 16 15 4-16 245 235 224 214 N/A - N/AC3.17 R99+HS+EUL 32 15 4-32 235 214 193 172 N/A - N/AC3.18 R99+HS+EUL 48 15 4-48 224 193 172 172 N/A - N/AC3.19 R99+HS+EUL 64 15 4-64 214 172 172 172 N/A - N/AC3.20 R99+HS+EUL 96 15 4-96 193 172 172 172 N/A - N/AC3.21 R99+HS+EUL 128 15 4-128 172 172 172 172 N/A - N/A




Table 15 DUW 30 with Increased Cell-Carrier Support for DUW, R99+HS+E-UL, R99+HS+E-UL+Multi-Carrier, per BB pool

Comments to Table 11, Table 12 and Table 13: 1. The number of “HSDPA users” and “HS-PDSCH codes/cc” is always “Up to”. 2. Max 512 users (HSDPA + DCH R99) can supported 3. “N/A” means that this configuration is not applicable, supported or possible. 4. “Dyn” means that feature “Dynamic Code Allocation” is activated. 30 HS-PDSCH codes can be shared between up to 2-6

cell-carriers (e.g. 5+5+5+5+5+5, 3+3+3+3+3+15) 5. A maximum of 256 EUL users in one base band pool is supported regardless of the number of cell carriers 6. When several cells are configured on one Resource_id the number of HS users per cells can vary due to resource pooling 7. Multi-Carrier implies even number of cell-carriers

Additional Comment to Table 14 and Table 15:

8. Requires feature Increased Cell-Carrier Support for DUW, FAJ 121 3928



C3.22 R99+HS+EUL 4 30 dyn. 4 N/A 250 248 245 240 - 240C3.23 R99+HS+EUL 16 30 dyn. 4-16 N/A 235 224 214 193 - 193C3.24 R99+HS+EUL 32 30 dyn. 4-32 N/A 214 193 172 172 172 172C3.25 R99+HS+EUL 48 30 dyn. 4-48 N/A 193 172 172 172 - 172C3.26 R99+HS+EUL 64 30 dyn. 4-64 N/A 172 172 172 172 - 172C3.27 R99+HS+EUL 96 30 dyn. 4-96 N/A 172 172 172 172 - 172C3.28 R99+HS+EUL 128 30 dyn. 4-128 N/A 172 172 172 172 - 172C3.29 R99+HS+EUL 4 60 dyn. 4 N/A N/A N/A 245 240 - 240C3.30 R99+HS+EUL 16 60 dyn. 4-16 N/A N/A N/A 214 193 - 193C3.31 R99+HS+EUL 32 60 dyn. 4-32 N/A N/A N/A 172 172 172 172C3.32 R99+HS+EUL 48 60 dyn. 4-48 N/A N/A N/A 172 172 - 172C3.33 R99+HS+EUL 64 60 dyn. 4-64 N/A N/A N/A 172 172 - 172C3.34 R99+HS+EUL 96 60 dyn. 4-96 N/A N/A N/A 172 172 - 172C3.35 R99+HS+EUL 128 60 dyn. 4-128 N/A N/A N/A 172 172 - 172C3.36 R99+HS+EUL 4 90 dyn. 4 N/A N/A N/A N/A 172 172 172C3.37 R99+HS+EUL 16 90 dyn. 4-16 N/A N/A N/A N/A 172 172 172C3.38 R99+HS+EUL 32 90 dyn. 4-32 N/A N/A N/A N/A 172 - 172C3.39 R99+HS+EUL 48 90 dyn. 4-48 N/A N/A N/A N/A 172 - 172C3.40 R99+HS+EUL 64 90 dyn. 4-64 N/A N/A N/A N/A 172 - 172C3.41 R99+HS+EUL 96 90 dyn. 4-96 N/A N/A N/A N/A 172 - 172C3.42 R99+HS+EUL 128 90 dyn. 4-128 N/A N/A N/A N/A 172 - 172





736 CE

10 HS codes

16 HS users

16 HS users

16 HS users

16 EUL users

16 EUL users

16 EUL users

10 HS codes

10 HS codes

• One Resource_id is loaded with HS software• 10 codes are allocated per cell • 48 HS users can be served over 3 cells• One Resource_id is loaded with EUL software• 48 EUL users can be served over 3 cells. • 736 CE available for R99 DCH shared over 3 cells

C3.9

27 HS codes

736 CE

1 HS code

16 HS users

16 HS users

16 HS users

16 EUL users

16 EUL users

16 EUL users

1 HS code

1HS code


C3.23 Cell 2

Cell 2

Cell 3

Cell 3

Cell 1

Cell 1

515 CE

10 HS codes

64HS users

64 HS users

64HS users

10 HS codes

10 HS codes

• Two Resource_id are loaded with HS software• 10 codes are are allocated per cell • 192 HS users can be served over 3 cells • One Resource_id is loaded with EUL software• 96 EUL users can be served over 3 cells• All cells can serve a maximum of 64 HS users simultaneously• Note: with two resource ids used for HSDPA, it is also

possible to support 15 HS codes per cell,as described in C3.17

C3.12Cell 2

Cell 3

Cell 1

Max 128 HS users

684 CE

10 HS codes

Peak 64HS users

Peak 64 HS users

Peak 64HS users

10 HS codes

10 HS codes

• One Resource_id is loaded with HS software• 10 codes are are allocated per cell• 128 HS users can be served over 3 cells• Each cell can serve a maximum of 64 HS users• The A-DPCH reservation is done for a maximum of 128 HS

users, as this is the maximum supported on one HS resource, which leaves 684 CE for R99 DCH

C3.12 for 3x1 (3cc) with resource poolingCell 2

Cell 3

Cell 1

32 EUL users

32 EUL users

32 EUL users

32 EUL users

32 EUL users

32 EUL users



Max 128 HS users

684 CE

5 HS codes

Peak 32 HS users

Peak 32 HS users

5 HS codes• One Resource_id is loaded with HS software• 5 codes are allocated per cell. • 128 HS users can be served over 6 cells• Each cell can serve a maximum of 32 HS users• One Resource_id is loaded with EUL software• 128 EUL users can be served over 6 cells• The A-DCH reservation is done for a maximum of 128 HS users, as this is the maximum supported on one HS resource, which leaves 684 CE for R99 DCH• Note: it is also possible to support a peak of 128 HS users per cell,

with the same configuration, as described in C3.7

C3.3 for 3x2 or 6x1 (6cc) with resource pooling

Cell 2

Cell 3

Cell 1

Peak 32 HS users

5 HS codes


5 HS codes

Peak 32 HS users

5 HS codes

Peak 32 HS users

5 HS codesCell 6

Cell 5

515 CE

5 HS codes

32 HS users

32 HS users

5 HS codes• Two Resource_ids are loaded with HS software• 5 codes are allocated per cell. • 192 HS users can be served over 6 cells• All cells can serve 32 HS users simultaneously• One Resource_id is loaded with EUL software• 128 EUL users can be served over 6 cells• Note: with two resource ids used for HSDPA, it is alsopossible to support 10 HS codes per cell,as described in C3.9

C3.3 for 3x2 or 6x1 (6cc)

Cell 2

Cell 3

Cell 1

32 HS users

5 HS codes

Cell 432 HS users

5 HS codes

32 HS users

5 HS codes

32 HS users

5 HS codesCell 6

Cell 5

Max 128 HS users24 HS codes

684 CE

1 HS code

Peak 32 HS users

Peak 32 HS users

1 HS code• One Resource_id is loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 24 codes are dynamically distributed over 6 cells• 128 HS users can be served over 6 cells• Each cell can serve a maximum of 32 HS users• One Resource_id is loaded with EUL software• 128 EUL users can be served over 6 cells• The A-DCH reservation is done for a maximum of 128 HS users,

as this is the maximum supported on one HS resource, which leaves 684 CE for R99 DCH• Note: it is also possible to support a peak of up to 128 HS users

per cell, with the same configuration, as described in C3.28

C3.24 for 3x2 or 6x1 (6cc) with resource pooling

Cell 2

Cell 3

Cell 1

Peak 32 HS users

1 HS code


1 HS code

Peak 32 HS users

1 HS code

Peak 32 HS users

1 HS codeCell 6

Cell 5

1 HS code

32 HS users

32 HS users

1 HS code • Two Resource_ids are loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 54 codes are dynamically distributed over 6 cells• 192 HS users can be served over 6 cells• All cells can serve 32 HS users simultaneously• One Resource_id is loaded with EUL software• 192 EUL users can be served over 6 cells• * Note: with two resource ids used for HSDPA, it is also

possible to support 60 HS codes shared over 6 cells. Thereforethis configuration is similar to C3.10 for 6cc, except that the60 HS codes are dynamically allocated and shared over all 6cc

C3.31 for 3x2 or 6x1 (6cc) with 60 HS codes dynamic*

Cell 2

Cell 3

Cell 1

32 HS users

1 HS code

Cell 432 HS users

1 HS code

32 HS users

1 HS code

32 HS users

1 HS codeCell 6

Cell 5

27HS

codes

27HS codes

515CE



300 CE

1 HS code

32 HS users

32 HS users

1 HS code• Two Resource_ids is loaded with HS software• Dynamic code allocation is activated. • 1 code is allocated per cell. • The remaining 84 codes are dynamically distributed over 6 cells. *• Max 15 HS codes in one cell • 192 HS users can be served over 6 cells• All cells can serve 32 HS users simultaneously• One Resource_id is loaded with EUL software• 192 EUL users can be served over 6 cells• 515 CE available for R99 DCH shared over 6 cells

C3.38 for 3x2 or 6x1 (6cc) with 90 HS codes dynamic

Cell 1

Cell 2

Cell 6

32 HS users

1 HS code

Cell 332 HS users

1 HS code

32 HS users

1 HS code

32 HS users

1 HS codeCell 5

Cell 4

515 CE

10 HS codes

32 HS users

32 HS users

10 HS codes • Two Resource_ids are loaded with HS software

• 10 HS codes is allocated per cell. • 192 HS users can be served over 6 cells• All cells can serve 32 HS users simultaneously• One Resource_id is loaded with EUL software• 192 EUL users can be served over 6 cells• 515 CE available for R99 DCH shared over 6 cells• Note: with two resource ids used for HSDPA, it is alsopossible to support 60 HS codes dynamically shared over 6 cells. Therefore this configuration is similar to C3.31 for 6cc,except that the 60 HS codes are fixed allocated to the 6cc

C3.10 for 3x2 or 6x1 (6cc)

Cell 2

Cell 3

Cell 1

32 HS users

10 HS codes

Cell 432 HS users

10 HS codes

32 HS users

10 HS codes

32 HS users

10 HS codesCell 6

Cell 5

515 CE42HS codes

42HS

codes

705 CE

10 HS codes

16 HS users

16 HS users

10 HS codes

• One Resource_ids are loaded with HS software• 10 HS codes is allocated per cell. *• 96 HS users can be served over 6 cells• All cells can serve 16 HS users simultaneously• 96 Multi-Carrier users can be served over 3 sectors

simultaneously• One Resource_id is loaded with EUL software• 96 EUL users can be served over 6 cells• 449 CE available for R99 DCH shared over 6 cells• Note: with one resource ids used for HSDPA, it is also

possible to support 60 HS codes dynamically shared over 6 cells. Therefore this configuration is similar to C3.30 for 6cc,except that the 60 HS codes are fixed allocated to the 6cc

C3.9 for 3x2 Multi-Carrier (6cc)

Cell 2

Cell 3

Cell 1

16 HS users

10 HS codes

Cell 416 HS users

10 HS codes

16 HS users

10 HS codes

16 HS users

10 HS codesCell 6

Cell 5

300 CE

15 HS codes

Peak 128HS users

Peak 128 HS users

15 HS codes• Two Resource_ids are loaded with HS software• 15 HS codes are allocated per cell. *• 256 HS users can be served over 6 cells• Max 128 HS users in one cell• 256 Multi-Carrier users can be served over 3 sectors



C3.21 for 3x2 Multi-Carrier (6cc), asymmetric*

Cell 1

Cell 2

Cell 6

Cell 3

Cell 5

Cell 4

473CE

Max128HS

users

15 HS codes

15 HS codes 15 HS codes

15 HS codes

Max128HS

usersPeak 128HS users

Peak 128HS users

Peak 128HS users

Peak 128HS users




300 CE

15 HS codes

15 HS codes

• Two Resource_ids are loaded with HS software• 15 HS codes is allocated per cell. *• 256 HS users can be served over 6 cells• Each cells can serve a maximum of 128 HS users• 256 Multi-Carrier users can be served over 3 sectors



C3.21 for 3x2 Multi-Carrier (6cc) with assymmetric*

Cell 1

Cell 2

Cell 6

Peak 128 HS users

Cell 3

15 HS codes

Cell 5

Cell 4

262 CE

15 HS codes

64 HS users

64 HS users

15 HS codes

• Three Resource_ids are loaded with HS software• 15 HS codes is allocated per cell. • 384 HS users can be served over 6 cells• All cells can serve 64 HS users simultaneously• 256 Multi-Carrier users can be served over 3 sectors

simultaneously• One Resource_id is loaded with EUL software• 256 EUL users can be served over 6 cells• Maximum 64 EUL users in one cell• 262 CE available for R99 DCH shared over 6 cells

C3.19 for 3x2 Multi-Carrier (6cc)

Cell 2

Cell 3

Cell 1

64 HS users

15 HS codes

Cell 464 HS users

15 HS codes

64 HS users

15 HS codes

64 HS users

15 HS codesCell 6

Cell 5

473CE

128HS users

128HS users

15 HS codes

15 HS codes

15 HS codes

Peak 128 HS users

Peak 128 HS users

Peak 128 HS users

Peak 128 HS users

Peak 128 HS users

4.6 RBS 6302 (WCDMA) One RBS 6302 can be equipped with one or two Outdoor Digital units WCDMA (ODW). ODW 30 is the baseband unit in the RBS 6302 main unit and is an outdoor convection cooled Digital Unit. For WCDMA it is possible to configure two Outdoor Digital units WCDMA (ODW 30) to form a WCDMA 3x4 configuration. The characteristics and capacity of ODW 30 is equal to DUW 30 in chapter 4.5.







192 288 47 271 / 367 47



288 398




144 288 53 208 / 352 53


44 Net no of CE is equal to static CE for “DCH or EUL” = max number of users 45 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 46 Gross no of CE is equal to “DCH, CCH and Softer HO”. 47 Including additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required 48 Net no of CE is equal to “DCH only”. 49 Gross no of CE is equal to “DCH, CCH and Softer HO”. 50 Net no of CE is equal to static CE for DCH or EUL = max number of users 51 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 52 Gross no of CE is equal to “DCH, CCH and Softer HO”. 53 Including additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required




E.g. DUW 11, with 2 way receive diversity, 200km cell range and a 2cc configuration, the net cost is 19 CE in uplink (i.e. 109 CE available in the uplink for R99 + EUL). Table 16, DUW 11, 2 way receive diversity

Table 17, DUW 11, 4 way receive diversity

Cell Range Net CE cost, 1cc Net CE cost, 2cc Net CE cost, 3cc Net CE cost, 4cc Net CE cost, 5cc Net CE cost, 6cc35 0 0 0 0 0 080 0 0 3 Not Supported Not Supported Not Supported

200 0 19 Not Supported Not Supported Not Supported Not Supported

Cell Range Net CE cost, 1cc Net CE cost, 2cc Net CE cost, 3cc35 0 0 040 0 0 380 0 11 Not Supported

100 0 19 Not Supported200 19 Not Supported Not Supported



DUW 11 can simultaneously support:

• Max 192 users (HSDPA + DCH R99)

• HSDPA up to 30 / 90 54 HS Codes

• EUL up to 128 users

• 288 Downlink CE

As DUW 11 does not need to trade DL CE resources with HSDPA code and EUL TXM resources, i.e. tables similar to the ones for DUW 10/20/30 will not be needed. Instead available HW capacity for DCH R99 CE will be calculated according to:

DL R99 CE = 192 – ( 1.3 x #HSDPA users x 0.5 CE )

#HSDPA users is total amount of HSDPA users in the Baseband pool. For Combined cell (FAJ 121 3249), please refer to Appendix A – Combined Cell.


Please also refer to chapter 4.2.3 for more details.

If DUW 11 is configured for more than 30 HS codes then feature Increased HSDPA code capacity on DUW, FAJ 121 2870, is needed.


DUW 11 01: KDU 127 174/1

54 Using FAJ 121 2870, Increased HSDPA Code Capacity on DUW, for up to 90 HS codes






768 1152 58 1082 / 1466 58



768 1022



When Increased Cell-Carrier Support for DUW, FAJ 121 3928, is activated the CE capacity is equally divided between the two baseband pools.




576 1152 64 833 / 1409 64




When a DUW 31 is configured with two baseband pools capacity trading is performed for each baseband pool separately. The yellow fields indicate that the Increased Cell Carrier feature for DUW, FAJ 121 3928, is activated. If two figures are present in the field, e.g. 6 + 6, then the first figure is valid for the first baseband pool and the second figure for the second baseband pool.

E.g. DUW 31, with 2 way receive diversity, 200km cell range and a 6cc configuration, the net cost is 38 CE in uplink (i.e. 474 CE available in the uplink for R99 + EUL). Table 18, DUW 31, 2 way receive diversity

E.g. DUW 31, with 4 way receive diversity, 80km cell range and a 6cc configuration, the net cost is 22 CE in uplink in the first baseband pool and the net cost is 22 CE in the second baseband pool (i.e. available static CE is 170 in the uplink for R99 + EUL in the first baseband pool and 170 static CE in the uplink for R99 + EUL in the second baseband pool). Table 19, DUW 31, 4 way receive diversity

Cell Range Net CE cost, 3cc Net CE cost, 6cc Net CE cost, 9ccNet CE cost, 12cc35 0 0 0 080 0 0 6 + 0 6 + 6

200 0 38 Not Supported Not Supported

Cell Range Net CE cost, 3cc Net CE cost, 6cc35 0 040 0 080 0 22 + 22

100 0 38 + 38200 57 Not Supported



DUW 31 can simultaneously support:

• Max 768 users (HSDPA + DCH R99).

• HSDPA up to 90 HS Codes when the DUW31 is configured with a single baseband pool and 180 HS Codes when the DUW31 is configured with 2 baseband pools.

• EUL up to 384 users per baseband pool.

• 768 Downlink CE

As DUW 31 does not need to trade DL CE resources with HSDPA code and EUL TMX resources, i.e. tables similar to the ones for DUW 10/20/30 will not be needed. Instead available HW capacity for DCH R99 CE will be calculated according to:


#HSDPA users is total amount of HSDPA users in the Baseband pool. For Combined cell (FAJ 121 3249), please refer to Appendix A – Combined Cell.

If feature Increased Cell-Carrier Support for DUW (FAJ 121 3928) is activated, then available DL R99 CE per BB pool is calculated using 50% of the total downlink CE, as an equal distribution of the total DL R99 CE is applied.




DUW 31 01: KDU 127 174/3





Net no. of CE 65 CE for EUL66 Gross no. of CE 67

1152 1728 68 1624 / 2200 68



1152 1522




864 1728 74 1249 / 2113 74

When Increased Cell Carrier support for DUW, FAJ 121 3928, is activated the CE capacity is equally divided between the two baseband pools.

• For a DL capacity overview associated with Combined cell (FAJ 121 3249), please refer to Appendix A – Combined Cell





When a DUW 41 is configured with two baseband pools capacity trading is performed for each baseband pool separately. The yellow fields indicate the Increased Cell Carrier feature for DUW, FAJ 121 3928, is activated. If two figures are present in the field, e.g. 6 + 6, then the first figure is valid for the first baseband pool and the second figure for the second baseband pool.



Cell Range Net CE cost, 3cc Net CE cost, 6cc Net CE cost, 9ccNet CE cost, 12cc35 0 0 0 080 0 0 0 0

200 0 0 57 + 0 57 + 57

Cell Range Net CE cost, 3cc Net CE cost, 6cc35 0 040 0 080 0 0

100 0 0200 57 57 + 57



DUW41 can simultaneously support:

• Max 768 users (HSDPA + DCH R99).

• HSDPA up to 90 HS Codes when the DUW41 is configured with a single baseband pool and 180 HS Codes when the DUW41 is configured with 2 baseband pools.

• EUL up to 384 users per baseband pool.

• 1152 Downlink CE

As DUW 41 does not need to trade DL CE resources with HSDPA code and EUL TMX resources, i.e. tables similar to the ones for DUW 10/20/30 will not be needed. Instead available HW capacity for DCH R99 CE will be calculated according to:


#HSDPA users is total amount of HSDPA users in the Baseband pool.

For Combined cell (FAJ 121 3249), please refer to Appendix A – Combined Cell.

If feature Increased Cell-Carrier Support for DUW (FAJ 121 3928) is activated, then available DL R99 CE per BB pool is calculated using 50% of the total downlink CE, as an equal distribution of the total DL R99 CE is applied.




DUW 41 01: KDU 127 174/4



4.10 RBS 6501 (WCDMA) The baseband unit in the RBS 6501 has the following characteristics and capacity for WCMDA.

The RBS 6501 can support the following:


Net no. of CE 75 CE for EUL76 Gross no. of CE 77

96 144 78 146 / 194 78



96 149

The RBS 6501 can support up to 6 WCDMA carriers. 4 WCDMA carriers integrated in the RBS 6501 and additional 2 carriers with additional mRRUS.

The RBS 6501 can simultaneously support:

• Max 64 users (HSDPA + DCH R99)

• HSDPA up to 30 / 6081 HS Codes

• EUL up to 64 users

• 96 Downlink CE

The downlink CE usable for DCH R99 is calculated according to chapter 4.2.3.

75 Net no of CE is equal to static CE for “DCH or EUL” = max number of users 76 CE for EUL is equal to Total CE. The extra dynamic CE beyond static CE can only be used for EUL. 77 Gross no of CE is equal to “DCH, CCH and Softer HO”. 78 Including additional Dynamic Channel Elements, FAJ 121 2598, CE extension for EUL, is required 79 Net no of CE is equal to “DCH only”. 80 Gross no of CE is equal to “DCH, CCH and Softer HO”. 81 Using FAJ 121 2870, Increased HSDPA Code Capacity on DUW, for up to 60 HS codes



5 Hardware Activation Codes (HWAC) Hardware activation codes support the option of providing a pay as you grow model for hardware capacity, (e.g. pay as you grow for Channel Elements). The hardware delivered may be capable of higher capacity than requested by customer. By locking capacity with Hardware Activation Codes, we can offer a pay-as-you-grow model, so the customer will initially only pay for the actual requested capacity and still have a smooth way to grow capacity without having to exchange or add new hardware modules.

Hardware Activation Codes are orderable together with the hardware in the RBS Product Package, but are also orderable as bulk in a separate Product Package.

The following HW Activation Codes are applicable:

• Channel Element DL, 16 – 1152 CE per DUW, in step of 16

o DL CE HWAC = DCH CE + A-DCH and F-DPCH CE

• Channel Element UL, 16 – 1152 CE per DUW, in step of 16

o UL CE HWAC = Net no. of CE + Additional Dynamic CE for EUL

• High Speed Codes (HSDPA), 0 – 180 codes per DUW, in step of 5

• STM-1

• IP, electrical

• IP, Optical



6 Large Configurations For large configurations, (e.g. 3x3, 3x4 and 6x2), multiple baseband pools are used. DUW30, DUW31 and DUW41 are capable to support 2 baseband pools when it is operated as primary DUW. DUW10, DUW20 and DUW11 and secondary DUWs are capable to support one baseband pool. Each baseband pool is capable to handle up to 6 cell-carriers (with 2RX diversity) and 3 cell-carriers (with 4RX diversity). Each baseband pool is dimensioned separately according to the rules applicable for one baseband pool.

In RBS 6000 nodes, it is possible to mix DUW variants, maximum two, and optimize the desired capacity per carrier. Some examples of how to combine DUW variants and optimize capacity per carrier are as follows:

DUW 103x1

DUW 103x1

DUW 103x1

DUW 103x1

DUW 313x2

3x3 RBS 6000 node

+

DUW 203x1

DUW 203x2

e

Figure 6 Examples of how to combine DUW variants



7 Transport network interfaces The mobile backhaul solution of any mobile Operator is often unique and depends on the Operator’s requirements and the market conditions.

MinilinkTN

MinilinkTN

MinilinkTN

MinilinkTN

Mobile backbone

BTS/Node B

OMS800/1410

OMS800/1410

BTS/Node B

MinilinkTN

OMS800/1410

OMS1600

OMS1600

OMS1600

RNC BSC

BTS/Node B

MinilinkTN

OMS1600

BTS/Node B

BTS/Node B

OMS1410

SDH SDH

OMS800OMS800

BTS/Node B

MinilinkTN

MinilinkTN

Figure 7 Overview of a transport network solution



The physical interfaces for connection to the transport network node on the DUW are:

100/1000 Base-T Ethernet

Optical interface port for Gigabit Ethernet SFPs

Multi Mode Fiber up to 0,55 km

Single Mode Fiber up to 10 km



Optical interface port for STM-182

155 Mbit/s, STM-1/VC12, OC-3/VT-1.5. Channelized STM-1 with 28 T1 or 21 E1 ATM or STM streams

Four IMA capable E1/T1/J1 ports83

2x 120 ohm RJ45 connectors

In addition to the TN interfaces on the DUW, it is possible to add transport interface units to support additional TN interfaces and functionality.

For single standard radio operation only, the transmission interface in the digital unit is normally sufficient.

For multi standard radio operation the Transport Connectivity Unit 02 (TCU 02) can be used to support one common backhaul interface. The common transmission interface can be either Ethernet or IP over E1/T1. The TCU 02 has the same form factor as e.g. a DUL20. When modernizing an RBS 3000 site where the Ethernet switch functionality in the ET-MFX board is used, TCU 02 or SIU 02 can be used to replace the ET-MFX board.

The Site Integration Unit 02 (SIU 02) adds transport sharing functionality, Site-LAN and Site Aggregation functionality to an Ericsson RBS 6000 node. For a multi standard configuration the SIU provides IP aggregation over both Ethernet and E1/T1 transport networks. In addition, the IP SIU enables operators to enhance the IP functionality of the RBS 6000 node, for example to support IPSec, enhanced IP synchronization, IP load-sharing etc. See ref [1] for details.

82 Not applicable for DUW 31 83 Not applicable for DUW 31



The Transport Interface unit (TIU) is a plug-in unit to extend the number of E1/T1 ports up to 16. The TIU provides E1/T1 cross-connection to the STM-1 interface on the DUW module. The channelized STM-1 is broken out into electrical E1/T1s, which can be delivered to the PDH electrical demarcation point. The TIU fits in the transmission space of the Macro RBS 6000 and two options exist:

o Basic package, for up to 16 E1/T1 electrical interfaces.

o Extended package, for up to 16 E1/T1, with an option to expand with Microwave links in the future (3 U high).

Please see ref [2] for details.



Figure 8 Examples of the transport options for RBS 6201

IP SIU

TIU, basic

TIU, extended package

TCU 02



8 Radio Unit Interface Each DUW in the node is equipped with six connectors, for connection to the radio units (the radio unit can be co-located together in the cabinet with the DUW or can be a remote radio unit mounted in the mast close to the antenna).

The DUW radio interface supports three types of radio units, radio units with electrical CPRI, radio units with optical CPRI and radio units with the gamma interface (only valid for RBS 3000 nodes). Electrical and optical CPRI is selected with help of SFP Modules (Small Form factor Pluggable).



9 Acronyms and Abbreviations

Abbreviation Meaning

3GPP 3rd Generation Partnership Project

16QAM 16-Quadrature Amplitude Modulation

A-DPCH Associated DPCH

BB Baseband

BP Board Processor

CC Cell Carrier

CCH Common Channel

CE Channel Element

CM Compressed Mode

CPRI Common Public Radio Interface

CS Circuit Switched

DCH Dedicated Channel

DEC Decoder

DEM Demodulator

DL Downlink

DPDCH Dedicated Physical Data Channel

DUW Digital Unit WCDMA

EUL Enhanced Uplink

EM Element manager

ENC Encoder

HO Hand-Over

HS High Speed

HS-DSCH HS Downlink Shared Channel

HS-SCCH HS Shared Control Channel

HSDPA High Speed Downlink Packet Access

HW Hardware

MBMS Multimedia Broadcast/Multicast Service

MO Managed Object

MOD Modulation



Abbreviation Meaning

MRC Maximum Ratio Combining

O&M Operation and Maintenance

OSS-RC Operations Support System – Radio & Core

QPSK Quadrature Phase-Shift Keying

PS Packet Switched

R99 Release 99

RA Random Access

RACH Random Access Channel

RAN Radio Access Network

RBS Radio Base Station

RLS Radio Link Set

RNC Radio Network Controller

RxD Receiver Diversity

SF Spreading Factor

SW Software

TTI Transmission Time Interval

TxD TX Diversity

UL Uplink

UMTS Universal Mobile Telephony System

WCDMA Wideband Code Division Multiple Access

XCU Auxiliary Converter Unit

10 References [1] Site Integration Unit web page in Product Catalogue

[2] TIU Ordering guide Site Transmission - TIU in RBS 6000

http://prodcat.ericsson.se/frontend/product.action?code=FGC%20101%200285&path=\Navigation%20Root\FGA%20101%2017\FGB%20101%20220\FGB%20101%20645

http://gask2web.ericsson.se/pub/picov/get?DocNo=1/2135-FCP1303624&Lang=EN&HighestFree=Y%20



11 Appendix A – Combined Cell The feature FAJ 121 3249 Combined Cell is supported on DUW from W14B. The DL CE capacity for combined cell solutions is described below. The notation “X CC x Y CP” used in the table describes a configuration where there are X combined cells and each combined cell is composed of 3 cell portions.

The table below describes the uplink CE capacity when combined cell is configured.

No. Configuration DUW10 DUW20 DUW301CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

1CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

1CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

HS users/ HS codes/ EUL users/ combined cell combined cell combined cell

C3.1 R99+HS+EUL 4 1..15 4 68 63 105 100 216 211 327 322 364 359 549 544C3.2 R99+HS+EUL 16 1..15 4-16 53 32 90 69 201 180 312 291 349 328 534 513C3.3 R99+HS+EUL 32 1..15 4-32 32 N/A 69 27 180 138 291 249 328 286 513 471C3.4 R99+HS+EUL 48 1..15 4-48 11 N/A 48 N/A 159 97 270 208 307 245 492 430C3.5 R99+HS+EUL 64 1..15 4-64 N/A N/A 27 N/A 138 55 249 166 286 203 471 388C3.6 R99+HS+EUL 96 1..15 4-96 N/A N/A N/A N/A 97 N/A 208 83 245 120 430 305C3.7 R99+HS+EUL 128 1..15 4-96 N/A N/A N/A N/A 55 N/A 166 N/A 203 37 388 222

No. Configuration DUW11 DUW31 DUW411CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

1CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

1CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

HS users/ HS codes/ EUL users/ combined cell combined cell combined cell

C4.1 R99+HS+EUL 4 5 4 96 94 144 141 390 388 585 582 586 584 879 876C4.2 R99+HS+EUL 16 5 4-16 91 84 136 126 385 378 577 567 581 574 871 861C4.3 R99+HS+EUL 32 5 4-32 84 70 126 105 378 364 567 546 574 560 861 840C4.4 R99+HS+EUL 48 5 4-48 77 56 115 84 371 350 556 525 567 546 850 819C4.5 R99+HS+EUL 64 5 4-64 70 42 105 63 364 336 546 504 560 532 840 798C4.6 R99+HS+EUL 96 5 4-96 56 14 84 22 350 308 525 463 546 504 819 757C4.7 R99+HS+EUL 128 5 4-96 42 N/A 63 N/A 336 281 504 421 532 477 798 715

DUW10 DUW20 DUW301CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

1CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

1CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

Static UL CEs 96 96 96 96 288 288 288 288 384 384 384 384Total EUL CEs 192 192 192 192 576 576 576 576 768 768 768 768

DUW11 DUW31 DUW411CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

1CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

1CC x 3CP

2CC x 3CP

1CC x 2CP

2CC x 2CP

Static UL CEs 144 144 144 144 576 576 576 576 864 864 864 864Total EUL CEs 288 288 288 288 1152 1152 1152 1152 1728 1728 1728 1728



When combined cell is configured the following number of users is supported:

• Max 96 HSDPA + DCH users on DUW10.








Figure 9 Examples of two Combined cells, each carrier with 3 cell portions