3GPP Standardisation 2007 - 20082ffbbddf-445f-4e2b-bae5... · 3GPP Standardisation 2007 - 2008 ....

Technical Note PR-TN 2009/00177

Issued: 04/2009

3GPP Standardisation 2007 - 2008

M.P.J. Baker

Philips Research Cambridge

Unclassified Koninklijke Philips Electronics N.V. 2009

PR-TN 2009/00177 Unclassified

ii Koninklijke Philips Electronics N.V. 2009

Authors’ address

M.P.J. Baker [email protected]

© KONINKLIJKE PHILIPS ELECTRONICS NV 2009 All rights reserved. Reproduction or dissemination in whole or in part is prohibited without the prior written consent of the copyright holder .

Unclassified PR-TN 2009/00177

Koninklijke Philips Electronics N.V. 2009 iii

Title: 3GPP Standardisation 2007 - 2008

Author(s): M.P.J. Baker

Reviewer(s): Terry Doyle; Ruud van Bokhorst

Technical Note: PR-TN 2009/00177

Project: Tracking and Analysis of 3GPP Standards (2000-146)

Customer: NXP Semiconductors

Keywords:

Abstract: This report reviews work carried out under SLA for NXP under the title

“Tracking and Analysis of 3GPP Standards” during 2007 and 2008.

An overview of the status of the standardisation work in 3GPP is provided, together with an outline for its continuation. The report also details the contributions made by the project to 3GPP and NXP/ST-NXP during the period of the SLA.

Conclusions:

The project “Tracking and Analysis of 3GPP Standards” has made significant contributions to the standardisation activities in 3GPP during 2007 and 2008, as well as to supporting development and strategy activities in NXP and ST-NXP.

During this period, Releases 7 and 8 of the WCDMA High-Speed Packet Access Specifications were completed, including MIMO technology for the first time in a cellular system. In parallel, the first version of the groundbreaking LTE specifications was completed, paving the way towards the 4th Generation. This work is set to continue as studies progress into LTE-Advanced.

3GPP is now by far the world’s largest standardisation activity for wireless communications. Earlier rivalry from 3GPP2 and the Qualcomm-inspired CDMA2000 family of standards has faded, confirming the 3GPP-developed systems as the global standard for the future. Moreover, recent months have seen numerous major operators and vendors (including Ericsson, Nokia and Alcatel-Lucent) committing to LTE technology rather than the IEEE’s WiMAX. This will help to assure economies of scale and global interoperability in the decades to come.


iv Koninklijke Philips Electronics N.V. 2009


Koninklijke Philips Electronics N.V. 2009 v

Contents

1. Introduction .............................................................................................................. 7

2. 3GPP Roadmap and Status ..................................................................................... 8

2.1. HSPA Evolution ................................................................................................ 9

2.1.1. References ........................................................................................... 10

2.2. LTE 11

2.2.1. Multicarrier technology ....................................................................... 11

2.2.2. Multiple antenna technology ............................................................... 12

2.2.3. Packet-Switched Radio Interface ........................................................ 13

2.2.4. Flat Network Architecture ................................................................... 13

2.2.5. References ........................................................................................... 13

2.3. Beyond LTE .................................................................................................... 14

3. Contributions to 3GPP ........................................................................................... 16

3.1. RAN WG1 (physical layer) ............................................................................. 16

3.1.1. HSPA ................................................................................................... 16

3.1.2. LTE ...................................................................................................... 16

3.1.3. LTE-A ................................................................................................. 17

3.2. RAN WG2 (protocols) .................................................................................... 17

3.2.1. HSPA ................................................................................................... 17

3.2.2. LTE ...................................................................................................... 18

4. Knowledge Transfer to NXP ................................................................................. 19

5. Conclusions and Future Outlook .......................................................................... 20

A Documents submitted to 3GPP .............................................................................. 21

A.1 RAN WG1 ............................................................................................................... 21

A.2 RAN WG2 ............................................................................................................... 34

A.3 RAN Plenary ........................................................................................................... 36

B 3GPP Meetings Attended ....................................................................................... 38


vi Koninklijke Philips Electronics N.V. 2009

B.1 2007 .......................................................................................................................... 38

B.2 2008 .......................................................................................................................... 38


Koninklijke Philips Electronics N.V. 2009 7

1. Introduction This report concludes the work carried out under SLA for NXP under the title “Tracking and Analysis of 3GPP Standards” during 2007 and 2008.

The project focused on the physical and protocol layers of the radio access network standardisation for UMTS, HSPA and LTE. The key outputs comprised transfer of knowledge and expertise to the NXP development teams, and, from August to November 2008, to ST-NXP Wireless.

This report provides an overview of the status of the standardisation work in 3GPP and an outline for its continuation, as well as detailing the contributions made by the project to 3GPP and NXP/ST-NXP during the period of the SLA.


8 Koninklijke Philips Electronics N.V. 2009

2. 3GPP Roadmap and Status Standardisation in 3GPP is proceeding in two parallel tracks: evolution of the original UMTS WCDMA air interface, and the development of LTE. Within each track, each specification release is fully backward-compatible, but the transition from the WCDMA air interface to LTE is non-backward-compatible, requiring multi-mode terminals and independent network infrastructure. This is illustrated in Figure 1.

UMTS Release 99 HSDPA HSUPA Release 7 HSPA+

LTE LTE-A

Rel-8 Rel-9 Rel-10

Figure 1: Standardisation tracks in 3GPP

From Release 8 onwards, the specification releases are linked between HSPA and LTE. Thus the first release of LTE is Release 8. The approximate timescales of each release, together with typical or projected deployment dates, are shown in Figure 2.

Figure 2: Approximate timelines for each 3GPP specification release



2.1. HSPA Evolution

HSPA evolution, otherwise known as HSPA+, provides a smooth upgrade path for operators who have already invested in WCDMA networks.

Three general trends can be observed in HSPA evolution:

1. Support for packet-switched services, especially based on IP, with improved terminal battery life through discontinuous transmission and reception;

2. Support for higher data rates through the use of wider bandwidths (multiple 5MHz carriers) with wide area coverage;

3. Support for higher peak data rates through higher spectral efficiency (MIMO and higher-order modulation), generally achievable only in small coverage areas.

The strongest support for the HSPA evolution track comes from Qualcomm, Ericsson, Nokia/NSN, Samsung, Huawei. The interested operators are Vodafone and Orange. Other companies showing some interest are Motorola, Alcatel-Lucent, InterDigital, LG and NEC, as well as Chinese companies (CATT, ZTE, TDTech) for TD-SCDMA evolution.

The key features of each release of WCDMA/HSPA can be summarised as follows:

• Introduction of the WCDMA air interface, fulfilling IMT2000 requirements for a 3rd Generation system.

Release 99:

• FDD and TDD modes provided, within a 5MHz carrier bandwidth.

• Narrowband TDD mode added, otherwise known as TD-SCDMA

Release 4:

• High-Speed Downlink Packet Access (HSDPA)

Release 5:

• High-Speed Uplink Packet Access (HSUPA)

Release 6:

• Fractional Dedicated Channel (F-DPCH)

• Multimedia Broadcast / Multicast Service (MBMS)

• Enhanced Layer 2 support for high data rates

Release 7:

• MIMO for HSDPA



• Higher-Order Modulation (64QAM downlink, 16QAM uplink)

• Continuous Packet Connectivity (CPC)

• HSDPA in Cell_FACH and Cell_PCH state

• Enhanced F-DPCH

• Dual-carrier HSDPA

Release 8:

• Simultaneous MIMO and 64 QAM in downlink

• HSUPA in Cell_FACH and Idle Mode

• HSDPA Serving Cell Change Enhancement

• Measurements for handover to LTE

• Downlink Optimised Broadcast (DOB)

• Dual-band HSDPA

Release 9:

• Dual-carrier HSDPA in conjunction with MIMO

• Dual-carrier HSUPA

2.1.1. References

For further information on WCDMA / HSPA, the reader is referred to the 25.xxx series of specifications available from www.3gpp.org, and to the following books:

3G Evolution: HSPA and LTE for Mobile Broadband, E Dahlman et al, Academic Press, 2008 (2nd edition)

WCDMA for UMTS, H Holma & AToskala, Wiley 2007 (4th edition)

http://www.3gpp.org/�



2.2. LTE

LTE is a non-backward-compatible revolution, covering both the air interface and the radio access network architecture. It is accompanied by a major development of the non-radio aspects, including the core network, under the term “System Architecture Evolution” (SAE). Together, LTE and SAE comprise the Evolved Packet System (EPS), in which both the core network and the radio access are fully packet-switched.

LTE is not “4G”, but it paves the way towards 4G. The peak data rate targets for LTE are 100Mbps downlink / 50Mbps uplink, with 2 to 4 times the spectral efficiency (bps/Hz) of UMTS Rel-6. Substantial effort has also been devoted towards providing uniform service provision and improved cell-edge performance, which are key goals for network operators to differentiate their service provision from hot-spot technologies like WiFi and WiMAX. Reduced end-to-end latency has also been a priority in the development of LTE, in order to support new applications like multi-user interactive gaming.

LTE also features flexible use of spectrum allocations, with fully scalable bandwidth up to 20MHz (e.g. supporting deployment in 1.4MHz, 3MHz, 5MHz, 10MHz, 15MHz or 20MHz carrier bandwidths). All terminals are required to support at least 20MHz bandwidth (receive and transmit). Early deployments are likely to be around 2.6GHz (Europe) and 700MHz (USA), as well as in due course reusing existing UMTS and GSM spectrum (beginning with 900MHz in Europe).

Strong pressure was exerted for a common design for LTE for operation in paired and unpaired spectrum, and although the FDD and TDD structures are separate, the differences between them are small and almost entirely confined to the physical layer. A common platform to implement both modes makes sense in LTE.

In the air interface, LTE makes use of some key new technology components:

2.2.1. Multicarrier technology

LTE moves away from the CDMA air interface of WCDMA. Orthogonal Frequency-Division Multiple Access (OFDMA) was selected for the LTE downlink, while a related scheme, known as Single-Carrier Frequency-Division Multiple Access (SC-FDMA) was chosen for the uplink.

OFDM subdivides the bandwidth available for signal transmission into a multitude of narrowband subcarriers, arranged to be mutually orthogonal, which either individually or in groups can carry independent information streams; in OFDMA, this subdivision of the available bandwidth is exploited by sharing the subcarriers between multiple users.

This resulting flexibility can be used in various ways:

• Different spectrum bandwidths can be utilized without changing the fundamental system parameters or equipment design;

• Transmission resources of variable bandwidth can be allocated to different users and scheduled freely in the frequency domain;



• Fractional frequency re-use and interference coordination between cells are facilitated.

OFDM is robust against time-dispersive radio channels, thanks to the subdivision of the wideband transmitted signal into multiple narrowband subcarriers, enabling inter-symbol interference to be largely constrained within a guard interval at the beginning of each symbol. Low-complexity receivers can be designed for the mobile terminal, by exploiting frequency-domain equalization.

By contrast, the transmitter design for OFDM is relatively costly, as the Peak-to-Average Power Ratio (PAPR) of an OFDM signal is high, resulting in a need for a highly-linear RF power amplifier. However, this limitation is not inconsistent with the use of OFDM for the downlink, as low-cost implementation has a lower priority for the base station than for the mobile terminal.

In the uplink, however, the high PAPR of OFDM is difficult to tolerate for the transmitter of the mobile terminal, since it is necessary to compromise between the output power required for good outdoor coverage, the power consumption, and the cost of the power amplifier. SC-FDMA provides a multiple access technology which has much in common with OFDMA—in particular the flexibility in the frequency domain and the incorporation of a guard interval at the start of each transmitted symbol to facilitate low-complexity frequency-domain equalization at the receiver. At the same time, SC-FDMA has a significantly lower PAPR. It therefore enables the uplink to benefit from the advantages of multicarrier technology while avoiding excessive cost for the mobile terminal transmitter and retaining a reasonable degree of commonality between uplink and downlink technologies.

2.2.2. Multiple antenna technology

The use of multiple antenna technology allows the the spatial domain to be exploited, giving another degree of freedom and the potential for additional capacity. This becomes essential in the quest for higher spectral efficiencies. The use of multiple antennas leads to the theoretically-achievable spectral efficiency being scaled linearly with the minimum of the number of transmit and receive antennas employed, at least in suitable radio propagation environments.

Multiple antennas can be used in a variety of ways, mainly based on three fundamental principles:

• Diversity gain: Use of the space-diversity provided by the multiple antennas to improve the robustness of the transmission against multipath fading.

• Array gain: Concentration of energy in one or more given directions via precoding or beamforming.

• Spatial multiplexing gain: Transmission of multiple signal streams to a single user on multiple spatial layers created by combinations of the available antennas.



The LTE system includes several complementary multiple-antenna options which allow for adaptability according to the deployment and the propagation conditions of the different users.

2.2.3. Packet-Switched Radio Interface

LTE is designed as a completely packet-oriented multiservice system, without the reliance on circuit-switched connection-oriented protocols prevalent in GSM and the first releases of WCDMA. In LTE, this philosophy is applied across all the layers of the protocol stack.

LTE therefore uses a transmission time interval (TTI) of just 1ms, allowing very low latency to be achieved.

2.2.4. Flat Network Architecture

LTE moves away from the hierarchical radio access network architecture of WCDMA (with separate base stations (NodeBs) and radio network controllers (RNCs)) to a flat network of interconnected base stations controlling the entire radio resource management (RRM) functionality, known as eNodeBs.

2.2.5. References

For further information on LTE, the reader is referred to the 36.xxx series of specifications available from www.3gpp.org, and to the following books:

LTE – The UMTS Long Term Evolution:

From Theory to Practice

Edited by:

Stefania Sesia, Issam Toufik, Matthew Baker

Hardback, 648 pages

Wiley, February 2009

ISBN: 978-0-470-69716-0

Available from www.wiley.com .

“Where this book is exceptional is that the reader will not just learn how LTE works but why it works”

from Foreword by Adrian Scrase, ETSI Vice-President, International Partnership Projects.


http://www.wiley.com/�



LTE – The UMTS Long Term Evolution:

A Pocket Dictionary of Acronyms

Stefania Sesia, Issam Toufik, Matthew Baker

96 pages

Wiley, April 2009

Available to download from www.wiley.com.

2.3. Beyond LTE

The first release of LTE provides a stepping stone towards a full “4G” system complying with the ITU requirements for “IMT-Advanced” systems.

The further development of LTE will proceed first with Release 9, consisting of a set of relatively minor enhancements, without exceeding the 20MHz carrier bandwidth. Release 9 is likely to be comprised predominantly of features initially considered for Release 8, but not prioritised and therefore not finally included in Release 8. Examples are MBMS Single Frequency Network operation, and multi-layer beamforming.

Release 10 will be a much more major enhancement of LTE, known as LTE-Advanced, or simply LTE-A. LTE-A will extend the capabilities of LTE to exceed the IMT-Advanced requirements. This targets peak data rates of 1Gbps downlink / 500Mbps uplink for low mobility scenarios.

Likely features of LTE-A include:

• Spectrum aggregation, enabling up to 100MHz to be used in a single link (either contiguous or non-contiguous, but in any case comprised of separate 20MHz carriers).

• Downlink MIMO extensions to 8x8 antenna configurations.

• Uplink MIMO with up to 4x4 antenna configurations.

• Co-operative MIMO transmissions from multiple cells.

http://www.wiley.com/�



• Uplink multiple access scheme enhancement to allow the use of non-contiguous blocks of subcarriers (so-called “Clustered DFT-S-OFDM”).

• Use of Relay Nodes to extend coverage (with the Relay Nodes probably appearing like normal base stations but with an in-band LTE interface to one or more neighbouring base stations).



3. Contributions to 3GPP The main topics on which the project contributed to 3GPP during the course of 2007 and 2008 are listed below. A full list of the technical documents submitted is given in Annex A, and a list of the standardisation meetings attended in Annex B.

3.1. RAN WG1 (physical layer)

3.1.1. HSPA

CQI feedback coding and signalling

Control signalling to support MIMO

Control signalling design to support higher-order modulation

Continuous Packet Connectivity (CPC)

Interaction between CPC and Compressed Mode

Enhanced F-DPCH

HSUPA operation in Cell_FACH state

RACH procedure for HSUPA in Cell_FACH

Requirements for number of monitored spreading codes

HSDPA Serving Cell Change Enhancements

Dual-Cell HSDPA Operation on Adjacent Carriers

3.1.2. LTE

Distributed Transmissions in LTE downlink

MU-MIMO

Dedicated Reference Signals

Downlink beamforming

CQI feedback signalling

Precoding for MIMO

Resource block allocation

Control signalling for dynamically- and persistently-scheduled transmissions

Uplink power control



Control signalling message formats

Blind decoding of control signalling

Procedure for HARQ ACK/NACK signalling

MBMS Counting

Discontinuous reception for power saving

UE Capabilities

Downlink power setting

Effect of false positive CRCs

Signalling of antenna configurations in neighbour cells

3.1.3. LTE-A

Requirements for LTE-Advanced

Key Physical Layer Technologies to address the LTE-Advanced Requirements

Interference Management

MU-MIMO

Backward-Compatibility

Multi-cell co-operative beamforming

Scheduler design and associated signalling requirements

3.2. RAN WG2 (protocols)

3.2.1. HSPA

MAC header design

HARQ process handling for MIMO

Discontinuous transmission and reception

RRC signalling

Continuous Packet Connectivity (CPC)

HSDPA Serving Cell Change

UE Capabilities



3.2.2. LTE

Random Access preamble design and data-carrying capacity

Feedback of Channel Quality

MAC header structure

HARQ/ARQ Interactions

Scheduling and discontinuous reception

Feedback for MBSFN

Signalling to support MBSFN operation – structure and design of control channels.

Multiplexing of MBSFN and non-MBMS data

Use of RACH for MBMS Counting

Broadcast information signalling

Triggering of scheduling requests

Buffer status reporting

UL coverage enhancement for VoIP transmission

RLC multiplexing and segmentation

RLC PDU construction

Effect of false positive CRCs

Resource allocation signalling for persistent scheduling



4. Knowledge Transfer to NXP The project has supported the NXP development teams and roadmap/strategy activities by means of detailed meeting reports after each 3GPP meeting, regular consultancy activities, and many tutorials.

The meetings attended (for which corresponding reports were provided) are listed in Annex B.

The following tutorials were provided:

Mar 2007 Le Mans HSDPA, Release 6

May 2007 Nuremberg HSPA Rel-7, LTE

Sep 2007 Dresden LTE

Nov 2007 Dresden LTE

Dec 2007 Redhill WCDMA Rel-99, HSDPA, Rel-6, Rel-7

Feb 2008 Sophia Antipolis HSUPA, LTE

Apr 2008 Eindhoven LTE-Advanced

Apr 2008 Le Mans HSDPA, HSUPA

May 2008 Dresden LTE

Jun 2008 Le Mans HSPA Rel-7, OFDM, LTE

Sep 2008 Le Mans HSDPA, Rel-6, Rel-7

Nov 2008 Nuremberg LTE

Nov 2008 Dresden LTE

Nov 2008 Sophia Antipolis HSPA Rel-7, Rel-8, LTE



5. Conclusions and Future Outlook The project “Tracking and Analysis of 3GPP Standards” has made significant contributions to the standardisation activities in 3GPP during 2007 and 2008, as well as to supporting development and strategy activities in NXP and ST-NXP.

During this period, Releases 7 and 8 of the WCDMA High-Speed Packet Access Specifications were completed, including MIMO technology for the first time in a cellular system. In parallel, the first version of the groundbreaking LTE specifications was completed, paving the way towards the 4th Generation. This work is set to continue as studies progress into LTE-Advanced.

3GPP is now by far the world’s largest standardisation activity for wireless communications. Earlier rivalry from 3GPP2 and the Qualcomm-inspired CDMA2000 family of standards has faded, confirming the 3GPP-developed systems as the global standard for the future. Moreover, recent months have seen numerous major operators and vendors (including Ericsson, Nokia and Alcatel-Lucent) committing to LTE technology rather than the IEEE’s WiMAX. This will help to assure economies of scale and global interoperability in the decades to come.



A Documents submitted to 3GPP The following documents were submitted to 3GPP during 2007 and 2008. All documents are available from www.3gpp.org.

A.1 RAN WG1 Tdoc Number

Source Companies Title

R1-070344 Philips Resource-Block mapping of Distributed Trans-missions in E-UTRA downlink

R1-070346 Philips Comparison of MU-MIMO feedback schemes with multiple UE receive antennas

R1-070347 Philips Receiver phase reference for support of MU-MIMO

R1-070348 Philips Control of CQI feedback signalling in E-UTRA R1-070349 Philips Block codes for CQI reporting for Rel-7 MIMO R1-070350 Philips HS-SCCH for MIMO and 64QAM R1-070351 Philips HARQ process handling for Rel-7 FDD MIMO R1-070352 Philips Continuous Packet Connectivity in conjunction

with Compressed Mode R1-070353 Philips Text proposal for Continuous Packet Connec-

tivity Clarifications R1-070354 Philips Pilot power setting for 16QAM in uplink R1-070537 Philips HS-SCCH for MIMO and 64QAM R1-070557 Philips CR25.212-0242r6 Proposal for block code for

CQI/PCI reporting for Rel-7 MIMO R1-070570 Philips, Ericsson, Motorola, Nokia,

Qualcomm Way forward for HS-SCCH part 1 structure for MIMO and 64QAM

R1-070571 Qualcomm, Philips, Nokia, Ericsson CR25.214-430r4 Definition of MIMO operation on HS-PDSCH, preferred precoding and CQI reporting procedures, modified CQI tables

R1-070580 Philips, Ericsson, Nokia, Qual-comm, Siemens

CR25.214-0421r9 Support of CPC feature

R1-070582 Ericsson, Qualcomm, Motorola, Philips

CR25.201-026r1 DRAFT Introduction of 64QAM for HSDPA










CR25.201-027r1 DRAFT Introduction of 16QAM for HSUPA












R1-070615 Philips, Ericsson, Nokia, Qualcomm Summary of Conclusions on interaction of CPC and Compressed Mode

R1-071018 Nokia, Siemens, Philips CPC CR25.214-0421r11 Support of CPC feature R1-071069 Alcatel-Lucent, Philips Dedicated Reference Signals for MU-MIMO

Precoding in E-UTRA Downlink R1-071090 Philips CR25.214-0433r2 Specification of Enhanced F-

DPCH for downlink code saving R1-071091 Philips Resource-Block mapping of Distributed Trans-

missions in E-UTRA downlink R1-071092 Philips Specifications required for support of precoding

feedback for SU- and MU-MIMO R1-071093 Philips Control of CQI feedback signalling in E-UTRA R1-071094 Philips 25.212 CR0241r3 (Rel-7, B) Coding of HS-

SCCH to support FDD MIMO R1-071095 Philips Evaluation of block codes for CQI reporting for

Rel-7 MIMO R1-071096 Philips CR25.212-0242r7 (Rel-7, B) Coding of HS-

DPCCH to support operation of FDD MIMO R1-071097 Philips, Ericsson, Nokia, Qual-

comm, Siemens CR25.211-230r2 (Rel-7, B) Support of CPC feature

R1-071098 Philips CR25.212-0245r3 (Rel-7, B) Introduction of 64QAM for HSDPA

R1-071126 Philips Evaluation of block codes for CQI reporting for Rel-7 MIMO

R1-071143 Philips, Qualcomm CR25.214-0433r3 Specification of Enhanced F-DPCH for downlink code saving

R1-071147 Ericsson, Philips Transmit diversity operation in MIMO mode R1-071160 Philips, Qualcomm, Motorola,

Ericsson, Nokia, Renesas 25.212 CR0245r4 (Rel-7, B) “Introduction of 64QAM for HSDPA”

R1-071161 Qualcomm, Philips CR25.214-0430r6 “Definition of MIMO operation on Hs-PDSCH, preferred precoding and CQI reporting procedures, modified CQI tables”

R1-071165 Philips, Ericsson, Qualcomm, Nokia, Siemens, Motorola

25.212CR0241r4 “Coding of HS-SCCH to sup-port FDD MIMO”

R1-071172 Nokia, Philips, Ericsson, Renesas, Siemens, Alcatel-Lucent, Qual-comm

25.214CR0421r12 “Support of CPC feature”

R1-071173 Ericsson, Philips, Nokia, Renesas, Siemens, Motorola, Qualcomm

25.212CR0238r5 “Support of CPC feature”

R1-071183 Qualcomm, Ericsson, Motorola, Philips, Alcatel-Lucent, Samsung

25.212CR0246r3 “Introduction of 16QAM for HSUPA”


25.213CR0086r3 – “Introduction of 16QAM for HSUPA”


25.214CR0435r3 – “Introduction of 16QAM for HSUPA”

R1-071194 Ericsson, Samsung, Philips, LGE, Qualcomm, Huawei, ITRI, ASUS TEK, CHTTL, ZTE

Way forward on precoding codebook for 2 TX SU-MIMO

R1-071229 Qualcomm, Philips, Ericsson, Nokia 25.214 CR0430r10 (Rel-7, B) "Definition of MIMO operation on HS-PDSCH, preferred precoding and CQI reporting procedures, modi-fied CQI tables"


25.213 CR0086r4 (Rel-7, B) "Introduction of 16QAM for HSUPA"



R1-071375 Ericsson, Philips MIMO HS-SCCH rate matching R1-071377 Ericsson, Philips CQI and ACK/NACK power setting for MIMO R1-071378 Ericsson, Philips Setting of the uplink HS-DPCCH power relative

to DPCCH power for MIMO R1-071379 Ericsson, Philips Definition of abbreviation "MIMO" R1-071385 Nokia, Alcatel-Lucent, Ericsson,

Philips, Siemens Correction to coding of HS-SCCH to support FDD MIMO

R1-071398 Philips Distributed Transmissions in E-UTRA Downlink Control Signalling

R1-071399 Philips Resource-Block mapping of Distributed Trans-missions in E-UTRA downlink

R1-071400 Philips Control of CQI feedback signalling in E-UTRA R1-071401 Philips, Alcatel-Lucent Text proposal on working assumptions on MU-

MIMO R1-071402 Philips Specifications required for support of precoding

feedback for SU- and MU-MIMO R1-071403 Philips Performance of LTE DL MU-MIMO with dedi-

cated pilots R1-071680 Nokia, Broadcom, Ericsson, Frees-

cale Semiconductor, Huawei, Motorola, NEC Group, Nortel, NTT DoCoMo, Panasonic, Philips, Qualcomm Europe, Siemens Net-works, Texas Instruments

Way Forward on Spatial CQI Definition for E-UTRA DL SU-MIMO

R1-071718 Alcatel-Lucent, Philips Dedicated reference signals for precoding in E-UTRA downlink

R1-071737 Ericsson, Motorola, Qualcomm, Philips


R1-071738 Ericsson, Motorola, Qualcomm, Philips


R1-071767 Philips, Qualcomm 25214CR0437r1 “Enhanced F-DPCH” R1-071775 Qualcomm, Ericsson, Motorola,

Philips 25.212 CR0246r4 Introduction of 16QAM for HSUPA

R1-071782 Qualcomm, Ericsson, Motorola, Philips

25.212 CR0246r5 Introduction of 16QAM for HSUPA

R1-071783 Qualcomm, Ericsson, Nokia, Mo-torola, Philips, Alcatel-Lucent, Samsung, Huawei

25.214CR0435r5 Introduction of 16QAM for HSUPA

R1-071794 Qualcomm, Ericsson, Motorola, Nokia, Nortel, NEC, TI, Huawei, Siemens, Philips, LGE, Samsung, Panasonic, ETRI, NTT DoCoMo

Way forward for stage 2.5 details of SCH

R1-071824 Philips, Nokia, Qualcomm, Ericsson 25214CR0437r2 “Enhanced F-DPCH” R1-071827 Nokia, Ericsson, Huawei, Philips Uplink power control in SHO with CPC feature R1-071829 Nokia, Ericsson, Motorola, Philips,

Qualcomm, Siemens 25214CR0438r1 “Clarifications for CPC feature”

R1-071831 Nokia, Ericsson, Motorola, Philips, Qualcomm, Siemens

25214CR0438r1 “Clarifications for CPC feature”

R1-072042 Qualcomm, Philips, Nokia, Ericsson 25214CR0438r3 Clarifications for CPC feature R1-072064 Mitsubishi Electric, Philips Resource block mapping for EUTRA downlink

distributed transmissions R1-072076 Panasonic, Mitsubishi Electric,

Philips, NTT DoCoMo Proposed way forward for CQI Feedback Control and Content in E-UTRA

R1-072387 Philips, Ericsson 25.212CR248r1 “Correction to coding of HS-SCCH to support FDD MIMO”



R1-072388 Philips 25.214CR447 CQI reporting when MIMO and CPC are both configured

R1-072389 Philips, NXP Semiconductors Remaining aspect of LCR TDD E-HICH R1-072390 Philips Draft reply to LS on CQI feedback [R1-072005] R1-072391 Philips, NXP Semiconductors Control of CQI feedback signalling in E-UTRA R1-072392 Philips, NXP Semiconductors,

Mitsubishi Electric Principles for mapping Virtual Resource Blocks to Physical Resource Blocks in E-UTRA Downlink

R1-072393 Philips Further discussion of Resource Block Mapping for E-UTRA Downlink

R1-072394 Philips Definition of PMI / CQI feedback calculation for MU-MIMO

R1-072395 Philips Suitable size of precoding codebook at eNodeB for MU-MIMO

R1-072396 Philips, NXP Semiconductors Text proposal on Working Assumptions for MU-MIMO

R1-072397 Philips Phase Reference for DL Beamforming R1-072548 Philips, Freescale, LG Electronics,

Mitsubishi Electric, Nortel, Pana-sonic, Samsung

Draft reply to LS on CQI feedback [R1-072005]

R1-072553 Philips 25.214CR447 CQI reporting when MIMO and CPC are both configured – simplified proposal

R1-072562 Qualcomm, Philips, Nokia, Nokia Siemens Networks, Ericsson

25214CR0438r6 Clarifications for CPC feature

R1-072609 Alcatel-Lucent, Ericsson, Huawei, Mitsubishi, Motorola, NEC, Nokia, Nortel, NTTDoCoMo, Philips, Samsung, TI, Qualcomm, LG

Distributed DL Transmission Way Forward

R1-072631 Qualcomm, Philips, Nokia, Nokia Siemens Networks, Ericsson, Vodafone

25.214CR451 Enhanced Cell_FACH Procedure

R1-072917 Mitsubishi, Philips Resource block mapping for EUTRA downlink distributed transmissions

R1-073135 Philips, NXP Semiconductors Control signalling for dynamically- and persis-tently-scheduled transmissions in E-UTRA

R1-073136 Philips, NXP Semiconductors CDD operation for SU-MIMO in conjunction with HARQ

R1-073140 Philips, Mitsubishi Electric, NXP Semiconductors

Further details of mapping of VRBs to PRBs in E-UTRA Downlink

R1-073141 Philips, NXP Semiconductors Definition of PMI / CQI feedback calculation for MU-MIMO

R1-073142 Philips, NXP Semiconductors Size of precoding codebook at eNodeB for MU-MIMO

R1-073143 Philips, NXP Semiconductors Text proposal on Working Assumptions for MU-MIMO

R1-073144 Philips, Alcatel-Lucent, NXP Semi-conductors, ArrayComm

Phase Reference for DL Beamforming

R1-073145 Philips, NXP Semiconductors Vector quantisation with successive refinement for MIMO feedback



R1-073209 CATT, Ericsson, Fujitsu, IPWire-less, Mitsubishi Electric, Motorola, NEC, Nokia, Nokia-Siemens, Nortel, NTT DoCoMo, Orange, Panasonic, Philips, Qualcomm, Samsung, Sharp, TI, T-Mobile, Toshiba Corporation, Vodafone, ZTE

Way Forward on Uplink Power Control of PUCCH

R1-073224 CATT, Ericsson, LGE, Motorola, Nokia, Nokia-Siemens, Nortel, NTT DoCoMo, Orange, Panasonic, Philips, Qualcomm, Samsung, Sharp, TI, Vodafone

Way Forward on Power Control of PUSCH

R1-073713 Philips, Ericsson, Nokia, Nokia Siemens Networks, NXP Semicon-ductors

Draft reply to LS on HS-SCCH less + MIMO [R1-073245]

R1-073714 Philips, NXP Semiconductors Draft reply to LS on Physical Layer Aspects of eMBMS Counting [R1-073246]

R1-073715 Philips, NXP Semiconductors Phase reference for downlink beamforming R1-073716 Philips Discussion of PDCCH message formats R1-073717 Philips Proposal for resource allocation signalling on

PDCCH R1-073718 Philips, NXP Semiconductors Vector quantisation with successive refinement

for MIMO feedback R1-073719 Philips, NXP Semiconductors CQI reporting for TDD R1-073720 Philips, NXP Semiconductors Way forward for DVRB to PRB mapping for

EUTRA downlink R1-073721 Philips Codebook for MU-MIMO R1-073722 Philips CQI definition for MU-MIMO R1-073723 Philips Signalling for UL resource allocation R1-073724 Philips, NXP Semiconductors UE procedure for ACK/NACK detection R1-073818 Philips, Nokia Siemens Networks,

Nokia, IPWireless Draft Reply LS on Physical Layer Aspects of eMBMS Counting

R1-073827 Philips LS on maximum transport block size for HS-SCCH-less operation

R1-073832 Ericsson, Philips, Nokia, Nokia Siemens Networks

25214 CR458r1 Correction of 64QAM CQI tables

R1-073838 Ericsson, Philips, Nokia, Nokia Siemens Networks

25214 CR462r1 Correction of MIMO CQI tables

R1-073844 Ericsson, CATT, Freescale Semi-conductor, Huawei, Icera Semicon-ductor, LGE, Motorola, Nokia, Nokia Siemens Networks, Nortel, NTT DoCoMo, Panasonic, Philips, Qualcomm Europe, Samsung, Texas Instruments, ZTE

Way forward for CQI reporting

R1-073866 Nokia, Nokia Siemens Networks, Philips

25214 CR456r3 Correction to Rel-7 E-DPDCH gain factor calculation

R1-073871 Ericsson, Qualcomm, Nokia, Nokia Siemens Networks, Samsung, Motorola, LG Electronics, Nortel, Philips, NXP Semiconductors

Maximum number of hybrid ARQ processes



R1-073886

NTT DoCoMo, Vodafone, Orange, T-Mobile, China Mobile, AT&T, Philips, Ericsson, Qualcomm Europe, NEC, Alcatel-Lucent, Fujitsu, Mitsubishi, Sharp, Array-comm, ITRI, ZTE

Way Forward on DL Beamforming

R1-073887 Ericsson, Motorola, Samsung, NTT DoCoMo, NEC, Huawei, LGE, Philips, Interdigital, Nortel, Qual-comm, Mitsubishi, TI, Alcatel-Lucent, Freescale, Nokia, Nokia-Siemens Networks, ZTE

Proposed way forward on distributed DL trans-mission

R1-074244 Philips, NXP, Ericsson CR25.211-248(Rel-7/F) Correction to transmit diversity specification in MIMO mode

R1-074245 Philips, NTT DoCoMo, Vodafone, AT&T, NEC, Fujitsu, Mitsubishi, NXP, Arraycomm

Way forward for dedicated reference symbols for downlink beamforming

R1-074246 Philips Dedicated reference symbol pattern R1-074247 Philips, NXP Discussion of PDCCH message formats R1-074248 Philips, NXP Proposal for resource allocation signalling on

PDCCH R1-074249 Philips, NXP Signalling for UL resource allocation R1-074250 Philips PDSCH timing for power saving for paging in idle

mode R1-074253 Philips DVRB to PRB mapping for EUTRA downlink R1-074254 Philips, NXP Codebook for MU-MIMO R1-074255 Philips, NXP CQI definition for MU-MIMO R1-074256 Philips, NXP UE procedure for ACK/NACK detection R1-074299 Nokia, Nokia Siemens Networks,

Ericsson, Philips 25212CR (R8, B) HS-SCCH information field mapping for 64QAM MIMO

R1-074362 NXP, Philips Capabilities of the lowest UE category R1-074462 Alcatel-Lucent, Nokia, Nokia Sie-

mens Networks, Ericsson, Philips 25.214 CR467r1 (Rel-7, ) Clarification on CQI tables in Rel-7

R1-074479 NEC, Ericsson, Fujitsu, Marvell Semiconductor, Motorola, Pana-sonic, Philips, Qualcomm, ZTE

Way forward on DL power control

R1-074496 Nokia Siemens Networks, Nokia, Huawei, Texas Instruments, Erics-son, Samsung, Nortel, Qualcomm, NEC, Philips, NTT DoCoMo

Refined proposal on CQI compression

R1-074506 Philips, Ericsson, NTT DoCoMo, China Mobile, CATT, RITT, Voda-fone, AT&T, Orange, TMobile, Qualcomm Europe, Sharp, NEC, Fujitsu, Mitsubishi, NXP Semicon-ductors, Alcatel-Lucent, Array-comm, ITRI

Way Forward for Dedicated RS for DL Beam-forming

R1-074503 Motorola, Nokia, Nokia Siemens Networks, Qualcomm, Philips, Samsung, TI

Resource block mapping for an odd number of resource blocks

R1-074516 NTT DoCoMo, Vodafone, Ericsson, Motorola, Nokia, Panasonic, Phil-ips, Qualcomm Samsung

LS to RAN4 on UE categories

R1-074518 Philips, Nokia Siemens Networks, Nokia, Alcatel-Lucent, Qualcomm

25.211 CR249 (Rel-6, F) Correction to E-DPCCH transmission



R1-074519 Philips, Nokia Siemens Networks, Nokia, Alcatel-Lucent, Qualcomm

25.211 CR250 (Rel-7, A) Correction to E-DPCCH transmission

R1-074551 Ericsson, NXP Semiconductors, Philips, Qualcomm

25.214 CR470 (Rel-7,) Correction to Rel-7 E-DPDCH gain factor calculation

R1-074622 Philips MBSFN remaining issues R1-074623 Philips Open issues on dedicated RS R1-074624 Philips, NXP Dedicated reference symbol pattern R1-074625 Philips Resource Allocation for E-DCH in Cell_FACH R1-074626 Philips Proposal for resource allocation signalling on

PDCCH R1-074627 Philips, NXP Signalling for UL resource allocation R1-074628 Philips, NXP PDSCH timing for power saving for paging in idle

mode R1-074630 Philips, NXP Codebook for MU-MIMO R1-074631 Philips, NXP CQI definition for MU-MIMO R1-074632 Philips, NXP UE procedure for ACK/NACK detection R1-074663 Nokia, Nokia Siemens Networks,

Philips, Ericsson, Qualcomm 25212CR0256 (Rel-8, B) HS-SCCH information field mapping for 64QAM MIMO

R1-074976 Philips Enhanced Uplink for CELL_FACH R1-075020 CMCC, CATT, Vodafone Group,

Verizon Wireless, Orange, AT&T, T-Mobile, NTT DoCoMo, Ericsson, Huawei, Nokia, Nokia Siemens Networks, RITT, ZTE, TD-Tech, Motorola, Qualcomm Europe, Nortel, Samsung, Alcatel Shanghai Bell, Texas Instruments, Philips, CHTTL, Spreadtrum Communica-tions, Mitsubishi Electric, NEC

Way Forward on LTE TDD Frame Structure

R1-075077 Samsung, LGE, Nortel, Qualcomm Europe, Motorola, Huawei, AT&T, Panasonic, ITRI, ETRI, Ericsson, Nokia, Nokia Siemens, SunPlus Mobile, Texas Instruments, Alcatel-Lucent, Philips

Way-forward on Data Power Setting for PDSCH across OFDM Symbols

R1-075079 Ericsson, Philips 25.214 CR471r2 (Rel-7,) Clarification of CQI definition

R1-075082 Ericsson, Nokia, Nokia Siemens Networks, Philips, Qualcomm

25.212CR0259 (Rel-7,F) Correction of number of TBs in a TTI in case of MIMO

R1-075083 Ericsson, Philips, Qualcomm 25.211CR251 (Rel-7,F) Mention PCI as part of HS-DPCCH structure

R1-080207

Texas Instruments, Panasonic, Mitsubishi Electric, Sharp, Philips

CQI Reporting Procedure for E-UTRA

R1-080450 Philips Open issues on UE-specific RS R1-080451 Philips UE-specific RS pattern R1-080452 Philips Resource allocation signalling on PDCCH R1-080453 Philips, NXP Signalling for UL resource allocation R1-080454 Philips, NXP PDSCH timing for power saving for paging in idle

mode R1-080455 Philips Way forward on Distributed DVRB for EUTRA

downlink R1-080456 Philips MBSFN remaining issues R1-080457 Philips, NXP Codebook for MU-MIMO R1-080458 Philips, NXP CQI definition for MU-MIMO



R1-080459 Philips, NXP UE procedure for ACK/NACK detection R1-080460 Philips Distributed Resource Allocation Signalling on

PDCCH R1-080461 Philips Resource Allocation for E-DCH in Cell_FACH R1-080566 Ericsson, Philips, Qualcomm, Nokia

Siemens Networks, Nokia, NEC, LG

Way forward for E-DCH resource allocation in CELL_FACH

R1-080579

AT&T, Alcatel-Lucent, ASUSTec, CMCC, Comsys, Ericsson, ETRI, Freescale, Huawei, I2R, Icera, ITRI, Marvell, Mitsubishi, Motorola, NEC, Nokia, Nokia-Siemens-Networks, Nortel, NTT DoCoMo, Panasonic, Philips, Samsung, Sunplus mMo-bile, Texas Instruments, Vodafone, ZTE

Further details of large delay CDD for E-UTRA

R1-080817 Philips Open issues on UE-specific RS R1-080819 Philips, NXP Configuration of PDCCH blind decoding sets R1-080820 Philips, NXP PDCCH message information content for persis-

tent scheduling R1-080821 Philips, NXP Resource allocation signalling on PDCCH R1-080822 Philips Distributed Resource Allocation Signalling on

PDCCH R1-080823 Philips, NXP PDCCH message information content for UL

resource allocation R1-080824 Philips, NXP PDCCH message for paging R1-080825 Philips Way forward on Distributed DVRB for EUTRA

downlink R1-080826 Philips MBSFN remaining issues R1-080827 Philips, NXP Codebook for MU-MIMO R1-080828 Philips, NXP CQI definition for MU-MIMO R1-080829 Philips, NXP UE procedure for ACK/NACK detection R1-080830 Philips Remaining issues on E-RACH procedure R1-080831 Philips, NXP UL coverage enhancement for VoIP transmis-

sion R1-080835 Qualcomm, Ericsson, Huawei,

Motorola, NEC, Nokia, Nokia Sie-mens Networks, Philips, NXP

25.211CR-xxx Introduction of E-AICH for the purpose of E-DCH Resource Configuration Allocation

R1-081047 Nokia, Nokia Siemens Networks, Broadcom, Freescale, Huawei, LG Electronics, NXP Semiconductors, Samsung, Texas Intruments, ZTE

Way Forward on Orthogonal Sequences for DL Reference signals

R1-081108 Motorola, Nortel, Broadcomm, Nokia, NSN, NTT DoCoMo, NEC, Mitsubishi, Alcatel-Lucent, CATT, Huawei, Sharp, Texas Instrument, ZTE, Panasonic, Philips, Toshiba

Way Forward on Dedicated Reference Signal Design for LTE downlink with Normal CP

R1-081111 Texas Instruments, Ericsson, Nortel, Philips, LG Electronics, Nokia Siemens Networks, Nokia, Samsung, Huawei, Mitsubishi Electric, NEC, Sharp

Further Refinements on CQI Reporting on PUSCH

R1-081116

Samsung, Texas Instruments, Ericsson, Nortel, Motorola, Pana-sonic, Philips, NTT DoCoMo

Further Refinements on Rank Reporting



R1-081135 Alcatel-Lucent, CATT, CMCC, Ericsson, Huawei, LGE, Motorola, Philips, Qualcomm Europe, Pana-sonic, Samsung, TD-Tech, T-mobile, Vodafone Group, Nortel, Nokia, Nokia Siemens Networks, ZTE

Way Forward on DwPTS design for LTE TDD

R1-081503 Philips Remaining issues on UE-specific RS R1-081504 Philips Analysis of search space design for PDCCH

blind decoding R1-081506 Philips, NXP PDCCH message information content for persis-

tent scheduling R1-081507 Philips, NXP Distributed Resource Allocation Signalling on

PDCCH R1-081508 Philips, NXP Index for PDCCH signalling of UL resource

allocation in conjunction with DRX R1-081509 Philips, NXP PDCCH message for paging R1-081510 Philips, NXP Codebook for MU-MIMO R1-081511 Philips, NXP CQI definition for MU-MIMO R1-081512 Philips, NXP UE procedure for ACK/NACK detection R1-081513 Philips RACH procedure for E-DCH in Cell_FACH R1-081584 Philips, Motorola, NXP, Panasonic,

Qualcomm 36213CR0008 – UE ACK/NACK Procedure

R1-081669 Nortel, Alcatel-Lucent, Philips, Vodafone, Verizon, Orange, T-Mobile

Draft response to LS on implications of MIMO schemes on RAN4 requirements

R1-081896

Nokia Siemens Networks, Ericsson, Motorola, NEC, Nokia, NXP, Philips, Qualcomm, Samsung

25211CRdraft, Introduction of the Enhanced Uplink for CELL_FACH state

R1-081897 Nokia Siemens Networks, Nokia, Ericsson, InterDigital, Samsung, Qualcomm, Philips, NXP

25214CRdraft, Introduction of the Enhanced Uplink for CELL_FACH state

R1-082036

Philips, NXP Comments on LTE-Advanced Requirements

R1-082037

Philips, NXP Key Physical Layer Technologies to address the LTE-Advanced Requirements

R1-082039

Philips, NXP PDCCH message information content for persis-tent scheduling

R1-082041

Philips, NXP Index for PDCCH signalling of UL resource allocation in conjunction with DRX

R1-082042

Philips, NXP 36.211CR0020 Correction of DL/UL Allocation for TDD

R1-082043

Philips, NXP Remaining issues on UE-specific RS

R1-082044

Philips, NXP Codebook for MU-MIMO

R1-082045

Philips, NXP CQI definition for MU-MIMO

R1-082046 Philips, NXP RACH procedure for E-DCH in Cell_FACH R1-082120 Nokia Siemens Networks, Ericsson,

Motorola, NEC, Nokia, NXP, Philips, Qualcomm, Samsung

25211CR0256, Introduction of the Enhanced Uplink for CELL_FACH state

R1-082121 Nokia Siemens Networks, Nokia, Ericsson, InterDigital, Samsung, Qualcomm, Philips, NXP

25214CR0490, Introduction of the Enhanced Uplink for CELL_FACH state



R1-082146 CATT, Ericsson, Nokia, Nokia Siemens Networks, CMCC, Philips, NXP, Samsung

Correction of the description of frame structure type 2

R1-082150 Philips, Ericsson, NXP Common RS configurations in conjunction with UE-specific RS

R1-082157 Huawei, Samsung, Philips 36.211 CR0024 (Rel-8, F) Consideration on the scrambling of PDSCH

R1-082192 Philips, NXP, Alcatel-Lucent, CATT, CMCC, Ericsson, Nokia, Nokia Siemens Networks, Nortel, Qual-comm, Samsung, Vodafone

36.211CR0031 Use of common RS when UE-specific RS are configured

R1-082205 Qualcomm, Philips, NXP 36.212 CR0013 (Rel-8, F) Payload size for DCI formats 3 and 3A

R1-082210 Nokia Siemens Networks, Ericsson, Motorola, NEC, Nokia, NXP, Philips, Qualcomm, Samsung

25211CR0256r1, Introduction of the Enhanced Uplink for CELL_FACH state

R1-082524 Philips, NXP Corrections to TS36.211 R1-082525 Philips, NXP Corrections to TS36.212 R1-082526 Philips, NXP Index for PDCCH signalling of UL resource

allocation in conjunction with DRX R1-082527 Philips, NXP PDCCH message information content for persis-

tent scheduling R1-082528 Philips CQI reference measurement period R1-082529 Philips Configuration of CQI modes R1-082530 Philips CQI for UE-specific RS R1-082531 Philips, NXP CQI definition for MU-MIMO R1-082532 Philips, NXP Control channel support for HSDPA Dual-Cell

operation R1-082533 Philips, NXP Discussion of Technologies for LTE-Advanced R1-082612

NEC Group, LGE, Ericsson, Nokia, Nokia Siemens Networks, Alcatel-Lucent, Nortel, Texas Instruments, Motorola, Samsung, Broadcom, Philips

Padding one bit to DCI format 1 when fomat 1 and fomat 0/1A have the same size

R1-082652 LGE, Motorola, Philips, Qualcomm Correction to the formula for uplink PUSCH power control

R1-082706 Qualcomm, Samsung, Panasonic, Philips, NXP, Alcatel-Lucent, Inter-Digital, Motorola

Response to Semi-Persistent Scheduling Activa-tion with Single PDCCH

R1-082724

LG, NEC, Qualcomm, Philips, Samsung, Ericsson, Nokia, Nokia Siemens Networks

Further clarifications on confirmation field in DCI format 2

R1-082726 Philips, Ericsson, NXP CQI reference measurement period R1-082727 Philips, NXP CQI for UE-specific RS R1-082728 Philips, NXP CQI definition for MU-MIMO R1-082792 Philips Effect of false positive UL grants R1-082793 Philips, NXP Corrections to TS36.211: specification of re-

served REs not used for RS R1-082794

Philips, NXP CR36.211-0033r1 Corrections to DCI formats

R1-082795

Philips, NXP CQI reference measurement period

R1-082796

Philips Configuration of CQI modes

R1-082797

Philips CQI corrections



R1-082798

Philips, NXP CQI definition for MU-MIMO

R1-082799

Philips, NXP Correction to precoding description

R1-082800

Philips, NXP Reception of DCI formats

R1-082801

Philips, NXP Analysis of HS-SCCH code monitoring require-ments for Dual-Cell HSDPA

R1-082802

Philips, NXP HS-SCCH code monitoring requirements for Dual-Cell HSDPA

R1-082803

Philips, NXP MU-MIMO for LTE-Advanced

R1-082804 Philips, NXP Interference Management for LTE-Advanced R1-082933 LGE, Philips, Samsung Correction to the uplink power control R1-082983

Panasonic, NEC, Philips Correction of subscripts in TS 36.213 section 7.2.2

R1-083244 NXP, Philips Feedback and Precoding Techniques for MU-MIMO for LTE-A

R1-083275 Ericsson, NXP, Philips, Qualcomm Europe, Samsung

25.214 CR0498R2 (Rel-8, B) Introduction of HS-PDSCH Serving Cell Change Enhancements

R1-083283 LGE, Samsung, Philips 36.213 CR0069 (Rel-8, F) Correction to the uplink power control

R1-083330 Ericsson, NXP, Philips, Qualcomm Europe, Samsung

25.214 CR0498R3 (Rel-8, B) Introduction of HS-PDSCH Serving Cell Change Enhancements

R1-083331 Philips, NXP 36.212 CR0033R2 (Rel-8, F) Corrections to DCI formats

R1-083389 Philips 36.213 CR0082 (Rel-8, F) CQI corrections R1-083390 Philips, NXP 36.213 CR0083 (Rel-8, F) Corrections to precod-

ing for large delay CDD R1-083395 Ericsson, Huawei, Nokia, Nokia

Siemens Networks, Philips, Qual-comm Europe, Samsung

25.211 CR0257r1 (Rel-8,B) “Introduction of Dual-Cell HSDPA Operation on Adjacent Carri-ers”

R1-083396 Ericsson, Huawei, Nokia, Nokia Siemens Networks, Philips, Qual-comm Europe, Samsung

25.212 CR0267r1 (Rel-8, B) “Introduction of Dual-Cell HSDPA Operation on Adjacent Carri-ers”





R1-083399 Ericsson, Huawei, Nokia, Nokia Siemens Networks, Philips, Qual-comm Europe


R1-083408 Philips, NXP, Ericsson, Motorola, Nokia, Nokia Siemens Networks, Qualcomm

36.213 CR0084 (Rel-8, F) CQI reference meas-urement period

R1-083438 Philips, NXP, Ericsson, Motorola, Nokia, Nokia Siemens Networks, Qualcomm

36.213 CR0084R1 (Rel-8, F) CQI reference measurement period

R1-083501 Philips, NXP Response to LS on scope and reference for parameter “sameRefSignalsInNeighbour” (R1-083474)

R1-083502 Philips, NXP 36211 CR0081 (Rel-8, F) Specification of re-served REs not used for RS



R1-083503 Philips 36213 CR0101 (Rel-8, F) Configuration of CQI modes

R1-083504 Philips, NXP 36213 CR0102 (Rel-8, F) Reception of DCI formats

R1-083505 Philips 36212 CR0049 (Rel-8, F) Corrections to DCI formats

R1-083506 Philips 36.213 CR0082r1 (Rel-8, F) CQI corrections R1-083507 Philips, NXP 36.213 CR0083r1 (Rel-8, F) Moving description

of large delay CDD R1-083508 Philips, NXP, Qualcomm 25.214 CR0503 (Rel-8, F) Correction to timing of

HSDPA enhanced cell change R1-083510 Philips, NXP MU-MIMO for LTE-Advanced R1-083511 Philips, NXP Interference Management for LTE-Advanced R1-083554 Philips, NXP LTE Advanced Backwards-Compatibility R1-083665

Panasonic, Philips Further correction and clarification of CQI defini-tion in TS 36.213

R1-083774 NXP, Philips Feedback and Precoding Techniques for MU-MIMO for LTE-A

R1-083775 NXP, Philips Unitary Beamforming for MU-MIMO With Per Transmit Antenna Power Constraint for LTE-A

R1-083901 NXP, Philips Physical limits of SU-MIMO configurations for LTE-A

R1-083885 Philips, NXP 36.211 CR0072r1 (Rel8, F) Corrections to precoding for large delay CDD

R1-083904 Philips, NXP, Qualcomm DRAFT Response to LS on scope and reference for parameter “sameRefSignalsInNeighbour”

R1-083933 Philips 36211 CR0081r1 (Rel-8, F) Specification of reserved REs not used for RS

R1-083983 Philips, NXP, Qualcomm, Ericsson 25.214 CR0503 (Rel-8, F) Correction to timing of HSDPA enhanced cell change

R1-084000 Philips, NXP 36.211 CR0072r2 (Rel8, F) Corrections to precoding for large delay CDD

R1-084029 Ericsson, Huawei, Nokia, Nokia Siemens Networks, Philips, Qual-comm Europe, Samsung, NEC

25.211CR0257r3 Introduction of Dual-Cell HSDPA Operation on Adjacent Carriers


25.212 CR0267r3 Introduction of Dual-Cell HSDPA Operation on Adjacent Carriers


25.214 CR0497r4 Introduction of Dual-Cell HSDPA Operation on Adjacent Carriers

R1-084039 Panasonic, Ericsson, Philips CQI/PMI reference measurement periods R1-084093 Philips, NXP Semiconductors, ST

Microelectronics, Qualcomm DRAFT Response to LS on scope and reference for parameter “sameRefSignalsInNeighbour”

R1-084094 Philips, NXP Semiconductors, ST Microelectronics

36.213 CR0102R1 (Rel-8, F) Reception of DCI formats

R1-084095 Philips, NXP Semiconductors, ST Microelectronics, NTT DoCoMo, Texas Instruments

36.213 CR0082R2 (Rel-8, F) Corrections to RI for CQI reporting


36.213 CR0083R2 (Rel-8, F) Moving description of large delay CDD


Scheduler for LTE-Advanced Evaluation and TP for TR36.814


MU-MIMO for LTE-Advanced




Interference Management for LTE-Advanced

R1-084100 Philips Multi-cell co-operative beamforming: Operation and performance, and TP for TR36.814

R1-084440 Texas Instruments, NTT DoCoMo, Philips

Inconsistency between PMI definition and code-book index

R1-084491 STMicroelectronics, Philips Feedback and precoding techniques for MU-MIMO for LTE-A

R1-084492 STMicroelectronics Unitary beamforming for MU-MIMO with per antenna power constraint for LTE-A

R1-084493 STMicroelectronics Physical limits of SU-MIMO configurations for LTE-A

R1-084494 STMicroelectronics Precoding with User Scheduling in MU-MIMO for LTE-A

R1-084495 STMicroelectronics Reliability of the channel knowledge at the eNodeB for MU-MIMO systems

R1-084496 STMicroelectronics Advantages and Limitations of Cooperative MIMO for LTE-A

R1-084527 Philips, ST Microelectronics, NXP Semiconductors

Multi-cell co-operative beamforming: Operation and performance, and TP for TR36.814

R1-084548 Motorola, TI, Ericsson, Philips, Samsung

Draft CR 36.213 Transition between DCI formats 2(A) and 1A

R1-084563 Ericsson, Nokia, Nokia Siemens Networks, Philips, Qualcomm Europe

25.214 CR0518R1 (Rel-7, F) Clarification of CQI repetition in case of UE DTX

R1-084564 Ericsson, Nokia, Nokia Siemens Networks, Philips, Qualcomm Europe

25.214 CR0524 (Rel-8, A) Clarification of CQI repetition in case of UE DTX

R1-084568 Ericsson, Philips, NXP, Samsung, NEC, Motorola, TI, LGE

36.212 CR0068 (Rel-8, F) DCI format 2/2A

R1-084576 Philips, NXP Semiconductors, ST Microelectronics, NTT DoCoMo, Texas Instruments

36.213 CR0082R3 (Rel-8, F) Corrections to RI for CQI reporting

R1-084586 Texas Instruments, NTT DoCoMo, Philips

36.213 CR0163 (Rel-8, F) Inconsistency be-tween PMI definition and codebook index

R1-084598 Panasonic, Alcatel-Lucent, Philips, Huawei, Qualcomm Europe, LGE, …

36.213 CR0164 (Rel-8, F) PDCCH validation for semi-persistent scheduling


Scheduler for LTE-Advanced Evaluation and TP for TR36.814

R1-084651 AT&T, CATT, CMCC, InterDigital, Orange, Philips, Qualcomm Europe, RIM, Telecom Italia, Tele-fonica, T-Mobile, Vodafone

Way forward on addressing forward compatibility in Rel-8

R1-084655 Nokia, Nokia Siemens Networks, Ericsson, Qualcomm, Philips, Samsung

25.213 CR0099 (Rel-8, B) Clarification to scrambling codes in dual cell HSDPA operation

R1-084656 Nokia, Nokia Siemens Networks, Ericsson, Qualcomm, Philips, Samsung

25.214 CR0528 (Rel-8, B) Clarifications to dual cell HSDPA operation

R1-084672 RAN1, Philips Response to LS on scope and reference for parameter “sameRefSignalsInNeighbour”



A.2 RAN WG2 Tdoc Number

Source Title

R2-070086 Panasonic, NTT DoCoMo, Texas Instruments, Philips, Fujitsu and Alcatel-Lucent

Inclusion of cause and CQI in the Random Access Preamble

R2-070164 Philips Quantized CQI for RACH Preamble Message R2-070165 Philips Impact of higher data rates on MAC header R2-070289 Philips HARQ process handling for Rel-7 FDD MIMO R2-070195 Qualcomm, Nokia, Ericsson, Philips Introduction of DTX/DRX and HS-SCCH less in

MAC R2-070196 Qualcomm, Nokia, Ericsson, Philips Introduction of DTX /DRX and HS-SCCH less

in RRC R2-070788 Philips MAC-hs header structure R2-070789 Philips Quantized CQI for RACH Preamble Message R2-071029

Ericsson, Qualcomm, Philips CR: Introduction of MIMO in 25.308

R2-071038 Ericsson, Qualcomm, Philips Introducing MIMO in HSDPA stage 2 specifica-tion 25.308CR0017

R2-071042 Qualcomm, Philips Introduction of MIMO in RRC specification 25.331CR2985

R2-071092 Qualcomm, Philips Introduction of MIMO in RRC specification 25.331CR2985r1

R2-071391 Philips Feedback of Channel Quality R2-071392 Philips MAC-ehs header structure R2-071984 Philips HARQ/ARQ Interactions R2-071884 Ericsson, Philips Restriction on the number of MIMO processes R2-072507 Philips HARQ/ARQ Interactions R2-072504 Philips Operation of E-UTRAN UL Scheduling and

DRX R2-072505 Philips Control of E-UTRAN UL scheduling R2-072767 Philips Common feedback for MBSFN R2-072946 Philips Slot format 4 and CPC R2-073394 Philips, NXP Semiconductors Control of E-UTRAN UL scheduling R2-073396 Philips, NXP Semiconductors Operation of E-UTRAN UL Scheduling and

DRX R2-073446 Philips Use of RACH for eMBMS Counting R2-073028 Alcatel-Lucent, Philips, NXP Semi-

conductors Handling of Slot Format 4 and CPC

R2-073760 Alcatel-Lucent, Philips, NXP Semi-conductors

Handling of Slot Format 4 and CPC

R2-073847 Alcatel-Lucent, Philips, NXP Semi-conductors

Handling of Slot Format 4 and CPC

R2-073193 Ericsson, Philips, NXP Semiconduc-tors

Restriction on the number of MIMO processes

R2-073755 Philips HS-SCCH less virtual IR buffer size R2-073767 Philips HS-SCCH less virtual IR buffer size R2-073832 Philips HS-SCCH less virtual IR buffer size R2-074207 NXP, Philips Update of the BCCH information in E-UTRA R2-074209 NXP, Philips Interactions between downlink HARQ and DRX R2-074355 Philips, NXP Control of E-UTRAN UL scheduling R2-074358 Philips, NXP Operation of E-UTRAN UL Scheduling and

DRX R2-074360 Philips, NXP Use of RACH for eMBMS Counting



R2-074362 Philips, NXP PDSCH timing for Power saving with Paging R2-074363 Philips, NXP Control of HARQ for RACH messages 3 and 4 R2-074364 Philips, NXP MCCH structure and multiplexing R2-074995 Philips, NXP Semiconductors Control of E-UTRAN UL scheduling R2-074996 Philips, NXP Semiconductors Operation of E-UTRAN UL Scheduling and

DRX R2-074997 Philips, NXP Semiconductors Use of RACH for eMBMS Counting R2-074999 Philips, NXP Semiconductors Control of HARQ for RACH messages 3 and 4 R2-075000 Philips, NXP Semiconductors MCCH structure and multiplexing R2-075163 Philips RACH Access for Enhanced Uplink in

Cell_FACH R2-075200 Philips RACH Access for Enhanced Uplink in

Cell_FACH R2-080300 Philips, NXP Semiconductors Operation of E-UTRAN UL Scheduling and

DRX R2-080301 Philips, NXP Semiconductors Control of HARQ for RACH messages 3 and 4 R2-080302 Philips, NXP Semiconductors Multiplexing of MBSFN subframes R2-080307 Philips, NXP Semiconductors Use of RACH for e-MBMS Counting R2-080308

Philips Dynamic Scheduling

R2-080309 Philips RRC signalling for Enhanced CELL_FACH R2-080310 Philips Resource allocation for Enhanced CELL_FACH R2-080359 Philips HS-SCCH code numbering R2-080365 Philips HS-SCCH code numbering R2-081021 Philips, NXP Semiconductors Operation of E-UTRAN UL Scheduling and

DRX R2-081022 Philips, NXP Semiconductors Control of HARQ for RACH messages 3 and 4 R2-081185 Philips UL coverage enhancement for VoIP transmis-

sion R2-081024 Philips RRC signalling for Enhanced CELL_FACH R2-081758 Philips, NXP Semiconductors Operation of E-UTRAN UL Scheduling and

DRX R2-081764 Philips, NXP Semiconductors Control of HARQ for RACH message 3 R2-081766 Philips, NXP Semiconductors Control of HARQ for RACH message 4 R2-081767 Philips, NXP Semiconductors Triggering of Scheduling Request R2-081768 Philips, NXP Semiconductors UL coverage enhancement for VoIP transmis-

sion R2-081769 Philips, Qualcomm Europe RRC signalling for Enhanced CELL_FACH R2-082451 Philips, NXP Semiconductors Operation of E-UTRAN UL Scheduling and

DRX R2-082452 Philips, NXP Semiconductors Control of HARQ for RACH message 3 R2-082453 Philips, NXP Semiconductors Triggering of Scheduling Request R2-082454 Philips, NXP Semiconductors TTI Bundling R2-082456 Philips, NXP Semiconductors RRC signalling for Enhanced CELL_FACH R2-083244 Philips Buffer status field table R2-083245 Philips HS-DSCH Serving Cell Change R2-083420 NXP Semiconductors, Philips Limitations on RLC SDU into MAC SDU multip-

lexing R2-083425 NXP Semiconductors Status PDU processing R2-083445 NXP Semiconductors RLC PDU construction R2-083972 NXP Semiconductors, Philips About RRC connection re-establishment pro-

cedure R2-083977 NXP Semiconductors, Philips About RRC connection reconfiguration proce-



dure R2-083983 NXP Semiconductors, Philips About PDU content of RRC connection re-

establishment message R2-083987 NXP Semiconductors, Philips About Generic error handling R2-084086 Philips, NXP Semiconductors Mitigating effect of false positive for uplink grant R2-084087 Philips, NXP Semiconductors Resource allocation signalling for SPS R2-084088 Philips, NXP Semiconductors Buffer Status Field Table R2-084090 Philips, NXP Semiconductors Improving the Robustness of Buffer Status

Reporting R2-084092 Philips, NXP Semiconductors Signalling of Reference Symbol Configuration

in Neighbour Cells R2-084365 NXP Semiconductors Limitations on RLC Status PDU construction R2-084366 NXP Semiconductors RLC AMD PDU re-segmentation R2-084367 NXP Semiconductors Limitations on PDCP/RLC SDU into MAC TB

multiplexing R2-084718 Philips Mitigating effect of false positive for uplink

grants (updated of R2-084086) R2-085075 Philips, NXP Semiconductors Buffer status field table R2-085077 Philips, NXP Semiconductors Improving the robustness of Buffer Status

Reporting R2-085078 Philips Signalling of SIB7 information to speed up

RACH access R2-085079 Philips UE Capabilities for Dual-Cell HSDPA Operation R2-086560 Philips, NXP Semiconductors, ST

Microelectronics MAC Open Issue HD13: DL HARQ process numbers for MIMO

R2-086561 Philips MAC Open Issue SR03: Timing of SR trigger w.r.t. current TTI

R2-086580 Philips Signalling of SIB7 information to speed up RACH access

R2-086129 NXP Semiconductors, Infineon, Philips

Limitations on PDCP/RLC SDU into MAC TB multiplexing

A.3 RAN Plenary Tdoc Number

Source Companies Title

RP-070454 Philips Grouping of Release 7 Features RP-070679 Proposed New Work Item: Enhanced UE

DRX Nokia, Nokia Siemens Networks, Qual-comm, LG Electronics, Philips, NXP

RP-080137 NTT DoCoMo, Alcatel-Lucent, AT&T, CATT, China Mobile, Ericsson, ETRI, Fujitsu, Huawei, InterDigital, LG Electron-ics, Mitsubishi Electric, Motorola, NEC, Nokia, Nokia Siemens Networks, Nortel, Orange, Panasonic, Philips, Qualcomm Europe, RIM, RITT, Rohde&Schwarz, Samsung, Sharp, Telecom Italia, Telefo-nica, Texas Instruments, T-Mobile Intl., Toshiba, Verizon, Vodafone, ZTE

Proposed SID on LTE-Advanced

RP-081110 NTT DOCOMO, Motorola, Panasonic, Nokia, Nokia Siemens Networks, Erics-son, LGE, Sharp, NEC, Fujitsu, Philips, Samsung

Clarification on path loss definition



RP-081115 NTT DOCOMO, Motorola, Panasonic, Nokia, Nokia Siemens Networks, Erics-son, LGE, Sharp, NEC, Fujitsu, Philips, Samsung

Clarification on path loss definition

REV-080042 Philips, NXP Comments on LTE-Advanced require-ments

REV-080043 Philips, NXP Key Technology Issues for LTE-Advanced



B 3GPP Meetings Attended Detailed reports were provided on each of the following meetings:

B.1 2007

3GPP RAN WG1 meeting #47bis: 15th - 19th January, Sorrento, Italy.

3GPP RAN WG2 meeting #56bis: 15th - 19th January, Sorrento, Italy.

3GPP RAN WG1 meeting #48: 12th - 16th February, St Louis, USA.

3GPP RAN WG2 meeting #57: 12th - 16th February, St Louis, USA.

3GPP RAN Plenary meeting #35: 6th - 9th March, Larnaca, Cyprus.

3GPP RAN WG1 meeting #48bis: 26th - 30th March, St Julian’s, Malta.

3GPP RAN WG2 meeting #57bis: 26th - 30th March, St Julian’s, Malta.

3GPP RAN WG1 meeting #49: 7th - 11th May, Kobe, Japan.

3GPP RAN WG2 meeting #58: 7th - 11th May, Kobe, Japan.

3GPP RAN Plenary meeting #36: 29th May - 1st June, Busan, Korea.

3GPP RAN WG1 meeting #49bis: 25th - 29th June, Orlando, USA.

3GPP RAN WG2 meeting #58bis: 25th - 29th June, Orlando, USA.

3GPP RAN WG1 meeting #50: 20th - 24th August, Athens, Greece.

3GPP RAN WG2 meeting #59: 20th - 24th August, Athens, Greece.

3GPP RAN Plenary meeting #37: 11th - 14th September, Riga, Latvia.

3GPP RAN WG1 meeting #50bis: 8th - 12th October, Shanghai, China.

3GPP RAN WG2 meeting #59bis: 8th - 12th October, Shanghai, China.

3GPP RAN WG1 meeting #51: 5th - 9th November, Jeju, Korea.

3GPP RAN WG2 meeting #60: 5th - 9th November, Jeju, Korea.

3GPP RAN Plenary meeting #38: 28th - 30th November, Cancun, Mexico (including workshop on IMT-Advanced).

B.2 2008

3GPP RAN WG1 meeting #51bis: 14th - 18th January, Sevilla, Spain.

3GPP RAN WG2 meeting #60bis: 14th - 18th January, Sevilla, Spain.

3GPP RAN WG1 meeting #52: 11th - 15th February, Sorrento, Italy.



3GPP RAN WG2 meeting #61: 11th - 15th February, Sorrento, Italy.

3GPP RAN Plenary meeting #39: 4th - 7th March, Puerto Vallarta, Mexico.

3GPP RAN WG1 meeting #52bis: 31st March - 4th April, Shenzhen, China.

3GPP RAN WG2 meeting #61bis: 31st March - 4th April, Shenzhen, China.

3GPP RAN Workshop on LTE-Advanced: 7th - 8th April, Shenzhen, China.

3GPP RAN WG1 meeting #53: 5th - 9th May, Kansas City, USA.

3GPP RAN WG2 meeting #62: 5th - 9th May, Kansas City, USA.

3GPP RAN Plenary meeting #40: 30th June - 4th July, Warsaw, Poland.

3GPP RAN WG1 meeting #54: 18th - 22nd August, Jeju, Korea.

3GPP RAN WG2 meeting #63: 18th - 22nd August, Jeju, Korea.

3GPP RAN Plenary meeting #41: 9th - 12th September, Kobe, Japan.

3GPP RAN WG1 meeting #54bis: 29th September - 3rd October, Prague, Czech Republic.

3GPP RAN WG2 meeting #63bis: 29th September - 3rd October, Prague, Czech Republic

3GPP RAN WG1 meeting #55: 10th – 14th November, Prague, Czech Republic

3GPP RAN WG2 meeting #64: 10th – 14th November, Prague, Czech Republic

3GPP RAN Plenary meeting #42: 2nd – 4th December, Athens, Greece.

3GPP Standardisation 2007 - 20082ffbbddf-445f-4e2b-bae5... · 3GPP Standardisation 2007 - 2008 ....

Documents

Transcript of 3GPP Standardisation 2007 - 20082ffbbddf-445f-4e2b-bae5... · 3GPP Standardisation 2007 - 2008 ....