1 Hybrid ARQ Operation for IEEE m IEEE Presentation Submission Template (Rev. 9) Document Number: IEEE C802.16m-08/454 Date Submitted: Source: Sungkyung Kim, Kwangjae Lim, Sungcheol Chang, Voice: Seokheon Cho, Jungim Kim, Chulsik Yoon {cyrano, kjlim, scchang, ETRI 161 Gajeong-dong Yusong-gu Daejeon, Korea * Venue: EEE Session #55, Macau, China Base Contribution: IEEE C802.16m-08/454 Purpose: To discuss and adopt the proposed text in the next revision of the m SDD Notice: This document does not represent the agreed views of the IEEE Working Group or any of its subgroups. It represents only the views of the participants listed in the “Source(s)” field above. It is offered as a basis for discussion. It is not binding on the contributor(s), who reserve(s) the right to add, amend or withdraw material contained herein. Release: The contributor grants a free, irrevocable license to the IEEE to incorporate material contained in this contribution, and any modifications thereof, in the creation of an IEEE Standards publication; to copyright in the IEEE’s name any IEEE Standards publication even though it may include portions of this contribution; and at the IEEE’s sole discretion to permit others to reproduce in whole or in part the resulting IEEE Standards publication. The contributor also acknowledges and accepts that this contribution may be made public by IEEE Patent Policy: The contributor is familiar with the IEEE-SA Patent Policy and Procedures: and. Further information is located at and.

2 Contents HARQ Mode HARQ Signaling HARQ Operation HARQ in Persistent Allocation HARQ Support for MAC PDU retransmission

3 HARQ Mode Comparison among the HARQ Operation Modes We propose the synchronous non-adaptive HARQ mode as a default mechanism by reason of low MAP overhead. Also, HARQ mode can be changed to the asynchronous adaptive scheme in order to get the scheduling gain or/and to support the flexibility of resource allocation. Synchronous non-adaptive Synchronous adaptive Asynchronous non-adaptive Asynchronous adaptive Retransmission timingfixed Not-fixed Retransmission formatfixeddynamicfixedDynamic Required retransmission signaling Implicit signaling Explicit signaling MAP overheadlowhigh flexibilitylowmedium high

4 HARQ Signaling Required HARQ Operation parameters –Per Network entry or/and Connection set-up HARQ type: CC, IR, CC-IR, etc. The number of maximum retransmissions in synchronous mode –Per New transmission of HARQ burst HARQ CH ID, toggle bit, SPID (IR case), MCS, Allocated resource region. –Per Retransmission in synchronous non- adaptive mode None –Per HARQ mode change Asynchronous mode indication –Per Retransmission in asynchronous adaptive mode HARQ CH ID, toggle bit, SPID (IR case), MCS or shortened adaptive transmission format, allocated resource region. [The Example for HARQ signaling]

5 DL HARQ Operation DL HARQ timing diagram –Synchronous HARQ subframe : N+M*X –Fixed or described HARQ feedback subframe: Y({N+M*X}%8) (N: subframe index of new transmission. M: the number of retransmission trials. X: synchronous HARQ interval, Y(K): HARQ feedback delay in K- subframe transmission) –The Example of TDD –The Example of FDD

6 UL HARQ Operation UL HARQ timing diagram –Synchronous HARQ subframe : N+M*X –Fixed or described HARQ feedback subframe: Y({N+M*X}%8) –The Example of TDD (5:3) DL HARQ Feedback –Physical channel vs. MAC signaling Physical DL Feedback channelMAC signaling via MAP CRC includedNoYes Error cases ACK to NAK error: collision owing to synchronous retransmission NAK to ACK error: data loss & resource waste Failure of reception: Resource waste FlexibilityLowhigh

7 HARQ in PA Persistent Allocation for VoIP –Fixed MCS and Fixed Allocated resource region. –HARQ signaling in PA Explicit HARQ CH ID allocation for new transmission The number of synchronous retransmissions (N=0, 1, 2,..) –The MS with low link budget may need more synchronous retransmissions without the additional MAP overhead. Resource allocation for asynchronous retransmission –The Example of Persistent Allocation with HARQ operation in downlink

8 HARQ Support for MAC PDU Retransmission HARQ-assisted Fast Retransmission –Purpose: To Recover the data loss owing to NAK to ACK Feedback Error and/or transmission failure by exceed in maximum retransmission. To reduce the long retransmission delay with ARQ scheme. –Operation: HARQ TX Side: Fast notification of maximum retransmission failure. HARQ RX Side: Delivery of HARQ Feedback Message (Report for HARQ ACK to NAK error or/and HARQ Max. retransmission failure) to the TX side.

9 Proposed Text (1) X.x. Hybrid ARQ Operations X.x.1 Basic Principles The HARQ scheme is basically a stop-and-wait protocol and supports multiple HARQ channels. Synchronous non-adaptive HARQ mode is used as a default scheme on both downlink HARQ and uplink HARQ in order to reduce downlink control overhead. Moreover, on purpose to enhance the scheduling gain and to support the flexibility of resource allocation, HARQ retransmission mode can be switched to asynchronous adaptive HARQ mode. To support optional asynchronous adaptive HARQ mode per HARQ burst, explicit signaling or implicit signaling is needed. For the HARQ operations the following parameters are considered: - HARQ type (CC, IR, CC-IR, etc.) - HARQ mode (synchronous non-adaptive, asynchronous adaptive) - HARQ CH ID - Toggle bit (new burst indication) - SPID (Redundancy version of IR) - MCS or Shortened adaptive HARQ transmission format - Allocated resource region - the number of maximum retransmissions

10 Proposed Text (2) For downlink HARQ operations, uplink HARQ feedback information (ACK/NAK) shall be transmitted through a physical uplink feedback channel. X.x.2 HARQ Operations for Persistent Allocation For Persistent Allocation, HARQ CH ID shall be explicitly signaled. The number of maximum synchronous retransmissions (N) is fixed during the persistent allocation (N=0, 1, 2,..). Xx3 HARQ support for fast MAC PDU retransmission Owing to the errors of the physical HARQ feedback channel and failure of maximum retransmission, data loss and resource waste can be generated on both downlink and uplink transmissions. To recover data loss and to reduce retransmission delay, HARQ feedback information can be used by the TX side. Moreover, cross-operations between HARQ and ARQ can be supported on both downlink HARQ and uplink HARQ.