1. 1 Performance comparison of Modulation and Coding set for IEEE 802.16m system Document Number: IEEE C802.16m-09/0555r3 Date Submitted: 2009-03-02 Source: Hua Zhou, Shengbao Liang, Yuanrong Lan, Jie Zhang, Yuantao Zhang, Jinyin Xue, Jian Wang, Jun Tian Voice:+86-10-59691519 Fujitsu R&D Center.E-mail: zhouhua@cn.fujitsu.com Venue: Call for comment on 802.16m amendment working document Comment for the text of “ Channel coding and HARQ ” Base Contribution: C802.16m-08_1425 Purpose: To be discussed and adopted into the 802.16m AWD by TGm. Notice: This document does not represent the agreed views of the IEEE 802.16 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 802.16. Patent Policy: The contributor is familiar with the IEEE-SA Patent Policy and Procedures: and.http://standards.ieee.org/guides/bylaws/sect6-7.html#6http://standards.ieee.org/guides/opman/sect6.html#6.3 Further information is located at and.http://standards.ieee.org/board/pat/pat-material.htmlhttp://standards.ieee.org/board/pat

2. 2 Introduction FEC&HARQ DG work out the draft proposal for nominal modulation and coding set. But this MCS table is lack of system level simulation result support. Without simulation results, we can not say how it works. We would like to investigate the existing MCS candidate on system level simulation. In other hand, 4-bit table or 5-bit table should also be evaluated, considering LTE has 5-bit MCS table. We might not close the MCS table size discussion until we have enough simulation results.

3. 3 Summary The simulation shows that two 4-bit MCS tables have almost same performance. However, Fujitsu’s proposal has a little gain over contribution C802.16m-09_0510’s proposal. Going beyond that, we simulate LTE 5-bit MCS table, which can bring 20+% throughput and coverage gain over 16E 11-level MCS table. In order to achieve higher performance, it’s worthwhile having 5-bit MCS table as candidate. We propose not to conclude MCS table before we have more simulation, for example, with bigger size MCS table and with CL SU/MU- MIMO scenario.

4. 4 Simulation results System level simulation MCS table Sector Throughput (Mbps)User Coverage 5%(bps/Hz) MIMO (2x2)MIMO(4x4)MIMO (2x2)MIMO(4x4) 16e MCS table (11-level)14.124.10.0270.049 Fujitsu ’ s MCS table (16-level) 15.7 (11.3%)26.6 (10.3%)0.032 (18.5%)0.054 (10.2%) C802.16m-09_0510 ’ s MCS table (16-level) 15.526.40.032 0.054 LTE MCS table (5-bit) 17.2 (22.0%) N/A 0.037 (37.0%) N/A

5. 5 C802.16m-09_0510’s proposal MCS indexModulationCode rate ‘ 0000 ’ QPSK31/256 ‘ 0001 ’ QPSK48/256 ‘ 0010 ’ QPSK71/256 ‘ 0011 ’ QPSK101/256 ‘ 0100 ’ QPSK135/256 ‘ 0101 ’ QPSK171/256 ‘ 0110 ’ 16QAM102/256 ‘ 0111 ’ 16QAM128/256 ‘ 1000 ’ 16QAM155/256 ‘ 1001 ’ 16QAM184/256 ‘ 1010 ’ 64QAM135/256 ‘ 1011 ’ 64QAM157/256 ‘ 1100 ’ 64QAM181/256 ‘ 1101 ’ 64QAM205/256 ‘ 1110 ’ 64QAM225/256 ‘ 1111 ’ 64QAM237/256

6. 6 Fujitsu’s proposal MCS IndexCode RateMod OrderSpectral Efficiency 00.133320.2667 10.217420.4348 20.344820.6897 30.476220.9524 40.600021.2000 50.315741.2632 60.416741.6667 70.484841.9394 80.555642.2222 90.625042.5000 100.714242.8571 110.500063.0000 120.611163.6667 130.703764.2222 140.800064.8000 150.904865.4286

7. 7 Simulation parameter settings ParametersValues Bandwidth10 MHz FFT size1024 Carrier frequency2.5 GHz Subframe structure18x6 CRU, according to the latest revision of IEEE 80216m-08/003r6 Channel ModelTU channel Mobile speed3 km/h Antenna configuration2x2, 4x4 Receiver algorithmMMSE Channel coding & modulation 16e 11 MCS & new MCS & LTE 29-level MCS Channel estimationPerfect channel estimation HARQ scheme Synchronous HARQ with Chase Combining, Retransmission delay = 8 TTI with maximum 3 retransmissions and initial target PER of 10% CQI feedback period and delayEvery 8 TTI Scheduling methodPF Cell to cell distance500m BTS power46dbm Shadow fading8dB UE noise figure9dB Link adaptation methodRBIR for MMSE receiver and SISO

8. 8 Proposed MCS table text for IEEE 802.16m AWD 15.x.1.3 –Table 15.x.1-1 MCS table for downlink and uplink data channel [TBD]