基于高性能编码调制映射的联合解调译码方法

doi:10.3969/j.issn.0372-2112.2018.09.021

电子学报 ›› 2018, Vol. 46 ›› Issue (9): 2194-2200.DOI: 10.3969/j.issn.0372-2112.2018.09.021

基于高性能编码调制映射的联合解调译码方法

侯磊, 张灿, 高绍帅, 陈德元

中国科学院大学电子电气与通信工程学院, 北京 101408

收稿日期:2017-05-23 修回日期:2017-09-26 出版日期:2018-09-25
- 通讯作者:
- 侯磊
- 作者简介:
- 张灿女,1954年7月生于湖南,中国科学院大学电子电气与通信工程学院教授,博士生导师.主要研究方向为移动无线通信,无线网络安全和信号处理.E-mail:czhang@ucas.ac.cn;高绍帅 男,1976年6月生于山东德州,中国科学院大学电子电气与通信工程学院教授,博士生导师.主要研究方向为无线通信,视频处理与通信.E-mail:ssgao@ucas.ac.cn;陈德元 男,1968年2月生于贵州省金沙县,中国科学院大学电子电气与通信工程学院副教授.主要研究方向为信道编码,联合信源信道编码.E-mail:chendy@ucas.ac.cn
- 基金资助:
- 国家自然科学基金 (No.61571416，No.61271282）; 中国科学院奖励基金

A Joint Demodulation and Decoding Method Based on High-Performance Code-Modulation Mapping

HOU Lei, ZHANG Can, GAO Shao-shuai, CHEN De-yuan

School of Electronic, Electrical and Communication Engineering, University of Chinese Academy of Sciences, Beijing 101408, China

Received:2017-05-23 Revised:2017-09-26 Online:2018-09-25 Published:2018-09-25

摘要/Abstract

摘要： 对于功率受限的加性高斯白噪声（Additive White Gaussian Noise，AWGN）信道，当具有高斯分布的信号作为信道输入时，信息传输性能接近信道容量.为了传输性能接近容量限，本文采用优化的非均匀排布APSK（Amplitude Phase Shift Keying）星座取代传统的多维QAM（Quadrature Amplitude Modulation）调制星座图，利用二进制交换算法（Binary Switching Algorithm，BSA）进行星座图的反馈后哈姆尼克均值优化，设计了一种新型的"4+12F-APSK"非均匀排布的星座映射方案，并与BICM-ID（Bit Interleaved Coded Modulation-Iterative Decoding）解调译码相结合，提出了基于高性能编码调制映射的联合解调译码方法，有效地解决了接近信道容量限的联合解调译码的难题.实验结果表明，在瑞利衰落信道误比特率在10的-5次方量级时，该方法比传统的MSEW（Maximum Squared Euclidean Weight），GRAY，SP（Set Partitioning）三种矩形QAM调制方案的译码性能至少改善0.6dB；在AWGN信道误比特率在10的-3次方量级时，该方法比传统的MSEW和GRAY映射至少改善0.3dB.同时，与其他16APSK映射方案相比，该方法无论是在瑞丽衰落信道还是在AWGN信道条件下，在相同的误比特率量级上，都具有1dB~2dB的译码性能增益，有效地逼近了传输容量限.该方法在移动通信和电视广播通信等资源有限网络中具有广泛的应用前景.

关键词: 非均匀排布APSK星座, 映射方案优化, 迭代-比特交织编码调制, 联合解调译码

Abstract: Over a power-limited additive white Gaussian noise channel(AWGN),the transmission performance can achieve the channel capacity when the input follows Gaussian distribution.Therefore,this paper found a promising ununiform-APSK(Amplitude Phase Shift Keying) constellation mapping "4+12F-APSK" which is optimized by the binary switching algorithm(BSA) using Harmonic mean after feedback to be the cost function,and presented a joint demodulation and decoding method based on high-performance code-modulation mapping to approach the channel capacity efficiently.In BICM-ID(Bit Interleaved Coded Modulation-Iterative Decoding),simulation results show that,in Rayleigh fading channel at BER(Bit Error Rate) of ten to the negative five,the proposed method outperforms the traditional rectangle 16QAM(Quadrature Amplitude Modulation) mapping as MESW(Maximum Squared Euclidean Weight),GRAY and SP(Set Partitioning) by 0.6dB at least;in AWGN channel at BER of ten to the negative three,this number is 0.3dB compared with MSEW and GRAY mapping.Moreover,both in Rayleigh and AWGN channels,the proposed method has 1dB~2dB performance gain compared with the other ununiform-16APSK mappings.It has a wide range of applications in resource limited networks such as mobile and broadcast communication.

Key words: non-uniformly spaced APSK constellation, mapping optimization, BICM-ID, joint demodulation and decoding

中图分类号:

TN911.3

侯磊, 张灿, 高绍帅, 陈德元. 基于高性能编码调制映射的联合解调译码方法[J]. 电子学报, 2018, 46(9): 2194-2200.

HOU Lei, ZHANG Can, GAO Shao-shuai, CHEN De-yuan. A Joint Demodulation and Decoding Method Based on High-Performance Code-Modulation Mapping[J]. Acta Electronica Sinica, 2018, 46(9): 2194-2200.

参考文献

[1] Xie Q L,Yang Z X,Song J,et al.EXIT-chart-matching-aided near-capacity coded modulation design and a BICM-ID design example for both gaussian and rayleigh channels[J].IEEE Transactions on Vehicular Technology,2013,62(3):1216-1227.
[2] Ungerboeck G.Channel coding with multilevel phase signals[J].IEEE Transactions on Information Theory,1982,28(1):55-67.
[3] Zehavi E.8-PSK trellis codes for a Rayleigh fading channel[J].IEEE Transactions on Communications,1992,40(5):873-883.
[4] Li X,Ritcey J A.Bit-interleaved coded modulation with iterative decoding[J].IEEE Communications Letters,1997,1(6):169-171.
[5] Navazi H M,Nguyen H H.A novel and efficient mapping of 32-qam constellation for BICM-ID systems[J].Wireless Personal Communications,2014,79(1):197-210.
[6] 宫丰奎,葛建华,王勇,张楠.基于BICM的高效编码协作方案及性能分析[J].电子学报,2010,4(38):748-753. Gong Feng-kui,Ge Jian-hua,Wang Yong,Zhang Nan.A BICM-based CC scheme with high efficiency and its performance analysis[J].Acta Electronica Sinica,2010,4(38):748-753.(in Chinese)
[7] Tan J D,Wang Q,Qian C,et al.A reduced-complexity demapping algorithm for BICM-ID systems[J].IEEE Transactions on Vehicular Technology,2015,64(9):4350-4356.
[8] Zou Xuelan,Liu Weiyan,Feng Guangzeng.Applying chaonic maps to interleaving scheme design in BICM-ID[J].Chinese Journal of Electronics,2010,19(3):521-524.
[9] ETSI EN 302307-1 V1.4.1(2014-11),Digital Video Broadcasting (DVB):Second Generation Framing Structure,Channel Coding and Modulation Systems for Broadcasting,Interactive Services,News Gathering and Other Broadband Satellite Applications:Part 1:DVB-S2[S].
[10] Gaudenzi R D,Fàbregas A G I,Martinez A,et al.Turbo-coded APSK modulations design for satellite broadband communications[J].International Journal of Satellite Communications and Networks,2006,24(4):261-281.
[11] Bahl L R,Cocke J,Jelinek F,et al.Optimal decoding of linear codes for minimizing symbol error rate[J].IEEE Transactions on Information Theory,1974,20(2):284-287.
[12] Caire G,Tarocco G,Biglieri E.Bit-interleaved coded modulation[J].IEEE Transactions on Information Theory,1998,44(3):927-946.
[13] Tan J,Stüber G L.Analysis and design of interleaver mappings for iteratively decoded BICM[A].IEEE International Conference on Communications[C].New York:IEEE,2002.1403-1407.
[14] Chindapol A,Ritcey J A.Design analysis and performance evaluation for BICM-ID with square qam constellations in rayleigh fading channels[J].IEEE Journal on Selected Areas in Communications,2001,19(5):944-957.
[15] Schreckenbach F,Gortz N,Hagerauer J,et al.Optimization of symbol mappings for bit-interleaved coded modulation with iterative decoding[J].IEEE Communications Letters,2003,7(12):593-595.
[16] Liu Z S,Xie Q L,Peng K W,et al.APSK constellation with gray mapping[J].IEEE Communications Letters,2011,15(12):1271-1273.
[17] Lin S,Costello D J JR.Error Control Coding[M].NJ:Prentice Hall,2004.

基于高性能编码调制映射的联合解调译码方法

A Joint Demodulation and Decoding Method Based on High-Performance Code-Modulation Mapping

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