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光通信中基于BCJR的BCH译码算法研究 被引量:3

Research on BCJR-based BCH decoding algorithm in optical communication
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摘要 首先从理论上分析了硬判决译码算法和软判决译码算法的性能然后对BCH(Bose,Ray-Chaudhuri,Hocquenghem)码的网格结构以及BCJR(Bahl,Cocke,Jelinek and Raviv)算法进行了详细地分析及推导。实验结果表明,在光信道环境中,在误比特率为10-5时,当仅提高最小汉明距离码率相同或者仅减小码率最小汉明距离相同时,BCJR算法相对于硬判决译码算法的编码增益分别在之前的编码增益基础上又增加了0.15dB和0.25dB。因此设计级联码方案时,应尽可能选择纠错能力较大的内码。此外也可以采用适当增加内码的冗余度相应减小外码的冗余度的方法,在获得更高的编码增益的同时保证整个系统的带宽利用率不变。 In this paper,the performances of the hard-decision and the soft-decision decoding algorithms for BCH(Bose,Ray-Chaudhuri,Hocquenghem) codes are analyzed in theory firstly.Then the trellis structure of BCH codes is introduced and the Bahl,Cocke,Jelinek and Raviv(BCJR) algorithm based on trellis is deduced.The experimental results show that in optical channel,as the bit-error-ratio reaches 10-5,the coding gain difference between the BCJR algorithm and the hard-decision algorithm is increased by 0.15 dB when only increasing the minimum Hamming distance and by 0.25 dB when only reducing the code rate.Therefore,for a concatenated code design in optical communication,the inner code with larger error correcting capability should be selected as possible.In addition,in order to obtain the higher coding gain and ensure the system bandwidth utilization rate unchanged,the method appropriately increasing the redundancy of inner code and decreasing the redundancy of outer code correspondingly is suggested.
作者 袁建国 何清萍 梁天宇 王永
机构地区 重庆邮电大学光纤通信技术重点实验室
出处 《光电子.激光》 EI CAS CSCD 北大核心 2012年第6期1093-1097,共5页 Journal of Optoelectronics·Laser
基金 国家自然科学基金(61071117 61003256) 重庆市自然科学基金(2010BB2409) 重庆市教委(KJ110519)资助项目
关键词 BCJR算法 网格 软判决译码 光通信 BCJR algorithm trellis soft decision decoding optical communication
分类号 TN911.22 [电子电信—通信与信息系统]
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光电子.激光
2012年 第6期

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