MIMO OFDM系统联合时频同步算法

Joint Time and Frequency Synchronization Method for MIMO OFDM Systems

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摘要为了解决多输入多输入多输出(Multiple imput multiple output,MIMO)正交频分复用(Orthogonal frequency division multiplexing,OFDM)系统的时间和频率偏移估计问题,提出了一种基于恒幅零自相关(Constant amplitude zero auto correlation,CAZAC)序列的联合时频同步算法。同步前导包括两个相同长度的训练符号。在接收端,分别计算两个本地训练序列与接收信号的互相关,利用CAZAC序列的特性可以检测出所有收发天线对之间的时间偏移和整数频率偏移;然后对接收信号进行整数频偏补偿,利用两个训练符号之间的关系可以估计出小数频率偏移。分析和仿真结果表明,该算法与传统的同步算法相比,不但具有更高的同步概率,而且能够估计出所有收发天线对之间的频率偏移。 To address the problem of time and frequency offset estimation for multiple input multiple output（MIMO） orthogonal frequency division multiplexing（OFDM） systems,a joint time and frequency synchronization algorithm based on constant amplitude zero auto correlation（CAZAC） sequences is proposed.The synchronization preamble consists of two training symbols with the same length.At the receivers,cross correlations between two local sequences and the received signal are calculated respectively,and the unique properties of CAZAC sequences are utilized to detect the time offsets and integer frequency offsets of all the transmitter and receiver pairs.After compensating for the integer frequency offsets,fractional frequency offsets are obtained by using the relationship between two training symbols.Analysis and simulation results demonstrate that the proposed method has a significantly higher synchronization probability than the conventional algorithm,and it can estimate the frequency offsets of all the transmitter and receiver pairs.

作者许成谦刘萌萌

机构地区燕山大学信息科学与工程学院

出处《数据采集与处理》 CSCD 北大核心 2012年第5期607-611,共5页 Journal of Data Acquisition and Processing

基金国家自然科学基金(61172094)资助项目

关键词正交频分复用多输入多输出时间同步频率同步恒幅零自相关 orthogonal frequency division multiplexing（OFDM） multiple input multiple output（MIMO） time synchronization frequency synchronization constant amplitude zero auto correlation（CAZAC）

分类号 TN92 [电子电信—通信与信息系统]

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参考文献9

1Schmidl T M, Cox D C. Robust frequency and tim- ing synchronization for OFDM [J]. IEEE Transac- tions on Communications, 1997, 45(12) : 1613-1621.
2Mody A N, Stuber G L. Synchronization for MIMO OFDM systems [C]//IEEE Global Telecommuni- cations Conference (GLOBECOM' 01). San Anto- nio, USA : IEEE, 2001 : 509-513.
3Van Zelst A, Schenk T C W. Implementation of an MIMO OFDM-based wireless LAN system[J]. IEEE Transactions on Signal Processing, 2004, 52 (2) : 483-494.
4郑娟,韩静,吕旌阳,吴伟陵,王衍文.MIMO-OFDM系统中高性能同步算法[J].北京邮电大学学报,2008,31(1):112-115. 被引量：7
5Feng C, Zhang J H, Zhang Y Y, et al. A novel tim- ing synchronization method for MIMO OFDM sys- tems[C]// IEEE Vehicular Technology Conference (VTC Spring 2008). Singapore: IEEE, 2008: 913- 917.
6Duanmu C J, Huang F. A timing synchronization method for MIMO-OFDM systems[C]// 2010 2nd International Conference on Information Science and Engineering. Hangzhou, China: IEEE (ICISE), 2010:1807-1810.
7Simon E P, Ros L, Hijazi H, et al. Joint carrier fre- quency offset and fast time-varying channel estima- tion for MIMO-OFDM systems [J]. IEEE Transac- tions on Vehicular Technology, 2011, 60(3): 955- 965.
8Younis S, A1-Dweik A, Hazmi A. Blind carrier fre- quency offset estimator for multi-input multi-output- orthogonal frequency division multiplexing systems over frequency-selective fading channels [J]. IET Communications, IET, 2010,4 (8) : 990-999.
9Chu D C. Polyphase codes with good periodic corre- lation properties[J]. IEEE Transactions on Informa- tion Theory, 1972, 18(4): 531-532.

二级参考文献7

1白洁,张建华,刘若菊,何学奇,张平.MIMO-OFDM系统定时与多径时延估计[J].北京邮电大学学报,2005,28(5):52-54. 被引量：7
2Mody A N, Stuber G L. Synchronization for MIMOOFDM systems [ C ] ff IEEE Global Communications Conference. San Antonio: IEEE, 2001: 509-513.
3Van Zelst A, Schenk T C W. Implementation of a MIMO OFDM-based wireless LAN system [ J ]. IEEE Transactions on Signal Processing, 2004, 52 (2) : 483- 494.
4Schmidl T M, Cox D C. Robust frequency and timing synchronization for OFDM [ J ]. IEEE Transactions on Communication, 1997, 45(12): 1613-1621.
5Tufvesson F, Edfors O, Faulkner M. Time and frequency synchronization for OFDM using PN-sequence preambles[C]//IEEE Vehicular Technology Conference. Amsterdam: IEEE, 1999: 2203-2207.
6Chu D C. Polyphase codes with good periodic correlation properties[J]. IEEE Transactions on Information Theory, 1972, 18(4): 531-532.
7Seung Duk Choi, Jung Min Choi, Jae Hong Lee. An initial timing offset estimation method for OFDM systems in rayleigh fading channel[C]//IEEE Vehicular Technology Conference. Hyatt Regency Montreal: IEEE, 2006: 1-5.

共引文献6

1谭泽富,廖明霞.同步误差对MIMO-OFDM系统性能的联合影响[J].重庆邮电大学学报（自然科学版）,2010,22(3):277-282. 被引量：3
2刘萌萌,许成谦.一种基于训练序列的OFDM联合时频同步算法[J].燕山大学学报,2011,35(3):257-261.
3孙虎.利用ZC序列的OFDM同步及稀疏信道估计[J].电子科技,2013,26(11):47-50. 被引量：1
4孙虎,胡方明,杜强.基于ZC序列的OFDM同步及稀疏信道估计算法[J].华中科技大学学报（自然科学版）,2013,41(10):6-10. 被引量：3
5张忠民,刘鑫.OFDM定时和频率同步改进算法[J].计算机仿真,2015,32(5):293-296. 被引量：3
6顾庆峰,杨仕平,王健,刘绍华.一种大频偏系统下信号检测序列的设计方法[J].舰船电子工程,2015,35(11):150-153.

1聂伟,严寒.一种改进的MIMO-OFDM系统时间同步方法[J].电子技术应用,2015,41(5):112-115. 被引量：1
2陈志颖,谢维波,王磊.音视频实时同步传输技术研究与实现[J].华侨大学学报（自然科学版）,2011,32(4):389-392. 被引量：6
3JunfeiLi HaoLing 李恒张侠.在更高阶运动目标ISAR成像中使用遗传算法[J].空载雷达,2005(1):59-65.
4陈发堂,曾雄.基于CAZAC序列的MIMO-OFDM系统定时同步算法[J].广东通信技术,2016,36(1):32-35.
5平一帆,张海林,王皓.一种新型OFDM系统频率和时间同步算法[J].无线电通信技术,2007,33(1):9-10.
6平一帆,张海林,王皓.一种新型OFDM系统频率和时间同步算法[J].电子元器件应用,2006,8(7):84-86.
7严春林,李少谦,唐友喜,罗霄,房家奕.利用CAZAC序列的OFDM频率同步方法[J].电子与信息学报,2006,28(1):139-142. 被引量：19
8黄淑琼.解析UWB信号的PPM调制性能[J].自动化技术与应用,2007,26(10):30-31.
9卢挺丰.现代OFDM系统中的同步技术[J].电子世界,2014(22):368-369.
10杨国军,贺志毅.舰船目标逆合成孔径成像算法改进研究[J].现代防御技术,2013(1):47-52. 被引量：1

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MIMO OFDM系统联合时频同步算法

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