单载波频域均衡中的水声信道频域响应与噪声估计

张歆; 张小蓟; 邢晓飞; 姜丽伟

doi:10.7498/aps.63.194304

摘要

本文对单载波频域均衡（SC-FDE）中的信道和噪声估计进行研究，理论分析了形成误码率平台的可能原因，提出了基于Chu序列的联合信道时频域响应和噪声功率估计算法. 利用水声信道响应的稀疏特性和门限确定信道能量集中区域，进行信道估计的去噪处理和噪声功率计算. 借助于水声射线模型对所提出的算法进行了仿真，分析了噪声估计对SC-FDE性能的重要影响. 仿真结果表明，所提出的信道和噪声估计算法可以有效减缓或消除SC-FDE中的误码率平台.

关键词:

Abstract

Single-carrier frequency domain equalization (SC-FDE) has drawn increasing researches because of its lower computational complexity and better performance of mitigating intersymbol interference (ISI) as compared with the time domain equalization. The practical SC-FDE systems, however, require the knowledge of the channel frequency domain response and the noise power to calculate filter coefficients of the frequency domain equalizer. Improper channel and noise estimations have been shown to result in error floor at high signal-to-noise ratio (SNR), which may impede the utilization of SC-FDE in the high-rate underwater acoustic (UWA) communications. In this paper, we discuss the possible influence of inaccurate noise estimation on the error floor at high SNR, and propose a joint estimation scheme for the channel time domain and frequency domain responses and also the noise power based on Chu sequence. The channel energy concentration region is determined by the threshold and the sparse channel impulse response (CIR) of UWA channels, used in denoising process of the CIR and the noise power computation. The bite error ratio performance of the SC-FDE variation versus the threshold is simulated via the UWA models, and accurate noise power estimation is shown to be desirable to improve the SC-FDE performance. Numerical examples also indicate that our joint estimation scheme can eliminate the error floor and improve the performance of SC-FDE at high SNR.

Keywords:

single-carrier frequency domain equalization /
channel estimation /
underwater acoustic communications /
channel equalization

作者及机构信息

1.
西北工业大学, 航海学院, 西安 710072

基金项目: 国家自然科学基金（批准号：61371088）资助的课题.

Authors and contacts

1.
School of Marine Science and Technology, Northwestern Polytechnical University, Xi'an 710072, China

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 61371088).

参考文献

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[2]	Zhang J, Zheng Y R, Xiao C S 2008 IEEE Conference Oceans 2008 Quebec, Canada, September 15-18 2008, p1
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[4]	Li B S, Huang J Zhou S L, Ball K, Stojanovic M, Freitag L 2009 IEEE J. Ocean Eng 34 634
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施引文献

[1]	Chitre M, Shahabudeen S, Freitag L, Stojanovic M 2008 IEEE Coference Oceans 2008 Quebec, Canada, September 15-18, 2008 p1
[2]	Zhang J, Zheng Y R, Xiao C S 2008 IEEE Conference Oceans 2008 Quebec, Canada, September 15-18 2008, p1
[3]	Zhang J, Zheng Y R 2010 J. Acoust. Soc. Am. 128 2910
[4]	Li B S, Huang J Zhou S L, Ball K, Stojanovic M, Freitag L 2009 IEEE J. Ocean Eng 34 634
[5]	Czylwik A 1997 IEEE Conference VTC Phoenix Arizona, USA, May 4-7, 1997 2 865
[6]	Benvenuto N, Tomasin S 2005 IEEE Trans. Communications 53 1867
[7]	Benvenuto N, Dinis R, Falconer D, Tomasin S 2010 Proceedings of the IEEE, 98 69
[8]	Zhang C, Wang Z C, Pan C Y, Chen S, Li H Z 2011 IEEE Trans. On Vehicular Technology 60 1295
[9]	Zhang X, Zhang X J 2013 J. Electronic & Information Technology35 510 (in Chinese) [张歆, 张小蓟2013电子与信息学报35 510]
[10]	He C B, Huang J G, Meng Q W, Zhang Q F, Shi W T 2013 Acta Phys. Sin. 62 234301(in Chinese) [何成兵, 黄建国, 孟庆微, 张群飞, 史文涛 2013 62 234301]
[11]	Huang G. L, Nix A, Armour S 2010 IEEE Vehicular Technology Conference Ottawa, Canada, September 6-9, 2010 p1
[12]	Zhang H T, Zhang X, Yang D C 2012 IEEE Vehicular Technology Conference Yokohama, Japan, May 6-9 2012, p1
[13]	Lam C T, Falconer D D, Danilo-Lemoine F 2008 IEEE J. Selected Areas in Communications 26 348
[14]	Coelho F, Dinis R, Montezuma P 2010 Military Communications Conference San Jose, USA, October 31-November 3, p1765
[15]	Zheng Y R, Xiao C S 2009 IEEE Trans. on Vehicular Technology 58 815
[16]	Wang H S, Zeng G H 2008 Chin. Phys. Soc. 17 4451

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