空间相关性对水声多输入多输出系统信道容量的影响(英文) 被引量：3

Effect of spatial correlation on underwater acoustic MIMO capacity

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摘要通过三维多径相关模型,以垂直收发阵为例研究了信道参数如声线角度扩展范围、到达方向和收发阵元间距对水声MIMO信道容量的影响。如果考虑静止的收发阵,且不考虑信道中散射体的运动时,MIMO系统的信道容量由收发阵元信号的空间相关性决定,当空间相关性较小时,增加收发阵元数可以带来较大的信道容量增益,而当空间相关性较大时,随着收发阵元数的增加信道容量将趋于饱和。 The effect of channel parameters such as angle spread, angle of arrival, and array element spacing on the underwater acoustic MIMO capacity is studied with a three-dimensional muhipath correlation model using a vertical transmitting and receiving array. In a MIMO system with static transmitting and receiving arrays, regardless of the movement of scatters in the underwater acoustic channel, the capacity is dependent on the spatial correlation among array element signals at the transmitter as well as at the receiver. If correlation between elements of the channel matrix is weak, increasing the number of array elements will greatly increase the MIMO capacity. In a channel of strong correlation, increasing the number of array elements will cause the MIMO capacity to approach saturation.

作者朴大志孙长瑜李启虎

机构地区中国科学院声学研究所中国传媒大学信息工程学院 [

出处《声学技术》 CSCD 北大核心 2006年第6期573-579,共7页 Technical Acoustics

关键词多输入多输出水声空间相关信道容量 MIMO underwater acoustics spatial correlation channel capacity

分类号 TN929.3 [电子电信—通信与信息系统]

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参考文献8

1J H Winters,J Salz,R D Gitlin.The impact of antenna diversity on the capacity of wireless communication system[J].IEEE Trans.Commun,1994,42:1740-1751.
2I E Telatar.Capacity of multi-antenna gaussian channels[R].AT&T Bell Laboratories,Murray Hill,NJ,Tech.Rep.#B10 112 170-950-615-07 TM,1995.
3G J Foschini,M J Gans.On the limits of wireless communications in a fading environment when using multiple antennas[J].Wireless Pers.Commun,1998,6(3):311-335.
4M Zatman,B Tracey.Underwater acoustic MIMO channel capacity[A],signals,systems and computers,2002,conference record of the Thirty-Sixth Asilomar Conference,2002,2,3-6:1364-1368.
5D Shiu,G J Foschini,M J Gans,J M Kahn.Fading correlation and its effect on the capacity of multielement antenna systems[J].IEEE Trans.Commun,2000,48:502-513.
6C N.Chuah,D N C Tse,J M Kahn,R A Valenzuela.Capacity scaling in MIMO wireless systems under correlated Fading[J].IEEE Trans Inform Theory,2002,48:637-650..
7M Chiani,M Z.Win.On the capacity of spatially correlated MIMO Rayleigh-Fading channels[J].IEEE Trans Inform Theory,2003,49:2363-2371.
8A Leon-Garcia.Probability and Random Processes for Electrical Engineering[M].Addison-Wesley,1990.

同被引文献11

1朴大志,孙长瑜,李启虎.单声线水声MIMO信道容量的研究[J].应用声学,2006,25(2):76-81. 被引量：3
2Kilfoyle D B, Preisig J C, Baggeroer A B. Spatial Modulation Experiments in the Underwater Acoustic Channel [J]. IEEE Journal of Oceanic Engineering, 2005,30(2): 406-415.
3Subhadeep Roy, Tolga Duman, Leo Ghazikhanian, et al. Enhanced underwater acoustic communication performance using space-time coding and processing[C]. MTS/ IEEE Techno-Ocean,2004, (1):26-33.
4Golden G D, Foschini C J, Valenzuela R A, et al. Detection algorithm and initial laboratory results using V-BLAST space-time communication architecture[J]. IEE Elec. Letters. 1999,35(1):6-7.
5Stojanovie M, Catipovic J A, Proakis J G. Phase-coherent digital Communication for underwater acoustic channels [J]. IEEE Journal of Oceanic engineering, 1994, 19(1): 100-111.
6Kilfoyle D B, Preisig J C, Baggeroer A B. Spatial Modu-lation Experiments in the Underwater Acoustic Channel[J]. IEEE Journal of Oceanic Engineering, 2005, 30(2): 406-415.
7Subhadeep Roy, Tolga Duman, Leo Ghazikhanian, et al. Enhanced underwater acoustic communication performance using space-time coding and processing[C]// MTS/IEEE TECHNO-OCEAN, 2004(1): 26-33.
8Golden G D, Foschini C J, Valenzuela R A, et al. Detection algorithm and initial laboratory results using V-BLAST space-time communication architecture[J]. IEE Elec. Letters, 1999, 35(1): 6-7.
9Stojanovie M, Catipovic J A, Proakis J G. Phase-coherent digital Communication for underwater acoustic channels[J]. IEEE Journal of Oceanic engineering, 1994, 19(1): 100-111.
10Bernard Sklar. Digital Communication Fundamentals and Applications[M].

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5凤凰音响唱响2012上海国际专业灯光音响展[J].音响技术,2012(6):78-78.
6电子百科[J].世界电子元器件,2014,0(9):33-33.
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9唐育中.如何降低表声线的二阶效应[J].现代电子,1993(2):48-52.
10陈柚钢.浅谈个人通信终端主动加扰防监听的控制[J].计算机光盘软件与应用,2014,17(17):291-292.

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空间相关性对水声多输入多输出系统信道容量的影响(英文) 被引量：3

参考文献8

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