非对称衰落信道下无人机中继传输方案及性能分析

doi:10.7527/S1000-6893.2013.0016

流体力学、飞行力学与发动机

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非对称衰落信道下无人机中继传输方案及性能分析

欧阳键¹, 庄毅¹, 薛羽¹, 王洲²

1. 南京航空航天大学计算机科学与技术学院, 江苏南京 210016;
2. 中航工业洛阳电光设备研究所, 河南洛阳 471009

收稿日期:2012-01-17 修回日期:2012-02-01 出版日期:2013-01-25 发布日期:2013-01-19
通讯作者: 庄毅,Tel.:025-84896779,E-mail:zhuangyi@nuaa.edu.cn E-mail:zhuangyi@nuaa.edu.cn
作者简介:欧阳键,男,博士研究生。主要研究方向:分布计算、协同传输技术。,E-mail:ouyangjian@nuaa.edu.cn;庄毅,女,教授,博士生导师。主要研究方向:分布计算。Tel:025-84896779,E-mail:zhuangyi@nuaa.edu.cn;薛羽,男,博士研究生。主要研究方向:分布计算、电子对抗。,E-mail:xueyu_123@nuaa.edu.cn;王洲,男,硕士,工程师。主要研究方向:军用航电火控系统仿真技术。,E-mail:hi.wz@tom.com
基金资助:
航空科学基金(2010ZC13012);江苏省普通高校研究生科研创新计划(CXLX11_0202);中央高校基本科研业务费专项资金

UAV Relay Transmission Scheme and Its Performance Analysis over Asymmetric Fading Channels

OUYANG Jian¹, ZHUANG Yi¹, XUE Yu¹, WANG Zhou²

1. College of Computer Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China;
2. Luoyang Institute of Electro-Optical Equipment, AVIC, Luoyang 471009, China

Received:2012-01-17 Revised:2012-02-01 Online:2013-01-25 Published:2013-01-19
Supported by:
Aeronautical Science Foundation of China (2010ZC13012); Funding of Jiangsu Innovation Program for Graduate Education (CXLX11_0202); Fundmental Research Funds for the Central Universities

摘要/Abstract

摘要：

无人机(UAV)作为中继传输平台受到了国内外研究人员的广泛关注。本文研究了非对称衰落信道下的无人机中继传输系统,提出了输出信噪比最大化准则下的波束形成(BF)优化方案,并推导出系统中断概率、遍历容量和平均误符号率等无线通信系统主要性能指标的理论表达式。通过计算机仿真验证了本文提出的中继传输方案及性能分析的正确性,并定量分析了天线数量、信道参数以及功率分配对系统性能的影响,为无人机中继传输系统的设计及性能评估提供了参考和依据。

关键词: 无人机, 中继传输, 性能分析, 波束形成, 非对称衰落信道

Abstract:

The application of unmanned aerial vehicles (UAVs) in relay transmission systems has received more and more attention recently. This paper presents a study of a UAV relay transmission system over asymmetric fading channels. Using the maximization of the output signal-to-noise ratio as the design criterion, the optimal beamforming (BF) for the relay system is first obtained. Then, the new accurate expressions for the outage probability, ergodic capacity and average symbol error rate are all derived. Finally, computer simulations demonstrate the validity of the proposed relay transmission scheme and its performance analysis, and provide a quantitative study of the effect of antenna number, channel parameters and power allocation on system performance. Our work can provide some useful reference and foundation work to the system engineer for the purpose of designing a UAV relay transmission system and evaluating its performance.

Key words: unmanned aerial vehicles, relay transmission, performance analysis, beamforming, asymmetric fading channel

中图分类号:

V243
TN925

欧阳键, 庄毅, 薛羽, 王洲. 非对称衰落信道下无人机中继传输方案及性能分析[J]. 航空学报, 2013, 34(1): 130-140.

OUYANG Jian, ZHUANG Yi, XUE Yu, WANG Zhou. UAV Relay Transmission Scheme and Its Performance Analysis over Asymmetric Fading Channels[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2013, 34(1): 130-140.

参考文献

[1] Samad T, Bay J S, Godbole D. Network-centric systems for military operations in urban terrain: the role of UAVs. Proceedings of the IEEE, 2007, 95(1): 92-107.

[2] Iscold P, Pereira G A S, Torres L A B, et al. Development of a hand-launched small UAV for ground reconnaissance. IEEE Transactions on Aerospace and Electronic Systems, 2010, 46(1): 335-348.

[3] Sujit P B, Beard R. Multiple UAV exploration of an unknown region. Annals of Mathematics and Artificial Intelligence, 2008, 52(2-4): 335-366.

[4] Berioli M, Molinaro A, Morosi S. Aerospace communications for emergency applications. Proceedings of the IEEE, 2011, 99(11): 1922-1938.

[5] Brackett H. "Lost communication": the pilot to ATC communication solution. Integrated Communications, Navigation and Surveilance Conference, 2011: 1-21.

[6] Cerasoli C. An analysis of unmanned airborne vehicle relay coverage in urban environments. IEEE Military Communications Conference, 2007: 1-7.

[7] Olsson P M, Kvarnstrom J, Doherty P, et al. Generating UAV communication networks for monitoring and surveillance. The 11th International Conference on Control, Automation, Robotics and Vision, 2010: 1070-1077.

[8] Zhu H, Swindlehurst A L, Liu K. Optimization of MANET connectivity via smart deployment/movement of unmanned air vehicles. IEEE Transactions on Vehicular Technology, 2009, 58(7): 3533-3546.

[9] de Freitas E P, Heimfarth T, Netto I F, et al. UAV relay network to support WSN connectivity. International Congress on Ultra Modern Telecommunications and Control Systems and Workshops, 2010: 309-314.

[10] Burdakov O, Doherty P, Holmberg K, et al. Optimal placement of UV-based communications relay nodes. Journal of Global Optimization, 2010, 48(4): 511-531.

[11] Burdakov O, Doherty P, Holmberg K, et al. Relay positioning for unmanned aerial vehicle surveillance. International Journal of Robotics Research, 2010, 29(8): 1069-1087.

[12] Li G Y, Zhang Y G. Adaptive cooperative transmission and node selection in aircraft approach. Acta Aeronautica et Astronautica Sinica, 2011, 32(11): 2083-2095. (in Chinese) 李国彦, 张有光. 飞行器进近中的自适应协同传输与节点选择. 航空学报, 2011, 32(11): 2083-2095.

[13] Zhan P C, Yu K, Swindlehurst A L. Wireless relay communications with unmanned aerial vehicles: performance and optimization. IEEE Transactions on Aerospace and Electronic Systems, 2011, 47(3): 2068-2085.

[14] Jiang F, Swindlehurst A L. Dynamic UAV relay positioning for the ground-to-air uplink. IEEE Globecom Workshops, 2010: 1766-1770.

[15] Abualhaol I Y, Matalgah M M. Performance analysis of cooperative multi-carrier relay-based UAV networks over generalized fading channels. International Journal of Communication Systems, 2011, 24(8): 1049-1064.

[16] Simon M K, Alouini M S. Digital communication over fading channels. 2nd ed. Hoboken: John Wiley and Sons, Inc., 2005: 20-24.

[17] Scaglione A, Goeckel D L, Laneman J N. Cooperative communications in mobile Ad hoc networks. IEEE Signal Processing Magazine, 2006, 23(5): 18-29.

[18] Dumont J, Hachem W, Lasaulce S, et al. On the capacity achieving covariance matrix for rician MIMO channels: an asymptotic approach. IEEE Transactions on Information Theory, 2010, 56(3): 1048-1069.

[19] Ding H Y, Ge J H, da Costa D B, et al. Diversity and coding gains of fixed-gain amplify-and-forward with partial relay selection in Nakagami-m fading. IEEE Communications Letters, 2010, 14(8): 734-736.

[20] Zhang X D. Matrix analysis and application. Beijing: Tsinghua University Press, 2004: 540-541. (in Chinese) 张贤达. 矩阵分析与应用. 北京: 清华大学出版社, 2004: 540-541.

[21] Love D J, Heath R W, Jr, Lau V K N, et al. An overview of limited feedback in wireless communication systems. IEEE Journal on Selected Areas in Communications, 2008, 26(8): 1341-1365.

[22] Assalini A, Dall’Anese E, Pupolin S. On the robustness of MIMO LMMSE channel estimation. IEEE Transactions on Wireless Communications, 2010, 9(11): 3313-3319.

[23] Gradshteyn I S, Ryzhik I M, Jeffrey A. Table of integrals, series, and products. 7th ed. Burlington: Academic Press, 2007: 340, 368, 709, 916-922, 1005-1024.

[24] Fan L S, Lei X F, Li W. Exact closed-form expression for ergodic capacity of amplify-and-forward relaying in channel-noise-assisted cooperative networks with relay selection. IEEE Communications Letters, 2011, 15(3): 332-333.

[25] da Costa D B, Aissa S. Capacity analysis of cooperative systems with relay selection in Nakagami-m fading. IEEE Communications Letters, 2009, 13(9): 637-639.

[26] Abramowitz M, Stegun I A. Handbook of mathematical functions with formulas, graphs, and mathematical tables. 10th ed. New York: Dover Publications, 1972: 505.

[27] McKay M R, Grant A J, Collings I B. Performance analysis of MIMO-MRC in double-correlated Rayleigh environments. IEEE Transactions on Communications, 2007, 55(3): 497-507.

E-mail：hkxb@buaa.edu.cn

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主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

非对称衰落信道下无人机中继传输方案及性能分析

UAV Relay Transmission Scheme and Its Performance Analysis over Asymmetric Fading Channels

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