logo

SCIENCE CHINA Information Sciences, Volume 60, Issue 2: 022308(2017) https://doi.org/10.1007/s11432-016-5577-x

Antenna selection for two-way full duplex massive MIMO networks with amplify-and-forward relay

More info
  • ReceivedDec 16, 2015
  • AcceptedJan 21, 2016
  • PublishedOct 17, 2016

Abstract

In this paper, the antenna selection problem is investigated for the relaying system with the base station having massive multiple antennas, where the relay station works in the full duplex mode and the two-way protocol. The antenna selection scheme is optimized by maximizing the minimum of the two signal to noise ratios (SNRs) with each corresponding to the uplink and the downlink traffics. With the optimized antenna selection scheme, the approximate probability density function (PDF) of the received SNR for each receiver is derived. In what follows, both the overall outage probability and the bit error rate are obtained in the analytical expression for the whole massive multi-input multi-output (MIMO) system. Moreover, the asymptotic overall outage probability is derived in an analytical expression with respect to the growing number of the antennas on the massive MIMO base station. Numerical simulations verify the derived analytical results.


Funded by

National High-Tech R&D Program of China(863)

(2014AA01A704)

Research Project of Jiangsu Province of China(BE2015156)

National Key Project of Underwater Acoustic Communications(8904004739)

National Basic Research Program of China(973)

(2013CB336600)

National Natural Science Foundation of China(Grants Nos. 61372101)

National Natural Science Foundation of China(61422105)

National Natural Science Foundation of China(61271018)

National Natural Science Foundation of China(61201172)

National Natural Science Foundation of China(61221002)

Research Project of Jiangsu Province of China(BK20130019)


Acknowledgment

Acknowledgments

This work was supported by National High-Tech R&D Program of China (863) (Grant No. 2014AA01A704), National Basic Research Program of China (973) (Grant No. 2013CB336600), National Natural Science Foundation of China (Grants Nos. 61372101, 61422105, 61271018, 61201172, 61221002), Research Project of Jiangsu Province of China (Grant Nos. BK20130019, BE2015156), National Key Project of Underwater Acoustic Communications (Grant No. 8904004739).


References

[1] Huang Y M, Yang L X, Bengtsson M, et al. A limited feedback joint precoding for amplify-and-forward relaying. IEEE Trans Signal Process, 2010, 58: 1347-1357 CrossRef Google Scholar

[2] Lin M, An K, Ouyang J, et al. Effect of beamforming on multi-antenna two hop asymmetric fading channels with fixed gain relays. Prog Electromagn Res, 2013, 133: 367-390 CrossRef Google Scholar

[3] Xu W, Dong X D, Huang Y M. Asymptotic achievable rate analysis for selection strategies in amplify-and-forward MIMO two-hop networks with feedback. IEEE Trans Veh Technol, 2010, 59: 3662-3668 CrossRef Google Scholar

[4] Zhao R, Yang L X, Huang Y M. Performance analysis of network coding for multicast relay system over Nakagami-m fading channels. Sci China Inf Sci, 2011, 54: 2338-2348 CrossRef Google Scholar

[5] Huang Y M, He S W, Jin S, et al. Decentralized energy-efficient coordinated beamforming for multicell systems. IEEE Trans Veh Technol, 2014, 63: 4302-4314 CrossRef Google Scholar

[6] Yang A, Xing C W, Fei Z S, et al. Performance analysis for uplink massive MIMO systems with a large and random number of UEs. Sci China Inf Sci, 2016, 59: 1-9 Google Scholar

[7] Ni Y, Zhang W C, Chen M. Antenna subset selection in MU large-scale MIMO systems. In: Proceedings of IEEE Wireless Communications and Networking Conference (WCNC'2013), Shanghai, 2013. 1--4. Google Scholar

[8] Ahlswede R, Cai N, Li S Y, et al. Network information flow. IEEE Trans Inf Theory, 2000, 46: 1204-1216 CrossRef Google Scholar

[9] Dai M J, Wang P, Zhang S L, et al. Survey on cooperative strategies for wireless relay channels. Trans Emerg Telecommun Technol, 2014, 25: 926-942 CrossRef Google Scholar

[10] Popovski P, Yomo H. Physical network coding in two-way wireless relay channels. In: Proceedings of IEEE International Conference on Communications (ICC'2007), Glasgow, 2007. 707--712. Google Scholar

[11] Koike-Akino T, Popovski P, Tarokh V. Optimized constellations for two-way wireless relaying with physical network coding. IEEE J Sel Areas Commun, 2009, 27: 773-787 CrossRef Google Scholar

[12] Ji B F, Song K, Huang Y M, et al. A cooperative relay selection for two-way cooperative relay networks in Nakagami channels. Wirel Pers Commun, 2013, 71: 2045-2065 CrossRef Google Scholar

[13] Khina A, Kochman Y, Erez U. Physical-layer MIMO relaying. In: Proceedings of IEEE International Symposium on Information Theory (ISIT'2011), Saint-Petersburg, 2011. 2437--2441. Google Scholar

[14] Zhou X Y, Bai B, Chen W. A low complexity energy efficiency maximization method for multiuser amplify-and-forward MIMO relay systems with a holistic power model. IEEE Commun Lett, 2014, 18: 1371-1374 CrossRef Google Scholar

[15] Dai M J, Wang H, Lin X H, et al. Opportunistic relaying with analogue and digital network coding for two-way parallel relay network. IET Commun, 2014, 8: 2200-2206 CrossRef Google Scholar

[16] Kim J, Kim D. BER analysis of dual-hop amplify-and-forward MIMO relaying with best antenna selection in Rayleigh fading channels. IEICE Trans Commun, 2008, 91: 2772-2775 Google Scholar

[17] Peters S, Heath R. Nonregenerative MIMO relaying with optimal transmit antenna selection. IEEE Signal Process Lett, 2008, 15: 421-424 CrossRef Google Scholar

[18] Cao L, Zhang X, Wang Y W, et al. Transmit antenna selection strategy in amplify-and-forward MIMO relaying. In: Proceedings of IEEE Wireless Communications and Networking Conference (WCNC'2009), Budapest, 2009. 1--4. Google Scholar

[19] Yang K, Yang N, Xing C W, et al. Relay antenna selection in MIMO two-way relay networks over Nakagami-m fading channels. IEEE Trans Veh Technol, 2013, 63: 2349-2362 Google Scholar

[20] Dai M J, Sung C W, Wang Y. Distributed on-off power control for amplify-and-forward relays with orthogonal space-time block code. IEEE Trans Wirel Commun, 2011, 10: 1895-1903 CrossRef Google Scholar

[21] Zheng G, Krikidis I, Ottersten B. Full-duplex cooperative cognitive radio with transmit imperfections. IEEE Trans Wirel Commun, 2013, 12: 2498-2511 CrossRef Google Scholar

[22] Zhou M X, Cui H Y, Song L Y, et al. Transmit-receive antenna pair selection in full duplex systems. IEEE Wirel Commun Lett, 2014, 3: 34-37 CrossRef Google Scholar

[23] Cheng X L, Yu B, Cheng X, et al. Two-way full-duplex amplify-and-forward relaying. In: Proceedings of IEEE Military Communications Conference (MILCOM'2013), San Diego, 2013. 1--6. Google Scholar

[24] Yu B, Yang L Q, Cheng X, et al. Transmit power optimization for full duplex decode-and-forward relaying. In: Proceedings of IEEE Global Communications Conference (GLOBECOM'2013), Atlanta, 2013. 3347--3352. Google Scholar

[25] Yu B, Yang L Q, Cheng X, et al. Relay location optimization for full-duplex decode-and-forward relaying. In: Proceedings of IEEE Military Communications Conference (MILCOM'2013), San Diego, 2013. 13--18. Google Scholar

[26] Dai M J, Wan S C. Achieving high diversity and multiplexing gains in the asynchronous parallel relay network. Trans Emerg Telecommun Technol, 2013, 24: 232-243 CrossRef Google Scholar

[27] Suraweera H A, Krikidis I, Zheng G, et al. Low-complexity end-to-end performance optimization in MIMO full-duplex relay systems. IEEE Trans Wirel Commun, 2014, 13: 913-927 CrossRef Google Scholar

[28] Zheng G. Joint beamforming optimization and power control for full-duplex MIMO two-way relay channel. IEEE Trans Signal Process, 2015, 63: 555-566 CrossRef Google Scholar

[29] Xia X C, Xu K, Zhang D M, et al. Low-complexity transceiver design and antenna subset selection for cooperative half- and full-duplex relaying systems. In: Proceedings of IEEE Global Communications Conference (GLOBECOM'2014), Austin, 2014, 3314--3319. Google Scholar

[30] Song K, Ji B F, Huang Y M, et al. Performance analysis of antenna selection in two-way relay networks. IEEE Trans Signal Process, 2015, 63: 2520-2532 CrossRef Google Scholar

[31] Gradshte{\u\i}n I, Ryzhik I, Jeffrey A, et al, Table of Integrals, Series, and Products. New York: Academic, 2007. 334--371. Google Scholar

[32] Guo H, Ge J. Performance analysis of two-way opportunistic relaying over Nakagami-m fading channels. Electron Lett, 2011, 47: 150-152 CrossRef Google Scholar

[33] Simon M K, Alouini M S. Digital Communication over Fading Channels. New York: Wiley, 2005. 193--218. Google Scholar

Copyright 2020 Science China Press Co., Ltd. 《中国科学》杂志社有限责任公司 版权所有

京ICP备18024590号-1       京公网安备11010102003388号