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Wireless Networks

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01-11-2015

Symbol-error rate optimized complex field network coding for wireless communications

Authors: Kayhan Eritmen, Mehmet Keskinoz

Published in: Wireless Networks | Issue 8/2015

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Abstract

In this paper, the complex field network coding (CFNC) over multi-user relay channel with non-orthogonal communications is studied. In order to improve the performance of CFNC coded relay channel, we propose to optimize the CFNC according to the symbol-error rate (SER) characteristics of the network. To achieve such an optimization, we first derive a bound for the SER of the coded relay channel, which uses maximum-likelihood detection both at the relay and destination node. Then, CFNC optimization is formulated as a convex program, which aims to minimize the SER-bound while considering the constraint on total transmit power and the network geometry. We next derive Karush–Kuhn–Tucker (KKT) conditions of optimal CFNC parameters. Due to the existence of nonlinearity in the simplified KKT conditions, a closed form solution for the optimal parameters is not possible. To overcome this difficulty, we also propose an approximate solution for the optimal CFNC, which utilizes an information theoretical result. After the SER-optimized CFNC parameters are determined, we investigate the average bit error rate (BER) of the network for various parameters. The performed numerical experiments reveal that SER-optimized CFNC could provide a BER improvement up-to 29 % over the conventional CFNC for a two-user relay channel.

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Wang, X., Vasilakos, A. V., Chen, M., Liu, Y., & Kwon, T. T. (2012). A survey of green mobile networks: Opportunities and challenges. Mobile Networks and Applications, 17(1), 4–20.CrossRef

Xu, Z., Qin, W., Tang, Q., & Jiang, D. (2014). Energy-efficient cognitive access approach to convergence communications. Science China Information Sciences, 57(4), 1–12.CrossRef

Vergara, E. J., Sanjuan, J., & Nadjm-Tehrani, S. (2013). Kernel level energy-efficient 3G background traffic shaper for android smartphones. In Proceedings of IEEE 9th international wireless communications and mobile computing conference (IWCMC’13), (pp. 443–449).

Jiang, D., Wang, X., Guo, L., Ni, H., & Chen, Z. (2011). Accurate estimation of large-scale IP traffic matrix. AEU-International Journal of Electronics and Communications, 65(1), 75–86.CrossRef

Cover, T. M., & Gamal, A. E. (1979). Capacity theorems for the relay channel. IEEE Transactions on Information Theory, 25(5), 572–584.CrossRefMATH

Ahlswede, R., Cai, N., Li, S. Y. R., & Yeung, R. W. (2000). Network information flow. IEEE Transactions on Information Theory, 46(4), 1204–1216.MathSciNetCrossRefMATH

Chen, Y., Kishore, S., & Li, J. (2006). Wireless diversity through network coding. In Proceedings of the wireless communications and networking conference, Vol. 3, (pp. 1681–1686).

Katti, S., Rahul, H., Hu, W., Katabi, D., M´edard, M., & Crowcroft, J. (2006) XORs in the air: Practical wireless network coding. In Proceedings of the ACM SIGCOMM, (pp. 243–254).

Li, S. Y. R., Yeung, R. W., & Cai, N. (2003). Linear network coding. IEEE Transactions on Information Theory, 49(2), 371–381.MathSciNetCrossRefMATH

10.

Zhang, S., & Liew, S. C. (2009). Channel coding and decoding in a relay system operated with physical layer network coding. IEEE Journal on Selected Areas in Communications, 27(5), 788–796.CrossRef

11.

Zhang, S., & Liew, S. C., & Lam, P. P. (2006) Hot topic: Physical layer network coding for the two-way relay channels. In Proceedings of the 12th MobiCom, (pp. 358–365).

12.

Wang, T., & Giannakis, G. B. (2008). Complex field network coding for multiuser cooperative communications. IEEE Journal of Selected Areas in Communications, 26(3), 561–571.MathSciNetCrossRef

13.

Guo, Z., Wang, B., Xie, P., Zeng, W., & Cui, J. (2009). Efficient error recovery with network coding in underwater sensor networks. Ad Hoc Networks, 7(4), 791–802.CrossRef

14.

Bhat, U., & Duman, T. M. (2012). Decoding strategies at the relay with physical-layer network coding. IEEE Transactions on Wireless Communications, 11(12), 4503–4513.CrossRef

15.

Liew, S. C., Zhang, S., & Lu, L. (2013). Physical-layer network coding: Tutorial, survey, and beyond. Physical Communication, 6, 4–42.CrossRef

16.

Lu, L., Wang, T., Liew, S. C., & Zhang, S. (2013). Implementation of physical-layer network coding. Physical Communication, 6, 74–87.CrossRef

17.

Akino, T. K., Popovski, P., & Tarokh, V. (2009). Optimized constellations for two-way wireless relaying with physical network coding. IEEE Journal of Selected Areas in Communications, 27(5), 773–787.CrossRef

18.

Zaidi, A. A., Khormuji, M. N., Yao, S., & Skoglund, M. (2009). Optimized analog network coding strategies for the white Gaussian multiple-access relay channel. IEEE ITW, (pp. 460–464).

19.

Wang, S., Song, Q., Wang, X., & Jamalipour, A. (2011). Rate and power Adaptation for analog network coding. IEEE Transactions on Vehicular Technology, 60(5), 2302–2313.CrossRef

20.

Proakis, J. G. (2001). Digital communications (4th ed.). New York: McGraw-Hill.

21.

Nocedal, J., & Wright, J. (2006). Numerical optimization (2nd ed.). Berlin: Springer.MATH

Title: Symbol-error rate optimized complex field network coding for wireless communications
Authors: Kayhan Eritmen
Mehmet Keskinoz
Publication date: 01-11-2015
Publisher: Springer US
Published in: Wireless Networks / Issue 8/2015
Print ISSN: 1022-0038
Electronic ISSN: 1572-8196
DOI: https://doi.org/10.1007/s11276-015-0924-1

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