Abstract
Green communication has become the main concern of many researchers according to the quick evolution of wireless communication applications. For this, in this correspondence we develop a cross-layer framework based on the joint association between Modulation and Coding Scheme together with truncated Selective Repeat Hybrid Automatic Repeat Request type I to examine the global energy consumption per bit of Multiband Orthogonal Frequency Division Multiplexing Ultra Wideband (MB-OFDM UWB) systems. Indeed, we examine a theoretical analysis based on throughput performance investigation when mode selection is performed which is dynamically selected following the Channel State Information. Next, we prove that cross-layer design outperforms the mode selection behavior in terms of outage probability. Then, based on the features of cross-layer MB-OFDM UWB (MB-UWB) design a theoretical framework is derived in terms of Packet Error Rate and overall energy expenditure per bit. Specifically, the closed form relation of energy per bit is determined by exploiting the proprieties of the two link adaptation tools. Correspondingly, since the purpose behind cross-layer design adoption into MB-UWB system is EE improvement, we have compared the impact of different M-QAM modulations into energy consumption per useful bit at various range of distances. The obtained results reveal that cross-layer design is a powerful solution in terms of EE enhancement.
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Bianzino, A., Chaudet, C., Rossi, D., & Rougier, J. (2012). A survey of green networking research. IEEE Communications Surveys, 14(1), 3–20.
FCC Document 00-163, Revision of Part 15 of the Commission’s Rules Regarding Ultra-Wideband Transmission Systems, April 22, 2002.
Molisch, A. F., Foerster, J. R. (2003). Channel Models for Ultrawideband Personal Area Networks. In IEEE Wireless Communications December 2003.
Batra, A., Balakrishnan, J., Aiello, R., Foerster, J., & Dabak, A. (2004). “Design of a multiband OFDM system for realistic UWB Channel Environments. IEEE Trans Microwave Theory, 52(12), 2123–2138.
High Rate Ultra Wideband PHY and MAC Standard, Ecma International Std. ECMA-368, Dec. 2005.
Alam, M. Yang, D. Huq, K. Saghezchi, F. Mumtaz, S. Rodriguez, J. (2015). Towards 5G: Context Aware Resource Allocation for Energy Saving. Journal of Signal Processing Systems Springer 2015.
Fei, Y., Zhang, P., & Zhao, Y. (2013). Energy-efficient cross-layer optimization for wireless sensor networks. Communication and Network, 5, 493–497.
Cui, S., Goldsmith, A. J., Bahai, A. (2003). Energy-constrained modulation optimization for coded systems. In IEEE Global Telecommunications Conference GLOBECOM ‘03, 2003.
Li, Y., Ozcan, G., Cenk Gursoy, M., Velipasalar, S. (2014). Energy Efficiency of Hybrid-ARQ Systems under QoS Constraints. In 48th Annual Conference on Information Sciences and Systems (CISS), 2014.
Su, W., Lee, S., Pados, D. A., & Matyjas, J. D. (2011). Optimal power assignment for minimizing the average total transmission power in hybrid-ARQ Rayleigh fading links. IEEE Transactions on Communications, 59(7), 1867–1877.
Chihi, H., Hamini, A., Bouallegue, R. (2015) Energy consumption performance results of multiband OFDM UWB systems. In IEEE IWCMC, Croitie August 2015.
Chihi, H., De Lacerda, R., & Bouallegue, R. (2015). Adaptive modulation and coding scheme for MB-OFDM UWB systems. Croitie: IEEE SoftCOM.
Liu, Q., Zhou, S., & Giannakis, G. B. (2004). Cross-layer combining of adaptive modulation and coding with truncated ARQ over wireless links. IEEE Transactions on Wireless Communications, 3(9), 1746–1754.
Wu, J., Wang, G., & Zheng, Y. R. (2014). Energy efficiency and spectral efficiency tradeoff in type-I ARQ systems. IEEE J. Selected Areas in communication, 32(2), 356–366.
To, D., Nguyen, H. X., Vien, Q.-T., & Huang, L.-K. (2015). Power allocation for HARQ-IR systems under QoS Constraints and Limited Feedback. IEEE Transactions On Wireless Communications, 14(3), 1581–1594.
Chaitanya, T. V. K., Le-Ngoc, T. (2015). Energy-efficient adaptive power allocation for incremental MIMO systems. IEEE Transactions on Vehicular Technology, 65(4), 2820–2827.
Chaitanya, T., & Larsson, E. (2013). Outage-optimal power allocation for hybrid ARQ with chase combining in i.i.d Rayleigh fading channels. IEEE Transactions on Communications, 61, 1835–1846.
Chen, J., Zhao, D., Wang, L. (2015). Self-sustained UWB sensing: A link and energy adaptive approach. Journal of Signal Processing Systems. doi:10.1007/s11265-015-1092-3.
Saleh, A., & Valenzuela, R. (1987). A Statistical Model for Indoor Multipath Propagation. IEEE Journal on Selected Areas in Communications, 5(2), 128–137.
Goldsmith, A., & Chua, S. G. (1998). Adaptive coded modulation for fading channels. IEEE Transactions on Communications, 46, 595–602.
Andrews, J. G., Ghosh, A., Muhamed, R. (2007). Fundamentals of WiMAX: Understanding Broadband Wireless Networking, 1st Edition 2007.
Caire, G., & Tuninetti, D. (2001). The throughput of hybrid-ARQ protocols for the Gaussian collision channel. IEEE Transactions on Informations Theory, 47(5), 1971–1988.
Viterbi, A. J., & Omura, J. K. (1979). Principles of digital communication and coding. New York: McGrow Hill.
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Chihi, H., Bouallegue, R. Energy Efficiency Investigation for the MB-OFDM UWB Cross-Layer Design. Wireless Pers Commun 97, 2439–2457 (2017). https://doi.org/10.1007/s11277-017-4616-2
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DOI: https://doi.org/10.1007/s11277-017-4616-2