Modeling and Analysis for Effective Capacity of a Cross-Layer Optimized Wireless Networks

Reham A. El-mayet; Hesham M. El-Badawy; Salwa H. Elramly

Open Science Index

Commenced in January 2007

Frequency: Monthly

Edition: International

Publications Count: 30526

5836

Modeling and Analysis for Effective Capacity of a Cross-Layer Optimized Wireless Networks

Authors:

Reham A. El-mayet, Hesham M. El-Badawy, Salwa H. Elramly

Abstract:

New generation mobile communication networks have the ability of supporting triple play. In order that, Orthogonal Frequency Division Multiplexing (OFDM) access techniques have been chosen to enlarge the system ability for high data rates networks. Many of cross-layer modeling and optimization schemes for Quality of Service (QoS) and capacity of downlink multiuser OFDM system were proposed. In this paper, the Maximum Weighted Capacity (MWC) based resource allocation at the Physical (PHY) layer is used. This resource allocation scheme provides a much better QoS than the previous resource allocation schemes, while maintaining the highest or nearly highest capacity and costing similar complexity. In addition, the Delay Satisfaction (DS) scheduling at the Medium Access Control (MAC) layer, which allows more than one connection to be served in each slot is used. This scheduling technique is more efficient than conventional scheduling to investigate both of the number of users as well as the number of subcarriers against system capacity. The system will be optimized for different operational environments: the outdoor deployment scenarios as well as the indoor deployment scenarios are investigated and also for different channel models. In addition, effective capacity approach [1] is used not only for providing QoS for different mobile users, but also to increase the total wireless network's throughput.

Keywords:

Cross-layer, effective capacity, LTE, OFDM, QoS, resource allocation, wireless networks.

Digital Object Identifier (DOI):

doi.org/10.5281/zenodo.10.5281/zenodo.1061786

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO690 PDF

1448

downloads

References:

[1] D. Wu and R. Negi, "Effective capacity: a wireless link model for support of quality of service", IEEE Transactions on Wireless Communications, vol. 2, no.4, pp. 630-643, July 2003.
[2] Nan Zhou, Xu Zhu and Yi Huang, "Cross-Layer Optimization with Guaranteed QoS for Wireless Multiuser OFDM Systems," Personal, Indoor and Mobile Radio Communications, IEEE 18th International Symposium PIMRC'07, Athens, pp. 1-5, Sept. 2007.
[3] Nan Zhou, Xu Zhu, Yi Huang and Hai Lin, "Novel Batch Dependant Cross-Layer scheduling for multiuser OFDM systems," IEEE International conference ICC'2008, Beijing, pp.3878~3882, May 2008.
[4] Dzmitry Kliazovich, Michael Devetsikiotis and Fabrizio Granelli, "Formal methods in cross layer modeling and optimization of wireless networks: state of the art and future directions," Handbook of Research on Heterogeneous Next Generation Networking: Innovations and Platforms, IGI global, pp1~24, 2009.
[5] Jia Tang, Xi Zhang, "Cross-Layer-Model Based Adaptive Resource Allocation for Statistical QoS Guarantees in Mobile Wireless Networks," IEEE Transactions on Wireless Communications, vol. 7, no. 6, pp. 2318-2328, June 2008.
[6] J. Tang and X. Zhang, "Cross-Layer Resource Allocation Over Wireless Relay Networks for Quality of Service Provisioning," IEEE J. Sel. Areas Communications, vol. 25, no. 4, pp. 645-657, May 2007.
[7] A. Balasubramanian and Scott L. Miller, "The Effective Capacity of a time Division Downlink Scheduling System," IEEE Transactions on Communications, vol. 58, no. 1, January 2010.
[8] Z. Shen, J. G. Andrews, and B. L. Evans, "Adaptive Resource Allocation in Multiuser OFDM Systems with Proportional Rate Constraints," IEEE Transactions on Wireless Communications, vol.4, pp 2726-2737, 2005.
[9] Andrea Goldsmith, Wireless Communications, Cambridge University, 2005.
[10] Qing Wang, Dapeng Wu and Pingyi Fan, "Effective Capacity of a correlated Nakagami-m Fading Channel," Wireless communications and mobile computing, John Wiley, Feb. 2011.
[11] Gaofei Huang, Guanchi Zhang and Hui Zheng , "QoS-driven resource allocation scheme for the OFDM amplify-and-forward relay system," Wireless Communications, Networking and Mobile Computing (WiCOM), Wuhan, pp. 3878-3882, Sept. 2011.
[12] T. M. Cover and J. A. Thomas, Elements of Information Theory. New York: Wiley, 1991.
[13] V.Erceg, K. V. S. Hari, "Channel Models for Fixed Wireless /networks," Technical Report, IEEE 802.16 Broadband Wireless Access Working Group, January 2001.
[14] "3GPP Long Term Evolution: System Overview, Product Development and Test Challenges," Agilent Technology, available on: http://cp.literature.agilent.com/litweb/pdf/5989-8139EN.pdf, June 2009.
[15] " 3G LTE Tutorial - 3GPP Long Term Evolution," Radio-Electronics, available on: http://www.radioelectronics. com/info/cellulartelecomms/lte-long-term-evolution/3g-ltebasics. php
[16] Nan Zhou, Xu Zhu, Yi Huang and Hai Lin, "Low Complexity Cross- Layer Design with Packet Dependent Scheduling for Heterogeneous Traffic in Multiuser OFDM Systems," IEEE Transactions on Wireless Communications, vol.9, no.6, pp.1912~1923, 2010.

Vol:14 No:07 2020 Vol:14 No:06 2020 Vol:14 No:05 2020 Vol:14 No:04 2020 Vol:14 No:03 2020 Vol:14 No:02 2020 Vol:14 No:01 2020
Vol:13 No:12 2019 Vol:13 No:11 2019 Vol:13 No:10 2019 Vol:13 No:09 2019 Vol:13 No:08 2019 Vol:13 No:07 2019 Vol:13 No:06 2019 Vol:13 No:05 2019 Vol:13 No:04 2019 Vol:13 No:03 2019 Vol:13 No:02 2019 Vol:13 No:01 2019
Vol:12 No:12 2018 Vol:12 No:11 2018 Vol:12 No:10 2018 Vol:12 No:09 2018 Vol:12 No:08 2018 Vol:12 No:07 2018 Vol:12 No:06 2018 Vol:12 No:05 2018 Vol:12 No:04 2018 Vol:12 No:03 2018 Vol:12 No:02 2018 Vol:12 No:01 2018
Vol:11 No:12 2017 Vol:11 No:11 2017 Vol:11 No:10 2017 Vol:11 No:09 2017 Vol:11 No:08 2017 Vol:11 No:07 2017 Vol:11 No:06 2017 Vol:11 No:05 2017 Vol:11 No:04 2017 Vol:11 No:03 2017 Vol:11 No:02 2017 Vol:11 No:01 2017
Vol:10 No:12 2016 Vol:10 No:11 2016 Vol:10 No:10 2016 Vol:10 No:09 2016 Vol:10 No:08 2016 Vol:10 No:07 2016 Vol:10 No:06 2016 Vol:10 No:05 2016 Vol:10 No:04 2016 Vol:10 No:03 2016 Vol:10 No:02 2016 Vol:10 No:01 2016
Vol:9 No:12 2015 Vol:9 No:11 2015 Vol:9 No:10 2015 Vol:9 No:09 2015 Vol:9 No:08 2015 Vol:9 No:07 2015 Vol:9 No:06 2015 Vol:9 No:05 2015 Vol:9 No:04 2015 Vol:9 No:03 2015 Vol:9 No:02 2015 Vol:9 No:01 2015
Vol:8 No:12 2014 Vol:8 No:11 2014 Vol:8 No:10 2014 Vol:8 No:09 2014 Vol:8 No:08 2014 Vol:8 No:07 2014 Vol:8 No:06 2014 Vol:8 No:05 2014 Vol:8 No:04 2014 Vol:8 No:03 2014 Vol:8 No:02 2014 Vol:8 No:01 2014
Vol:7 No:12 2013 Vol:7 No:11 2013 Vol:7 No:10 2013 Vol:7 No:09 2013 Vol:7 No:08 2013 Vol:7 No:07 2013 Vol:7 No:06 2013 Vol:7 No:05 2013 Vol:7 No:04 2013 Vol:7 No:03 2013 Vol:7 No:02 2013 Vol:7 No:01 2013
Vol:6 No:12 2012 Vol:6 No:11 2012 Vol:6 No:10 2012 Vol:6 No:09 2012 Vol:6 No:08 2012 Vol:6 No:07 2012 Vol:6 No:06 2012 Vol:6 No:05 2012 Vol:6 No:04 2012 Vol:6 No:03 2012 Vol:6 No:02 2012 Vol:6 No:01 2012
Vol:5 No:12 2011 Vol:5 No:11 2011 Vol:5 No:10 2011 Vol:5 No:09 2011 Vol:5 No:08 2011 Vol:5 No:07 2011 Vol:5 No:06 2011 Vol:5 No:05 2011 Vol:5 No:04 2011 Vol:5 No:03 2011 Vol:5 No:02 2011 Vol:5 No:01 2011
Vol:4 No:12 2010 Vol:4 No:11 2010 Vol:4 No:10 2010 Vol:4 No:09 2010 Vol:4 No:08 2010 Vol:4 No:07 2010 Vol:4 No:06 2010 Vol:4 No:05 2010 Vol:4 No:04 2010 Vol:4 No:03 2010 Vol:4 No:02 2010 Vol:4 No:01 2010
Vol:3 No:12 2009 Vol:3 No:11 2009 Vol:3 No:10 2009 Vol:3 No:09 2009 Vol:3 No:08 2009 Vol:3 No:07 2009 Vol:3 No:06 2009 Vol:3 No:05 2009 Vol:3 No:04 2009 Vol:3 No:03 2009 Vol:3 No:02 2009 Vol:3 No:01 2009
Vol:2 No:12 2008 Vol:2 No:11 2008 Vol:2 No:10 2008 Vol:2 No:09 2008 Vol:2 No:08 2008 Vol:2 No:07 2008 Vol:2 No:06 2008 Vol:2 No:05 2008 Vol:2 No:04 2008 Vol:2 No:03 2008 Vol:2 No:02 2008 Vol:2 No:01 2008
Vol:1 No:12 2007 Vol:1 No:11 2007 Vol:1 No:10 2007 Vol:1 No:09 2007 Vol:1 No:08 2007 Vol:1 No:07 2007 Vol:1 No:06 2007 Vol:1 No:05 2007 Vol:1 No:04 2007 Vol:1 No:03 2007 Vol:1 No:02 2007 Vol:1 No:01 2007