Authors: Yao-Tien Wang, Hsiang-Fu Yu, Dung Chen Chiou

Abstract:

In wireless and mobile communications, this progress provides opportunities for introducing new standards and improving existing services. Supporting multimedia traffic with wireless networks quality of service (QoS). In this paper, a grey-fuzzy controller for radio resource management (GF-RRM) is presented to maximize the number of the served calls and QoS provision in wireless networks. In a wireless network, the call arrival rate, the call duration and the communication overhead between the base stations and the control center are vague and uncertain. In this paper, we develop a method to predict the cell load and to solve the RRM problem based on the GF-RRM, and support the present facility has been built on the application-level of the wireless networks. The GF-RRM exhibits the better adaptability, fault-tolerant capability and performance than other algorithms. Through simulations, we evaluate the blocking rate, update overhead, and channel acquisition delay time of the proposed method. The results demonstrate our algorithm has the lower blocking rate, less updated overhead, and shorter channel acquisition delay.

Keywords: radio resource management, grey prediction, fuzzylogic control, wireless networks, quality of service.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1085008

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1672

References:

[1] "http://www.3gpp.org", 2002.
[2] H. Holma and A. Toskala (eds.), WCDMA for UMTS. Wiley, 2000.
[3] 3rd Generation Partnership Project Technical Specification Group Radio Access Network. Working Group 1, "Physical Layer - Measurements." TS25.225 v4.0.0. 2001.
[4] 3rd Generation Partnership Project. Technical Specification Group. Radio Access Network "Radio Interface Protocol Architecture." TS25.301 v4.2.0. 202.
[5] 3rd Generation Partnership Project. Technical Specification Group. Radio Access Network "Radio Resource Control (RRC); Protocol Specification." TS25.331" 4.4.0, 2002.
[6] S. K. Das, S. K. Sen and R. Jayaram, A structured channel borrowing scheme for dynamic load balancing in cellular networks, IEEE Distributed Computing Systems Conference, pages 116-123, 1997.
[7] J. Kim, T. Lee, and C. S. Hwang, A dynamic channel assignment scheme with two thresholds for load balancing in cellular networks, IEEE Radio and Wireless Conference, pages 141-145, 1999.
[8] X. Dong and T. H. Lai, Distributed dynamic carrier allocations in mobile cellular networks: search vs. update, IEEE Distributed Computing Systems Conference, pages 108-115, 1997.
[9] T. Lee, J. Kim, and C. S. Hwang, A dynamic channel assignment scheme with two thresholds for load balancing in cellular networks, IEEE Radio and Wireless Conference, pages 141-145, 1999.
[10] H. Jiang and S. S. Rappaport, CBWL: a new channel assignment and sharing method for cellular communication systems, IEEE Transactions on Vehicular Technology, pages 313 -322, 1994.
[11] S. Kim and P. K. Varshney, Adaptive Load Balancing with Preemption for Multimedia Cellular Network, IEEE Wireless Communications and Networking Conference, pages 1680-1684, 2003.
[12] T. S. Yum and M. Zhang, Comparisons of channel-assignment strategies in cellular mobile telephone systems, IEEE Transactions on Vehicular Technology, pages 211-215, 1989.
[13] Y. -T. Wang and J.-P. Sheu, A Dynamic Channel Borrowing Approach with Fuzzy Logic Control in Distributed Cellular Networks, the special issue of Simulation Modeling Practice and Theory, Vol. 12, pages 287 - 303, 2004.
[14] Y. T. Wang, A Fuzzy-Based Dynamic Channel Borrowing Scheme for Wireless Cellular Networks, IEEE Vehicular Technology Conference, pages 1517-1521, 2003.
[15] L. A. Zadeh, Fuzzy Algorithm. Information and Control, pages 94-102, 1968.
[16] Y. Zhang, A new adaptive channel assignment algorithm in cellular mobile systems, IEEE Systems Sciences Conference, pages 1-7, 1999.
[17] J. S. Engel and M. Peritsky, Statistically-optimum dynamic sever assignment in systems with interfering severs, IEEE Vehicular Technology Conference, pages 1287-1293, 1973.
[18] H. Haas and S. McLaughlin, A novel decentralized DCA concept for a TDD network applicable for UMTS. IEEE Transactions on Vehicular Technology, pages 881-885, 2001.
[19] J. Karlsson and B. Eklundh, A cellular mobile telephone system with load sharing-an enhancement of directed retry, IEEE Transactions on Communications, pages 530-535, 1989.
[20] S. Mitra and S. DasBit, A load balancing strategy using dynamic channel assignment and channel borrowing in cellular mobile environment, IEEE Personal Wireless Communications Conference, pages 278-282, 2000.
[21] J. L. Deng , Control problem of grey systems, System and Control Letters, Vol. 1, pages 288-294, 1982.
[22] Ren C. Luo and Tse Min Chen , Autonomous Mobile Target Tracking System Based on Grey-Fuzzy Control Algorithm, IEEE Transactions on Industrial Electronics, VOL. 47, NO. 4, pages 920-931, 2000.
[23] C.-Y. Kung, K.-T. Hsu, T.-M. Yan and P.-W. Liu, An Application of the Grey Prediction Theory to the Annual Medical Expense of Taiwan-s National Health Insurance, Journal of Grey System, Vol. 9, No. 2, pages 75-86, 2006.
[24] W.-N. Pi and L.-C. Liou, Electric Power Demand Forecasting in Taiwan via Grey Prediction, Journal of Science and Engineering Technology, Vol. 3, No. 2, pages 11-18, 2007.
[25] Y.-T. Wang and K.-M. Hung "Fuzzy Logic Based Neural Network Model for Load Balancing in Wireless Networks. " KICS Communications Society, International Journal of Communications and Networks, Vol. 10, pp.38- 43, 2008.