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http://dx.doi.org/10.5762/KAIS.2011.12.7.3176

Transmission Rate Priority-based Traffic Control for Contents Streaming in Wireless Sensor Networks  

Lee, Chong-Deuk (Div. of Electronic Engineering, Chonbuk National University)
Publication Information
Journal of the Korea Academia-Industrial cooperation Society / v.12, no.7, 2011 , pp. 3176-3183 More about this Journal
Abstract
Traffic and congestion control in the wireless sensor network is an important parameter that decides the throughput and QoS (Quality of Service). This paper proposes a transmission rate priority-based traffic control scheme to serve digital contents streaming in wireless sensor networks. In this paper, priority for transmission rate decides on the real-time traffic and non-real-time with burst time and length. This transmission rate-based priority creates low latency and high reliability so that traffic can be efficiently controlled when needed. Traffic control in this paper performs the service differentiation via traffic detection process, traffic notification process and traffic adjustment. The simulation results show that the proposed scheme achieves improved performance in delay rate, packet loss rate and throughput compared with those of other existing CCF and WCA.
Keywords
Traffic; Wireless Sensor Network; Transmission Rate; Digital Contents;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
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1 Wang C., Sohraby K., Daneshmand M., Hu. Y., "Upstream congestion control in wireless sensor networks through cross-layer optimization," IEEE Journal on Selected Areas in Communications 25, Vol. 4, pp. 786-795, 2007.   DOI   ScienceOn
2 Wan C. Y., Eisanman S. B., Campbell A. T., "CODA: Congestion Detection and Avoidance in sensor networks," in: Proceedings of ACM Sensys'03, Los Angeles, CA, November 5-7, 2003.
3 C. D, Lee, " Transmission Rate-Based Overhead Monitoring for Multimedia Streaming Optimization in Wireless Networks," KONI, Vol. 14-3, pp. 358-366, June, 2010.
4 C. D, Lee, " Fuzzy Relevance-Based Clustering for Routing Performance Enhancement in Wireless Ad-Hoc Networks," KONI, Vol. 14-4, pp. 495-503, August, 2010.
5 C. D, Lee, T. W, Jeong, "Fuzzy filtering based segment grouping for user-centered multimedia streaming service in P2P distribution mobile networks," Journal of internet technology, Vol. 11-5, pp 651-658, 2010.
6 Villalba, L. J. G., Orozco, A. L. S., Cabrera, A. T., and Abbas, C. J. B. "Routing protocols in wireless sensor networks," Sensors, Vol. 9, pp. 8399-8421, 2009.   DOI
7 Islam, T. A., Manel, G. Z., Jamal, N. and Julian, M. P. "Wireless multimedia sensor networks: current trends and future directions." Sensors, Vol. 10, pp. 6662-6717, 2010.   DOI
8 Yaghmaee, M. H, and Adjeroh, D. A., "Priority-based rate control for service differentiation and congestion control in wireless multimedia sensor networks," Computer Networks, Vol. 53, pp. 1798-1811, 2009.   DOI
9 Dhurandher, S. K. and Singh, G. V., "Weighted-based adaptive clustering algorithm in mobile ad hoc networks," ICPWC'2005, pp.96-100, 2005.
10 Ee, C. T., Bajcsy R., "Congestion control and fairness for many-to one routing in sensor networks," in: Proceedings of ACM Sensys, November 2004.
11 Lyer Y. G., Gandham S., Nenkatesan S., "STCP: A generic transport layer protocol for wireless sensor networks," In: Proceedings of IEEE ICCCN 2005, San Diego, CA, October 17-19, 2005.   DOI
12 Hull B., Jamieson K., Balakrishnan H., "Mitigating congestion in wireless sensor networks," In: Proceedings of ACM Sensys'04, Baltimore, MD, November 3-5, 2004.