Mobile Sink Node with Discerning Motility Approach for Energy Efficient Delay Sensitive Data Communication over Wireless Sensor Body Area Networks
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Abstract
The sensors nearby the static sink drains their energy resources rapidly, since they continuously involve to build routes in Wireless sensor networks, which are between data sources and static sink. Hence, the sensors nearby the sink having limited lifespan, which axing the network lifetime.The mobile-sink strategy that allows the sink to move around the network area to distribute the transmission overhead to multiple sensor nodes. However, the mobile-sink strategy is often tall ordered practice due to the continuous need of establishing routes between source nodes and the mobile sink (MS) at new position occurred due to its random mobility. In regard to above stated argument, this manuscript proposed a novel energy data transmission strategy which is effective for WSN with mobile sink. Unlike the traditional contributions, which relies on mobile sink with random mobility strategies, the proposal defines a discerning path for mobile sink routing between sectioned clusters of the WSN. The proposal of the manuscript titled “Mobile Sink Node with Discerning Motility Approach (MSDMA) for Energy Efficient Data Communication over WBAN”. The method defined in proposed model sections the target network in to multiple geographical clusters and prioritize these clusters by the delay sensitivity of the data transmitted by the sensor nodes of the corresponding clusters. Further, discriminating these clusters by their delay sensitive priority to define mobile sink route. For estimation of the delay sensitive priority of the clusters, set of metrics are proposed. The experimental study carried on simulation to assess the significance of the suggested method. The performance improvement of the suggested method is ascended through comparative analysis performed against benchmark model under divergent metrics.
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References
Akyildiz, Ian F., et al. "A Survey on Sensor Networks." IEEE Communications Magazine (2002): 103.
Lu, Mingming, et al. "Energy-efficient connected coverage of discrete targets in wireless sensor networks." International Journal of Ad Hoc and Ubiquitous Computing 4.3/4 (2009): 137-147.
Z Zhao, Qun, and Mohan Gurusamy. "Lifetime Maximization for Connected Target Coverage in Wireless Sensor Networks." IEEE/ACM Transactions on Networking 16.6 (2008): 1378-1391.
Pyun, Sung-Yeop, and Dong-Ho Cho. "Power-saving scheduling for multiple-target coverage in wireless sensor networks." IEEE Communications Letters 2.13 (2009): 130-132.
aliJamali, Mohammad, et al. "An energy-efficient algorithm for connected target coverage problem in wireless sensor networks." Computer Science and Information Technology (ICCSIT), 2010 3rd IEEE International Conference on. Vol. 9. IEEE, 2010.
Garg, P. ., Sharma, N. ., Sonal, & Shukla, B. . (2023). Predicting the Risk of Cardiovascular Diseases using Machine Learning Techniques. International Journal of Intelligent Systems and Applications in Engineering, 11(2s), 165 –. Retrieved from https://ijisae.org/index.php/IJISAE/article/view/2520
Pujari, Arun K. "High-Energy-First (HEF) Heuristic for Energy-Efficient Target Coverage Problem." arXiv preprint arXiv:1103.4769 (2011).
Gil, Joon-Min, and Youn-Hee Han. "A Target Coverage Scheduling Scheme Based on Genetic Algorithms in Directional Sensor Networks." Sensors 11.2 (2011): 1888-1906.
Tan, Rui, et al. "Exploiting Reactive Mobility for Collaborative Target Detection in Wireless Sensor Networks." IEEE Transactions on Mobile Computing 3.9 (2010): 317-332.
He, Jing, et al. "A Reliable Energy Efficient Algorithm for Target Coverage in Wireless Sensor Networks." 2010 IEEE 30th International Conference on Distributed Computing Systems Workshops. IEEE, 2010.
Zhang, Honghai, and Jennifer C. Hou. "Maintaining sensing coverage and connectivity in large sensor networks." Ad Hoc & Sensor Wireless Networks 1.1-2 (2005): 89-124.
Xiangning, Fan, and Song Yulin. "Improvement on LEACH Protocol of Wireless Sensor Network." Proceedings of the 2007 International Conference on Sensor Technologies and Applications. IEEE Computer Society, 2007.
Allen, I. Elaine, and Christopher A. Seaman. "Likert scales and data analyses." Quality progress 40.7 (2007): 64.
Hamida, Elyes Ben, and Guillaume Chelius. "A Line-Based Data Dissemination protocol for Wireless Sensor Networks with Mobile Sink." IEEE International Conference on Communications (ICC 2008). 2008.
Shin, Jeong-Hun, et al. "Railroad: virtual infrastructure for data dissemination in wireless sensor networks." Proceedings of the 2nd ACM international workshop on Performance evaluation of wireless ad hoc, sensor, and ubiquitous networks. ACM, 2005.
Tunca, Can, et al. "Ring Routing: An Energy-Efficient Routing Protocol for Wireless Sensor Networks with a Mobile Sink." IEEE Transactions on Mobile Computing 9.14 (2015): 1947-1960.