Abstract
We propose a distributed and transmission power efficient fault-tolerant topology management technique, known as transmission power efficient disjoint path (TEDP), designed for nonhomogeneous wireless sensor networks (WSNs). A nonhomogeneous WSN is consisting of a substantially large count of energy-constrained and low-computational capability low-cost sensors and a small number of resource-extensive sensors with unrestrained battery power. The aim of our proposed algorithm is to designate every sensor node’s communication range in order to ensure that every sensor node establishes k-vertex disjoint connectivity with resource-extensive nodes, and the overall transmission power utilization in the network is substantially minimized. With the employment of TEDP algorithm, the induced topologies can tolerate k − 1 node failures in the worst case. The experimental outcomes demonstrate that in contrast to existing solutions our algorithm attains the decline in overall transmission power substantially by 25% and the decline in utmost transmission power needed in a sensor node by 30%.
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Nayak, M.R., Tripathy, G., Rath, A.K. (2018). A Distributed Transmission Power Efficient Fault-Tolerant Topology Management Mechanism for Nonhomogeneous Wireless Sensor Network. In: Saeed, K., Chaki, N., Pati, B., Bakshi, S., Mohapatra, D. (eds) Progress in Advanced Computing and Intelligent Engineering. Advances in Intelligent Systems and Computing, vol 563. Springer, Singapore. https://doi.org/10.1007/978-981-10-6872-0_45
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DOI: https://doi.org/10.1007/978-981-10-6872-0_45
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