Journal of Soft Computing Paradigm
IRO Journals
Volume 3 — Issue 1 — March 2021

Wireless Rechargeable Sensor Network Fault Modeling and Stability Analysis

https://doi.org/10.36548/jscp.2021.1.006
S. R. Mugunthan
Associate Professor, Department of Computer Science and Engineering, Sriindu college of Engineering and Technology, Sheriguda, Hyderabad, India
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Mugunthan, S. R. 2021. “Wireless Rechargeable Sensor Network Fault Modeling and Stability Analysis”. Journal of Soft Computing Paradigm 3 (1): 47-54. https://doi.org/10.36548/jscp.2021.1.006.
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Keywords

— Stability analysis
— wireless rechargeable sensor networks
— homogenous network
— epidemic modeling
— low-energy
Published: 23-04-2021

Abstract

Wide attention has been acquired by the field of wireless rechargeable sensor networks (WRSNs ) across the globe due to its rapid developments. Addressing the security issues in the WRSNs is a crucial task. The process of reinfection, charging and removal in WRSN is performed with a low-energy infected susceptible epidemic model presented in this paper. A basic reproductive value is attained after which the epidemic equilibrium and disease-free points of global and local stabilities are simulated and analyzed. Relationship between the reproductive value and rate of charging as well as the stability is a unique characteristic exhibited by the proposed model observed from the simulations. The WRSN and malware are built with ideal attack-defense strategies. When the reproductive value is not equal to one, the accumulated cost and non-optimal control group are compared in the sensor node evolution and the optimal strategies are validated and verified.

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