Dynamic Behaviors of Wireless Sensor Networks Infected by Virus with Latency Delay

doi:10.23940/ijpe.19.03.p1.719731

Int J Performability Eng ›› 2019, Vol. 15 ›› Issue (3): 719-731.doi: 10.23940/ijpe.19.03.p1.719731

Dynamic Behaviors of Wireless Sensor Networks Infected by Virus with Latency Delay

Xiaopan Zhang^a, Lingyun Yuan^{a, b, *}, Jianhou Gan^b, and Cong Li^a

a School of Information Science and Technology, Yunnan Normal University, Kunming, 650500, China;
b Key Laboratory of Educational Information for Nationalities, Ministry of Education, Yunnan Normal University, Kunming, 650500, China

Submitted on ; Revised on ;
Contact: blues520@sina.com
About author:Xiaopan Zhang is currently pursuing a Master's degree in the School of Information Science and Technology at Yunnan Normal University. His current research interests include Internet of things and wireless sensor networks.Lingyun Yuan received her Ph.D. from the Shenyang Institute of Automation at the Chinese Academy of Sciences. She is currently a professor in the School of Information Science and Technology at Yunnan Normal University. Her research interests include Internet of things and wireless sensor networks.Jianhou Gan received his Ph.D. from Kunming University of Science and Technology. He is currently a professor in the Key Laboratory of Educational Information for Nationalities in the Ministry of Education at Yunnan Normal University. His research interests include artificial intelligence and knowledge engineering.Cong Li is currently pursuing a Master's degree in the School of Information Science and Technology at Yunnan Normal University. His research interests include Internet of things and wireless sensor networks.

Abstract

Abstract: Oscillatory behavior is a ubiquitous phenomenon in various physical and biological processes. Recently, it has been reported that oscillations of wireless sensor networks infected by virus (WSNIVs) can potentially be deleterious to the security strength of systems and may even cause network congestion and paralysis. Moreover, it has been discovered that latency delays are essential for the function of WSNIVs and can drive instability and periodic oscillations, enhance complexity, and even lead to multistability and chaotic motion. However, the precise roles of such delay during the regulation process are still not completely understood. Here, the primary objective of this paper is to study oscillatory behaviors of WSNIVs with latency delay. In particular, the sufficient conditions for local stability and existence with Hopf bifurcation are obtained. Moreover, we further discuss the properties of Hopf bifurcation by using the normal form and the center manifold theorem. The obtained results show that the latency delay can drive the WSNIVs to be oscillatory even when the network is at a stable state, suggesting that such delay might be a potential hazard to the security of wireless sensor systems. Our findings highlight the importance of considering delays when developing safer and more effective wireless sensor networks. Finally, we test and analyze the above research results through numerical calculation with Matlab and simulation experiments with OPNET, and the conclusions are verified to be correct and effective in experiments.

Key words: wireless sensor networks, virus, time delay, Hopf bifurcation, LEACH

Xiaopan Zhang, Lingyun Yuan, Jianhou Gan, and Cong Li. Dynamic Behaviors of Wireless Sensor Networks Infected by Virus with Latency Delay [J]. Int J Performability Eng, 2019, 15(3): 719-731.

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Dynamic Behaviors of Wireless Sensor Networks Infected by Virus with Latency Delay

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