Controlling worm propagation in wireless sensor networks: Through fractal-fractional mathematical perspectives.
Mian Imad Shah, Eltigani Ismail Hassan, Amjad Ali, Abdulghani Muhyi, Waleed Eltayeb Ahmed, Khaled Aldwoah
Abstract
Open AccessWireless Sensor Networks (WSNs) are particularly vulnerable to malware attacks due to their limited processing power, memory, and energy, which makes defending against such threats especially challenging. To mitigate these serious security issues caused by malware infection, various preventive measures can be implemented, such as honeypots, robust security protocols, hardware-based protections, regular updates, firewalls, and intrusion detection systems (IDS). Considering these security concerns, we adopt an advanced version of the existing susceptible-infectious-protected-recovered SIPR model that incorporates a fractional-fractal derivative (FFD) defined in the Atangana-Baleanu-Caputo (ABC) sense, which offers a more realistic representation than the classical model. Furthermore, this research work introduced a new isolated nodes compartment [Formula: see text], along with parameters [Formula: see text] and [Formula: see text], defining the recovery and isolation rates of [Formula: see text], respectively, in the existing SIPR model. Moreover, this study focuses on the existence and uniqueness of solutions, stability analysis, control theory and numerical approximation for the proposed generalized susceptible-infectious isolated-protected-recovered [Formula: see text] model. Additionally, nonlinear and fixed-point theory are used to obtain the results of existence and stability analysis. On the same line, Newton polynomial-based numerical scheme was established for the proposed modified model. The dynamics of desired results are visualized using MATLAB.