Exploring Stability and Chaos in the Fractional-Order Arneodo System via Grünwald–Letnikov Scheme
Mohamed Elbadri, Manahil A. M. Ashmaig, Abdelgabar Adam Hassan, Walid Hdidi, Hussein Zaky. Barakat, Ghozail Sh. Al-Mutairi, Mohamed A. Abdoon
Abstract
This paper investigates the dynamical properties of the fractional-order Arneodo system using a Grünwald–Letnikov-based numerical discretization. Fractional-order operators introduce memory and hereditary effects, enabling a more realistic description than classical integer-order models. The local stability of equilibrium points is examined through eigenvalue analysis of the Jacobian matrix, along with dissipativity conditions and the emergence of complex attractors. A comprehensive dynamical investigation is presented through phase portraits, time series, Lyapunov exponents, and bifurcation diagrams for varying fractional orders. Numerical findings demonstrate the emergence of new chaotic and hyperchaotic attractors. The results confirm that the fractional order strongly influences the system’s stability, sensitivity, and complexity. Our results confirm the relevance of fractional-order modeling in applications, such as secure communication, random number generation, and complex system analysis.