Analytical Approximate Solutions of Nonlinear Fractional-Order  Nonhomogeneous Differential Equations

Falade  K. Iyanda; Adesina  K. Adio; Nuru Muazu; Abdullahi  Muhammad

doi:10.24237/djes.2022.15310

Authors

Falade K. Iyanda
faladekazeem2013@gmail.com
Department of Mathematics, Faculty of Computing and Mathematical Sciences, Kano University of Science and Technology Wudil, P.M.B 3244, Kano State, Nigeria
Adesina K. Adio School of Science and Technology, Babcock University, Ilishan-Remo Nigeria
Nuru Muazu Department of Mathematics, Faculty of Computing and Mathematical Sciences, Kano University of Science and Technology Wudil, P.M.B 3244, Kano State, Nigeria
Abdullahi Muhammad Department of Mathematics, Faculty of Natural and Applied Sciences, Sule Lamido University, Kafin Hausa, Jigawa State Nigeria

Keywords:

Adomian decomposition algorithm MAPLE 18 software Nonlinear fractional differential equation Computational simulations

Abstract

Computational simulation of natural phenomenon is currently attracting increasing interest in applied mathematics and computational physics. Mathematical software for simulation is limited by the availability, speed, and parallelism of high-performance computing. To improve the performance and efficiency of some numerical techniques, a step-by-step approach to mathematical software coding is needed to build robust parameter-oriented problems. Therefore, this article aims to present and apply the Adomian decomposition algorithm coded by the MAPLE 18 software package for the solutions of nonlinear fractional-order differential equations in applied physics and engineering sciences. The present technique is used without linearization or slight disturbance of nonlinear terms, which confirms the strength, accuracy, and simplicity of the algorithm. The two test problems are considered for different initial conditions and the solutions obtained show that the Adomian decomposition algorithm is fast, easy, stable in good agreement with analytical techniques and that a good computational approach to fractional-order value problems arising in applied mathematics and engineering sciences.

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