Numerical Solution of Variable-Order Fractional Differential Equations Using Bernoulli Polynomials

TL;DR

This paper presents a novel Bernoulli polynomial-based numerical method for solving multiterm variable-order fractional differential equations, demonstrating high accuracy and efficiency through illustrative examples and comparisons with existing methods.

Contribution

The work introduces an operational matrix for variable-order fractional integration with Bernoulli polynomials, enabling efficient solutions for complex fractional differential equations.

Findings

High-accuracy solutions with few basis functions

Better results than existing methods in literature

Effective even when solutions are not infinitely differentiable

Abstract

We introduce a new numerical method, based on Bernoulli polynomials, for solving multiterm variable-order fractional differential equations. The variable-order fractional derivative was considered in the Caputo sense, while the Riemann--Liouville integral operator was used to give approximations for the unknown function and its variable-order derivatives. An operational matrix of variable-order fractional integration was introduced for the Bernoulli functions. By assuming that the solution of the problem is sufficiently smooth, we approximated a given order of its derivative using Bernoulli polynomials. Then, we used the introduced operational matrix to find some approximations for the unknown function and its derivatives. Using these approximations and some collocation points, the problem was reduced to the solution of a system of nonlinear algebraic equations. An error estimate is given for the approximate solution obtained by the proposed method. Finally, five illustrative examples were considered to demonstrate the applicability and high accuracy of the proposed technique, comparing our results with the ones obtained by existing methods in the literature and making clear the novelty of the work. The numerical results showed that the new method is efficient, giving high-accuracy approximate solutions even with a small number of basis functions and when the solution to the problem is not infinitely differentiable, providing better results and a smaller number of basis functions when compared to state-of-the-art methods.