Abstract
The well-known central finite difference approximation was combined with the trapezoid quadrature method in this study to provide a numerical solution of the linear system of Volterra integro-fractional differential equations (LSVI-FDEs) of arbitrary orders, where the fractional derivative is described in the Caputo sense and the orders are between zero and one. The method works by first using the central finite difference approximation to approximate the Caputo derivative at any fixed point and then using the trapezoidal rule to obtain a finite difference expression for our fractional equation, while recalling the linear spline approximation for the first steps. This new, more efficient method involves converting sets of equations and conditions into matrix relationships, from which symmetry matrices can be created in some cases. We also present a new approach for error analysis of the discrete numerical scheme and the explicit numerical technique for LSVI-FDEs. The multi-level explicit finite difference approximation’s stability and convergence were explored, and a MatLab application was created to explain the results. Finally, several numerical examples are offered to demonstrate the technique’s application.
Highlights
Fractional calculus (FC) is one of the most important branches of mathematics that deals with arbitrary order integrals and derivatives
With the aid of linear classic spline approximation (LSA) are described here. Their findings were achieved by running programs created for this purpose in MatLab using the ASVIFT-C
This paper presents an improved, new numerical scheme for approximating the solution of LSVI-FDEs with constant coefficients including trapezoidal rules using a central finite difference approach (CFDA) for a Caputo derivative sense
Summary
Fractional calculus (FC) is one of the most important branches of mathematics that deals with arbitrary order integrals and derivatives. The concept of FC has been efficaciously investigated to focus on various problems in physics, signal-processing, engineering, bio-science, and different fields in recent years. Theory, control theory, electromagnetic theory, facts, optics, capacity theory, diffusion, and viscoelasticity are just a few of the real-world applications of fractional calculus (see, for instance, [1–8]). Mathematical modeling transforms many applied problems into a set of fractional differential and integral equations [8–10]. Al-Nasir [11] used quadrature methods to solve Volterra integral equations of the second kind. Al-Rawi [12] used it to solve the first kind of integral equations of the convolution type. Saadati and Shakeri [13] used the trapezoidal rule to solve linear IDEs
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