A study of three variable analogues of certain fractional integral operators

Khan, Mumtaz Ahmad, Sharma, Bhagwat Swaroop

25 September 2017

The paper deals with a three variable analogues of certain fractional integral operators introduced by M. Saigo. Resides giving three variable analogues of earlier known fractional integral operators of one variable as a special cases of newly defined operators, the paper establishes certain results in the form of theorems including integration by parts.

Fractional Integral Operator

Gauss Hypergeometric Function

Weyl Fractional Integral

Fractional Calculus

The Numerical Solutions of Fractional Differential Equations with Fractional Taylor Vector

KrishnasamySaraswathy, Vidhya

12 August 2016

In this dissertation, a new numerical method for solving fractional calculus problems is presented. The method is based upon the fractional Taylor vector approximations. The operational matrix of the fractional integration for the fractional Taylor vector is introduced. This matrix is then utilized to reduce the solution of the fractional calculus problems to the solution of a system of algebraic equations. This method is used to solve fractional differential equations, Bagley-Torvik equations, fractional integro-differential equations, and fractional duffing problems. Illustrative examples are included to demonstrate the validity and applicability of this technique.

numerical solution

fractional differential equations

operational matrix

fractional integral operator

fractional derivative

fractional Taylor vector

A novel Chebyshev wavelet method for solving fractional-order optimal control problems

Ghanbari, Ghodsieh

13 May 2022

This thesis presents a numerical approach based on generalized fractional-order Chebyshev wavelets for solving fractional-order optimal control problems. The exact value of the Riemann– Liouville fractional integral operator of the generalized fractional-order Chebyshev wavelets is computed by applying the regularized beta function. We apply the given wavelets, the exact formula, and the collocation method to transform the studied problem into a new optimization problem. The convergence analysis of the proposed method is provided. The present method is extended for solving fractional-order, distributed-order, and variable-order optimal control problems. Illustrative examples are considered to show the advantage of this method in comparison with the existing methods in the literature.

Fractional-order Chebyshev wavelets

Numerical method

Beta function

Control Theory