On the Nonlinear $\Psi$-Hilfer Fractional Differential Equations

TL;DR

This paper studies nonlinear $\\Psi$-Hilfer fractional differential equations, establishing existence, uniqueness, and continuous dependence of solutions, and develops Picard iteration methods with error bounds for solving these equations.

Contribution

It introduces new existence and uniqueness results for nonlinear $\Psi$-Hilfer fractional equations and develops Picard iterative solutions with error estimates.

Findings

Proved existence and uniqueness of solutions in weighted function spaces.

Developed Picard iteration method with error bounds for nonlinear equations.

Derived explicit solution representations using Mittag-Leffler functions.

Abstract

We consider the nonlinear Cauchy problem for $ \Psi $- Hilfer fractional differential equations and investigate the existence, interval of existence and uniqueness of solution in the weighted space of functions. The continuous dependence of solutions on initial conditions is proved via Weissinger fixed point theorem. Picard's successive approximation method has been developed to solve nonlinear Cauchy problem for differential equations with $ \Psi $- Hilfer fractional derivative and an estimation have been obtained for the error bound. Further, by Picard's successive approximation, we derive the representation formula for the solution of linear Cauchy problem for $ \Psi $-Hilfer fractional differential equation with constant coefficient and variable coefficient in terms of Mittag-Leffler function and Generalized (Kilbas-Saigo) Mittag-Leffler function.