Study of a Generalized Nonlinear Euler-Poisson-Darboux System: Numerical and Bessel Based Solutions

Authors

Chteoui Riadh Laboratory of Algebra, Number Theory and Nonlinear Analysis LR15ES18, Department of Mathematics, Faculty of Sciences, 5019 Monastir. Tunisia
Arfaoui Sabrine Laboratory of Algebra, Number Theory and Nonlinear Analysis LR15ES18, Department of Mathematics, Faculty of Sciences, 5019 Monastir. Tunisia
Ben Mabrouk Anouar Département de Mathématiques, Institut Supérieur de Mathámatiques Appliquées et Informatique de Kairouan, Avenue Assad Ibn Al-Fourat, Kairouan 3100, Tunisia

DOI:

https://doi.org/10.4208/jpde.v33.n4.2

Keywords:

Finite difference method, Lyapunov-Sylvester operators, generalized Euler-Poisson-Darboux equation, hyperbolic equation, Lauricella hypergeometric functions.

Abstract

In this paper a nonlinear Euler-Poisson-Darboux system is considered. In a first part, we proved the genericity of the hypergeometric functions in the development of exact solutions for such a system in some special cases leading to Bessel type differential equations. Next, a finite difference scheme in two-dimensional case has been developed. The continuous system is transformed into an algebraic quasi linear discrete one leading to generalized Lyapunov-Sylvester operators. The discrete algebraic system is proved to be uniquely solvable, stable and convergent based on Lyapunov criterion of stability and Lax-Richtmyer equivalence theorem for the convergence. A numerical example has been provided at the end to illustrate the efficiency of the numerical scheme developed in section 3. The present method is thus proved to be more accurate than existing ones and lead to faster algorithms.<\/p>"

Downloads

Published

2020-08-04

Issue

Vol. 33 No. 4 (2020)

Section

Articles