A Bernoulli-barycentric rational matrix collocation method with preconditioning for a class of evolutionary PDEs

Abstract

We propose a Bernoulli-barycentric rational matrix collocation method for two-dimensional evolutionary partial differential equations (PDEs) with variable coefficients that combines Bernoulli polynomials with barycentric rational interpolations in time and space, respectively. The theoretical accuracy O((2π)-N+hxdx-1+hydy-1) of our numerical scheme is proven, where N is the number of basis functions in time, hx and hy are the grid sizes in the x, y-directions, respectively, and 0≤ dx≤ b-ahx,~0≤ dy≤d-chy. For the efficient solution of the relevant linear system arising from the discretizations, we introduce a class of dimension expanded preconditioners that take the advantage of structural properties of the coefficient matrices, and we present a theoretical analysis of eigenvalue distributions of the preconditioned matrices. The effectiveness of our proposed method and preconditioners are studied for solving some real-world examples represented by the heat conduction equation, the advection-diffusion equation, the wave equation and telegraph equations.