High order compact schemes for flux type BCs

TL;DR

This paper introduces innovative fourth order compact schemes for flux boundary conditions in elliptic PDEs, utilizing undetermined coefficient methods to ensure high accuracy, stability, and applicability to various equations and boundary types.

Contribution

The paper develops the first high order compact schemes for flux boundary conditions using undetermined coefficient methods, applicable to general elliptic PDEs including anisotropic and oscillatory problems.

Findings

New HOC schemes for Robin and Neumann BCs with high accuracy.

Coefficient matrices are M-matrices ensuring stability and convergence.

Smaller error constants compared to traditional methods.

Abstract

In this paper new innovative fourth order compact schemes for Robin and Neumann boundary conditions have been developed for boundary value problems of elliptic PDEs in two and three dimensions. Different from traditional finite difference operator approach, which may not work for flux type of boundary conditions, carefully designed undetermined coefficient methods are utilized in developing high order compact (HOC) schemes. The new methods not only can be utilized to design HOC schemes for flux type of boundary conditions but can also be applied to general elliptic PDEs including Poisson, Helmholtz, diffusion-advection, and anisotropic equations with linear boundary conditions. In the new developed HOC methods, the coefficient matrices are generally M-matrices, which guarantee the discrete maximum principle for well-posed problems, so the convergence of the HOC methods. The developed HOC methods are versatile and can cover most of high order compact schemes in the literature. The HOC methods for Robin boundary conditions and for anisotropic diffusion and advection equations with Robin or even Dirichlet boundary conditions are likely the first ones that have ever been developed. With the help of pseudo-inverse, or SVD solutions, we have also observed that the developed HOC methods usually have smaller error constants compared with traditional HOC methods when applicable. Non-trivial examples with large wave numbers and oscillatory solutions are presented to confirm the performance of the new HOC methods.