Lattice Green’s Functions for High-Order Finite Difference Stencils

Author(s)

Gabbard, James; van Rees, Wim M.

Abstract

Lattice Green's Functions (LGFs) are fundamental solutions to discretized linear operators, and as such they are a useful tool for solving discretized elliptic PDEs on domains that are unbounded in one or more directions. The majority of existing numerical solvers that make use of LGFs rely on a second-order discretization and operate on domains with free-space boundary conditions in all directions. Under these conditions, fast expansion methods are available that enable precomputation of 2D or 3D LGFs in linear time, avoiding the need for brute-force multi-dimensional quadrature of numerically unstable integrals. Here we focus on higher-order discretizations of the Laplace operator on domains with more general boundary conditions, by (1) providing an algorithm for fast and accurate evaluation of the LGFs associated with high-order dimension-split centered finite differences on unbounded domains, and (2) deriving closed-form expressions for the LGFs associated with both dimension-split and Mehrstellen discretizations on domains with one unbounded dimension. Through numerical experiments we demonstrate that these techniques provide LGF evaluations with near machine-precision accuracy, and that the resulting LGFs allow for numerically consistent solutions to high-order discretizations of the Poisson's equation on fully or partially unbounded 3D domains.

Date issued

2024-01-04

URI

https://hdl.handle.net/1721.1/154893

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

SIAM Journal on Numerical Analysis

Publisher

Society for Industrial & Applied Mathematics (SIAM)

Citation

Gabbard, James and van Rees, Wim M. 2024. "Lattice Green’s Functions for High-Order Finite Difference Stencils." SIAM Journal on Numerical Analysis, 62 (1).

Version: Author's final manuscript

ISSN

0036-1429

1095-7170