Helmholtz equation and non-singular boundary elements applied to multi-disciplinary physical problems

TL;DR

This paper discusses a novel non-singular boundary element method for solving Helmholtz equation problems, enabling accurate and reliable simulations of complex physical wave phenomena in engineering applications.

Contribution

It introduces a singularity-free 3D boundary element framework that improves accuracy and handles complex geometries for Helmholtz-related problems.

Findings

Effective in acoustics and electromagnetic scattering

Handles complex curved shapes with higher order elements

Provides superior accuracy over traditional methods

Abstract

The famous scientist Hermann von Helmholtz was born 200 years ago. Many complex physical wave phenomena in engineering can effectively be described using one or a set of equations named after him: the Helmholtz equation. Although this has been known for a long time from a theoretical point of view, the actual numerical implementation has often been hindered by divergence free and/or curl free constraints. There is further a need for a numerical method that is accurate, reliable and takes into account radiation conditions at infinity. The classical boundary element method (BEM) satisfies the last condition, yet one has to deal with singularities in the implementation. We review here how a recently developed singularity-free three-dimensional (3D) boundary element framework with superior accuracy can be used to tackle such problems only using one or a few Helmholtz equations with higher order (quadratic) elements which can tackle complex curved shapes. Examples are given for acoustics (a Helmholtz resonator among others) and electromagnetic scattering.