Robust Field-Only Surface Integral Equations: Scattering from a Dielectric Body

TL;DR

This paper introduces a new, robust surface integral method for solving Maxwell's equations on dielectric scatterers that avoids common numerical issues and simplifies implementation, effective across various scattering regimes.

Contribution

A novel, fully desingularized surface integral method for electric fields in dielectric scattering that simplifies computations and improves robustness over existing techniques.

Findings

Method is simpler and avoids intermediate quantities.

No zero frequency catastrophe issues.

Effective in Rayleigh, Mie, and geometrical optics regimes.

Abstract

A robust and efficient field-only nonsingular surface integral method to solve Maxwell's equations for the components of the electric field on the surface of a dielectric scatterer is introduced. In this method, both the vector Helmholtz equation and the divergence-free constraint are satisfied inside and outside the scatterer. The divergence-free condition is replaced by an equivalent boundary condition that relates the normal derivatives of the electric field across the surface of the scatterer. Also, the continuity and jump conditions on the electric and magnetic fields are expressed in terms of the electric field across the surface of the scatterer. Together with these boundary conditions, the scalar Helmholtz equation for the components of the electric field inside and outside the scatterer is solved by a fully desingularized surface integral method. Comparing with the most popular surface integral methods based on the Stratton-Chu formulation or the PMCHWT formulation, our method is conceptually simpler and numerically straightforward because there is no need to introduce intermediate quantities such as surface currents and the use of complicated vector basis functions can be avoided altogether. Also, our method is not affected by numerical issues such as the zero frequency catastrophe and does not contain integrals with (strong) singularities. To illustrate the robustness and versatility of our method, we show examples in the Rayleigh, Mie, and geometrical optics scattering regimes. Given the symmetry between the electric field and the magnetic field, our theoretical framework can also be used to solve for the magnetic field.