A novel direct Helmholtz solver in inhomogeneous media based on the operator Fourier transform functional calculus

TL;DR

This paper introduces a new numerical method using operator Fourier transform to directly solve the Helmholtz equation efficiently in inhomogeneous media across multiple dimensions, handling complex wave phenomena with high computational capacity.

Contribution

The novel approach employs OFT representation of pseudodifferential operators for fast, direct Helmholtz solutions in inhomogeneous media, outperforming traditional methods in efficiency and versatility.

Findings

Achieved convergence rates confirmed through numerical studies.

Demonstrated ability to solve large-scale 3D problems with over a billion unknowns.

Successfully applied to complex wave scattering and propagation scenarios.

Abstract

This article presents novel numerical algorithms based on pseudodifferential operators for fast, direct, solution of the Helmholtz equation in 1D, 2D, and 3D inhomogeneous unbounded media. The proposed approach relies on an Operator Fourier Transform (OFT) representation of pseudodifferential operators ({\Psi}DO) which frame the problem of computing the inverse Helmholtz operator with a spatially-dependent wave speed in terms of two sequential applications of an inverse square root {\Psi}DO. The OFT representation of the action of the inverse square root {\Psi}DO, in turn, can be effected as a superposition of solutions of a pseudo-temporal initial-boundary-value problem for a paraxial equation. The OFT framework offers several advantages over traditional direct and iterative approaches for the solution of the Helmholtz equation. The operator integral transform is amenable to standard quadrature methods and the required pseudo-temporal paraxial equation solutions can be obtained using any suitable numerical method. A specialized quadrature is derived to evaluate the OFT efficiently and an alternating direction implicit method, used in conjunction with standard finite differences, is used to solve the requisite component paraxial equation problems. Numerical studies in 1D, 2D, and 3D are presented to confirm the expected OFT-based Helmholtz solver convergence rate. In addition, the efficiency and versatility of our proposed approach is demonstrated by tackling nontrivial wave propagation problems, including two-dimensional plane wave scattering from a geometrically complex inhomogeneity, three-dimensional scattering from turbulent channel flow and plane wave transmission through a spherically-symmetric gradient-index Luneburg lens. All computations, 3D problems which involve solving the Helmholtz equation with more than one billion complex unknowns, are performed in a single workstation.