Massively parallel Schwarz methods for the high frequency Helmholtz equation

Abstract

We investigate the parallel one-level overlapping Schwarz method for solving finite element discretization of high-frequency Helmholtz equations. The resulting linear systems are large, indefinite, ill-conditioned, and complex-valued. We present a practical variant of the restricted additive Schwarz method with Perfectly Matched Layer transmission conditions (RAS-PML), which was originally analyzed in a theoretical setting in arXiv:2404.02156, with some numerical experiments given in arXiv:2408.16580. In our algorithm, the width of the overlap and the additional PML layer on each subdomain is allowed to decrease with O(k-1 (k)), as the frequency k → ∞, and this is observed to ensure good convergence while avoiding excessive communication. In experiments, the proposed method achieves O(kd) parallel scalability under Cartesian domain decomposition and exhibits O(k) iteration counts and convergence time for d-dimensional Helmholtz problems (d = 2,3) as k increases. In this preliminary note we restrict to experiments on 2D problems with constant wave speed. Details, analysis and extensions to variable wavespeed and 3D will be given in future work.