PARALLEL SKELETONIZATION FOR INTEGRAL EQUATIONS IN EVOLVING MULTIPLY-CONNECTED DOMAINS

This paper presents a general method for applying hierarchical matrix skeletonization factorizations to the numerical solution of boundary integral equations with possibly rank-deficient integral operators. Rank-deficient operators arise in boundary integral approaches to elliptic partial differential equations with multiple boundary components, such as in the case of multiple vesicles in a viscous fluid flow. Our generalized skeletonization factorization retains the locality property afforded by the proxy point method, and allows for a parallelized implementation where different processors work on different parts of the boundary simultaneously. Further, when the boundary undergoes local geometric perturbations (such as movement of an interior hole), the factorization can be recomputed efficiently with respect to the number of modified discretization nodes. We present an application that leverages a parallel implementation of skeletonization with updates in a shape optimization regime.

Automated summary

This paper introduces a general method of applying hierarchical matrix skeletonization factorizations to numerical solutions of boundary integral equations, particularly useful for possibly rank-deficient operators and multiple boundary component problems. The method retains locality, allows parallelized implementation, and efficiently handles boundary geometric perturbations.