English

Parsimonious convolution quadrature

Numerical Analysis 2024-10-22 v1 Numerical Analysis

Abstract

We present a method to rapidly approximate convolution quadrature (CQ) approximations, based on a piecewise polynomial interpolation of the Laplace domain operator, which we call the \emph{parsimonious} convolution quadrature method. For implicit Euler and second order backward difference formula based discretizations, we require O(NlogN)O(\sqrt{N}\log N) evaluations in the Laplace domain to approximate NN time steps of the convolution quadrature method to satisfactory accuracy. The methodology proposed here differentiates from the well-understood fast and oblivious convolution quadrature \cite{SLL06}, since it is applicable to Laplace domain operator families that are only defined and polynomially bounded on a positive half space, which includes acoustic and electromagnetic wave scattering problems. The methods is applicable to linear and nonlinear integral equations. To elucidate the core idea, we give a complete and extensive analysis of the simplest case and derive worst-case estimates for the performance of parsimonious CQ based on the implicit Euler method. For sectorial Laplace transforms, we obtain methods that require O(log2N)O(\log^2 N) Laplace domain evaluations on the complex right-half space. We present different implementation strategies, which only differ slightly from the classical realization of CQ methods. Numerical experiments demonstrate the use of the method with a time-dependent acoustic scattering problem, which was discretized by the boundary element method in space.

Keywords

Cite

@article{arxiv.2410.15079,
  title  = {Parsimonious convolution quadrature},
  author = {Jens M. Melenk and Jörg Nick},
  journal= {arXiv preprint arXiv:2410.15079},
  year   = {2024}
}

Comments

19 pages, 5 figures

R2 v1 2026-06-28T19:28:14.094Z