English

Convolution quadrature methods for time-domain scattering from unbounded penetrable interfaces

Computational Physics 2019-10-02 v1 Numerical Analysis

Abstract

This paper presents a class of boundary integral equation methods for the numerical solution of acoustic and electromagnetic time-domain scattering problems in the presence of unbounded penetrable interfaces in two-spatial dimensions. The proposed methodology relies on Convolution Quadrature (CQ) methods in conjunction with the recently introduced Windowed Green Function (WGF) method. As in standard time-domain scattering from bounded obstacles, a CQ method of the user's choice is utilized to transform the problem into a finite number of (complex) frequency-domain problems posed on the domains involving penetrable unbounded interfaces. Each one of the frequency-domain transmission problems is then formulated as a second-kind integral equation that is effectively reduced to a bounded interface by means of the WGF method---which introduces errors that decrease super-algebraically fast as the window size increases. The resulting windowed integral equations can then be solved by means of any (accelerated or unaccelerated) off-the-shelf Helmholtz boundary integral equation solver capable of handling complex wavenumbers with a large imaginary part. A high-order Nystr\"om method based on Alpert quadrature rules is utilized here. A variety of numerical examples including wave propagation in open waveguides as well as scattering from multiply layered media demonstrate the capabilities of the proposed approach.

Keywords

Cite

@article{arxiv.1809.05084,
  title  = {Convolution quadrature methods for time-domain scattering from unbounded penetrable interfaces},
  author = {Ignacio Labarca and Luiz M. Faria and Carlos Pérez-Arancibia},
  journal= {arXiv preprint arXiv:1809.05084},
  year   = {2019}
}
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