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Bibliographic Details
Main Authors: Rösler, Frank, Stepanenko, Alexei
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.00846
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author Rösler, Frank
Stepanenko, Alexei
author_facet Rösler, Frank
Stepanenko, Alexei
contents This paper is concerned with the numerical computation of scattering resonances of the Laplacian for Dirichlet obstacles with rough boundary. We prove that under mild geometric assumptions on the obstacle there exists an algorithm whose output is guaranteed to converge to the set of resonances of the problem. The result is formulated using the framework of Solvability Complexity Indices. The proof is constructive and provides an efficient numerical method. The algorithm is based on a combination of a Glazman decomposition, a polygonal approximation of the obstacle and a finite element method. Our result applies in particular to obstacles with fractal boundary, such as the Koch Snowflake and certain filled Julia sets. Finally, we provide numerical experiments in MATLAB for a range of interesting obstacle domains.
format Preprint
id arxiv_https___arxiv_org_abs_2402_00846
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Computing scattering resonances of rough obstacles
Rösler, Frank
Stepanenko, Alexei
Numerical Analysis
Analysis of PDEs
Spectral Theory
81U24, 47N40, 65N15
This paper is concerned with the numerical computation of scattering resonances of the Laplacian for Dirichlet obstacles with rough boundary. We prove that under mild geometric assumptions on the obstacle there exists an algorithm whose output is guaranteed to converge to the set of resonances of the problem. The result is formulated using the framework of Solvability Complexity Indices. The proof is constructive and provides an efficient numerical method. The algorithm is based on a combination of a Glazman decomposition, a polygonal approximation of the obstacle and a finite element method. Our result applies in particular to obstacles with fractal boundary, such as the Koch Snowflake and certain filled Julia sets. Finally, we provide numerical experiments in MATLAB for a range of interesting obstacle domains.
title Computing scattering resonances of rough obstacles
topic Numerical Analysis
Analysis of PDEs
Spectral Theory
81U24, 47N40, 65N15
url https://arxiv.org/abs/2402.00846