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The application of a high-order discontinuous Galerkin time-domain method for the computation of electromagnetic resonant modes

Mark Dawson, Rubén Sevilla Orcid Logo, Kenneth Morgan Orcid Logo

Applied Mathematical Modelling, Volume: 55, Pages: 94 - 108

Swansea University Authors: Mark Dawson, Rubén Sevilla Orcid Logo, Kenneth Morgan Orcid Logo

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Abstract

This work presents a highly accurate and efficient methodology for the computation of electromagnetic resonant frequencies and their associated modes in cavities. The proposed technique consists of a high–order discontinuous Galerkin time–domain solver combined with a signal processing algorithm for...

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Published in: Applied Mathematical Modelling
ISSN: 0307-904X
Published: 2018
Online Access: Check full text

URI: https://cronfa.swan.ac.uk/Record/cronfa36201
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Abstract: This work presents a highly accurate and efficient methodology for the computation of electromagnetic resonant frequencies and their associated modes in cavities. The proposed technique consists of a high–order discontinuous Galerkin time–domain solver combined with a signal processing algorithm for extracting the frequency content. The methodology is capable of incorporating the CAD boundary representation of the domain. The numerical results demonstrate that incorporating the exact boundary representation results in a improved convergence rate, a phenomenon that has not been previously reported. Several numerical examples in two and three dimensions show the potential of the proposed technique for cavities filled with non–dispersive or dispersive media.
Keywords: Maxwell’s equations; resonant modes; high–order; discontinuous Galerkin; time–domain
College: College of Engineering
Start Page: 94
End Page: 108