Improved Residual Distributionschemes For The Maxwell’s

Electrodynamics have innumerable applications, one of which is to locate embedded object, for example in a human body using electromagnetic scattering. The wireless telecommunication is all about the radiation of electromagnetic waves, and the optical waveguide transmits signals at the speed of l...

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Main Author: Sien, Neoh Soon
Format: Thesis
Language:English
Published: 2019
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spelling my.usm.eprints.48332 http://eprints.usm.my/48332/ Improved Residual Distributionschemes For The Maxwell’s Sien, Neoh Soon T Technology Electrodynamics have innumerable applications, one of which is to locate embedded object, for example in a human body using electromagnetic scattering. The wireless telecommunication is all about the radiation of electromagnetic waves, and the optical waveguide transmits signals at the speed of light. The aspiration of this work is to introduce the vertex-based residual distribution(RD) schemes for Maxwell’s equations, which is time-explicit and still secondorder-accurate. The computational electromagnetics (CEM) works do not havea standard mesh topology for unstructured grid, which might inhibit their computationaldevelopment. The most eminent residual distribution scheme which vouches for the second-order-accuracy is the Lax-Wendroff residual distribution (RD-LW) scheme. The RD schemes are transcendent for upwind schemes that stay compact, such as the RD-LDA (low diffusion A) scheme, but appears to be time-implicit for time-dependent fluid problems. The first innovation in this work is to procure a time-explicit updating scheme for RD-LDA scheme while still retaining the order-of-accuracy. Besides, the RD-Galerkin method is propounded in this work, which is rare in RD framework. Secondly, the weak Galerkin FEM is adapted for time-dependent second-order Maxwell’s equation, and also devising a gradient flux residual approach which is tantamount to the RD-scheme for secondorder Maxwell’s equation. These two effective solvers reduce first-order Maxwell’s equations to second-order Maxwell’s equation in scalar form. The weak Galerkin finite-element method (FEM) is indisputably more accurate in replicating nuxxiv merical results, but it is somehow deficient upon handling certain boundaries,unlike the gradient flux residual approach. The novelty of this work comes from introducing the RD schemes to first-order Maxwell’s equations, while devising a new RD scheme for the second-order Maxwell’s equation. The test cases in this work comprised of three main electrodynamics phenomena, they are waveguide propagation, radiation mechanism and scattering problem. Three-dimensional problems are also studied to ascertain the extension of these schemes for realtime applications. The numerical results manifest no instability issues for all the constructed numerical schemes. The lumped RD-LDA scheme trims off the computational cost by approximately 50 times, as compared to its time-implicit consistent mass-matrix approach, although this is still 4 to 6 times higher than the RD-LW scheme’s. In general, the space-centered schemes of RD-LW, RDGalerkin, weak Galerkin FEM and gradient flux residual in this work promise an order-of-accuracy between 1:4212 and 2:43871. In contradistinction to the spacecentered schemes, the upwind RD-LDA schemes only have an order-of-accuracy ranging from 0:7825 to 0:9335. 2019-12-01 Thesis NonPeerReviewed application/pdf en http://eprints.usm.my/48332/1/Improved%20Residual%20Distributionschemes%20For%20The%20Maxwell%E2%80%99s.pdf Sien, Neoh Soon (2019) Improved Residual Distributionschemes For The Maxwell’s. PhD thesis, Universiti Sains Malaysia.
institution Universiti Sains Malaysia
building Hamzah Sendut Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Sains Malaysia
content_source USM Institutional Repository
url_provider http://eprints.usm.my/
language English
topic T Technology
spellingShingle T Technology
Sien, Neoh Soon
Improved Residual Distributionschemes For The Maxwell’s
description Electrodynamics have innumerable applications, one of which is to locate embedded object, for example in a human body using electromagnetic scattering. The wireless telecommunication is all about the radiation of electromagnetic waves, and the optical waveguide transmits signals at the speed of light. The aspiration of this work is to introduce the vertex-based residual distribution(RD) schemes for Maxwell’s equations, which is time-explicit and still secondorder-accurate. The computational electromagnetics (CEM) works do not havea standard mesh topology for unstructured grid, which might inhibit their computationaldevelopment. The most eminent residual distribution scheme which vouches for the second-order-accuracy is the Lax-Wendroff residual distribution (RD-LW) scheme. The RD schemes are transcendent for upwind schemes that stay compact, such as the RD-LDA (low diffusion A) scheme, but appears to be time-implicit for time-dependent fluid problems. The first innovation in this work is to procure a time-explicit updating scheme for RD-LDA scheme while still retaining the order-of-accuracy. Besides, the RD-Galerkin method is propounded in this work, which is rare in RD framework. Secondly, the weak Galerkin FEM is adapted for time-dependent second-order Maxwell’s equation, and also devising a gradient flux residual approach which is tantamount to the RD-scheme for secondorder Maxwell’s equation. These two effective solvers reduce first-order Maxwell’s equations to second-order Maxwell’s equation in scalar form. The weak Galerkin finite-element method (FEM) is indisputably more accurate in replicating nuxxiv merical results, but it is somehow deficient upon handling certain boundaries,unlike the gradient flux residual approach. The novelty of this work comes from introducing the RD schemes to first-order Maxwell’s equations, while devising a new RD scheme for the second-order Maxwell’s equation. The test cases in this work comprised of three main electrodynamics phenomena, they are waveguide propagation, radiation mechanism and scattering problem. Three-dimensional problems are also studied to ascertain the extension of these schemes for realtime applications. The numerical results manifest no instability issues for all the constructed numerical schemes. The lumped RD-LDA scheme trims off the computational cost by approximately 50 times, as compared to its time-implicit consistent mass-matrix approach, although this is still 4 to 6 times higher than the RD-LW scheme’s. In general, the space-centered schemes of RD-LW, RDGalerkin, weak Galerkin FEM and gradient flux residual in this work promise an order-of-accuracy between 1:4212 and 2:43871. In contradistinction to the spacecentered schemes, the upwind RD-LDA schemes only have an order-of-accuracy ranging from 0:7825 to 0:9335.
format Thesis
author Sien, Neoh Soon
author_facet Sien, Neoh Soon
author_sort Sien, Neoh Soon
title Improved Residual Distributionschemes For The Maxwell’s
title_short Improved Residual Distributionschemes For The Maxwell’s
title_full Improved Residual Distributionschemes For The Maxwell’s
title_fullStr Improved Residual Distributionschemes For The Maxwell’s
title_full_unstemmed Improved Residual Distributionschemes For The Maxwell’s
title_sort improved residual distributionschemes for the maxwell’s
publishDate 2019
url http://eprints.usm.my/48332/1/Improved%20Residual%20Distributionschemes%20For%20The%20Maxwell%E2%80%99s.pdf
http://eprints.usm.my/48332/
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score 13.214268