Login (DCU Staff Only)
Login (DCU Staff Only)

DORAS | DCU Research Repository

Explore open access research and scholarly works from DCU

Advanced Search

Accelerated stationary iterative methods for the numerical solution of electromagnetic wave scattering problems

Mullen, Marie (2010) Accelerated stationary iterative methods for the numerical solution of electromagnetic wave scattering problems. PhD thesis, Dublin City University.

Abstract
The main focus of this work is to contribute to the development of iterative solvers applied to the method of moments solution of electromagnetic wave scattering problems. In recent years there has been much focus on current marching iterative methods, such as Gauss-Seidel and others. These methods attempt to march a solution for the unknown basis function amplitudes in a manner that mimics the physical processes which create the current. In particular the forward backward method has been shown to produce solutions that, for some twodimensional scattering problems, converge more rapidly than non-current marching Krylov methods. The buffered block forward backward method extends these techniques in order to solve three-dimensional scattering problems. The convergence properties of the forward backward and buffered block forward backward methods are analysed extensively in this thesis. In conjunction, several means of accelerating these current marching methods are investigated and implemented. The main contributions of this thesis can be summarised as follows: ² An explicit convergence criterion for the buffered block forward backward method is specified. A rigorous numerical comparison of the convergence rate of the buffered block forward backward method, against that of a range of Krylov solvers, is performed for a range of scattering problems. ² The acceleration of the buffered block forward backward method is investigated using relaxation. ² The efficient application of the buffered block forward backward method to problems involving multiple source locations is examined. ² An optimally sized correction step is introduced designed to accelerate the convergence of current marching methods. This step is applied to the forward backward and buffered block forward backward methods, and applied to two and three-dimensional problems respectively. Numerical results demonstrate the significantly improved convergence of the forward backward and buffered block forward backward methods using this step.
Metadata
Item Type:Thesis (PhD)
Date of Award:17 June 2010
Refereed:No
Supervisor(s):Brennan, Conor
Uncontrolled Keywords:Integral equation; method of moments; wave scattering; buffered block forward backward
Subjects:Engineering > Telecommunication
Mathematics
DCU Faculties and Centres:DCU Faculties and Schools > Faculty of Engineering and Computing > School of Electronic Engineering
Research Initiatives and Centres > Research Institute for Networks and Communications Engineering (RINCE)
Use License:This item is licensed under a Creative Commons Attribution-NonCommercial-No Derivative Works 3.0 License. View License
Funders:Irish Research Council for Science Engineering and Technology
ID Code:15420
Deposited On:04 Apr 2011 15:49 by Conor Brennan . Last Modified 19 Jul 2018 14:50
Documents

Full text available as:

[thumbnail of Marie Mullen 55152155 PhD thesis]
Preview
PDF (Marie Mullen 55152155 PhD thesis) - Requires a PDF viewer such as GSview, Xpdf or Adobe Acrobat Reader
1MB
Downloads

Downloads

Downloads per month over past year

Archive Staff Only: edit this record