Applications of boundary element methods (BEM) to the solution of static field problems in electrical engineering are considered in this paper. The choice of a suitable BEM formulation for electrostatics, steady current flow fields or magnetostatics is discussed from user's point of view. The dense BEM matrix is compressed with an enhanced fast multipole method (FMM) which combines well-known BEM techniques with the FMM approach. An adaptive grouping scheme for problem oriented meshes is presented along with a discussion on the influence of the mesh to the efficiency of the FMM. The computational costs of the FMM algorithm are analyzed for typical problems in practice. Finally, some electrostatic and magnetostatic numerical examples demonstrate the simple usability and the efficiency of the FMM.
%0 Journal Article
%1 buchau2005multipole
%A Buchau, André
%A Hafla, Wolfgang
%A Groh, Friedemann
%A Rucker, Wolfgang M.
%D 2005
%J Computing and Visualisation in Science
%K myown from:andrebuchau
%N 3-4
%P 137-144
%R 10.1007/s00791-005-0003-8
%T Fast multipole method based solution of electrostatic and magnetostatic field problems
%U https://doi.org/10.1007/s00791-005-0003-8
%V 8
%X Applications of boundary element methods (BEM) to the solution of static field problems in electrical engineering are considered in this paper. The choice of a suitable BEM formulation for electrostatics, steady current flow fields or magnetostatics is discussed from user's point of view. The dense BEM matrix is compressed with an enhanced fast multipole method (FMM) which combines well-known BEM techniques with the FMM approach. An adaptive grouping scheme for problem oriented meshes is presented along with a discussion on the influence of the mesh to the efficiency of the FMM. The computational costs of the FMM algorithm are analyzed for typical problems in practice. Finally, some electrostatic and magnetostatic numerical examples demonstrate the simple usability and the efficiency of the FMM.
@article{buchau2005multipole,
abstract = {Applications of boundary element methods (BEM) to the solution of static field problems in electrical engineering are considered in this paper. The choice of a suitable BEM formulation for electrostatics, steady current flow fields or magnetostatics is discussed from user's point of view. The dense BEM matrix is compressed with an enhanced fast multipole method (FMM) which combines well-known BEM techniques with the FMM approach. An adaptive grouping scheme for problem oriented meshes is presented along with a discussion on the influence of the mesh to the efficiency of the FMM. The computational costs of the FMM algorithm are analyzed for typical problems in practice. Finally, some electrostatic and magnetostatic numerical examples demonstrate the simple usability and the efficiency of the FMM.},
added-at = {2020-09-15T12:16:04.000+0200},
author = {Buchau, André and Hafla, Wolfgang and Groh, Friedemann and Rucker, Wolfgang M.},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2ac6adc10e2ef9e8f652322ef4adb8f98/iis},
day = 01,
doi = {10.1007/s00791-005-0003-8},
interhash = {5044f6a4fe728b67f1755ebce286e49e},
intrahash = {ac6adc10e2ef9e8f652322ef4adb8f98},
issn = {1433-0369},
journal = {Computing and Visualisation in Science},
keywords = {myown from:andrebuchau},
month = dec,
number = {3-4},
pages = {137-144},
timestamp = {2020-09-15T10:16:04.000+0200},
title = {Fast multipole method based solution of electrostatic and magnetostatic field problems},
url = {https://doi.org/10.1007/s00791-005-0003-8},
volume = 8,
year = 2005
}