A self-optimizing discretization scheme for 2D boundary element calculations

A.P.J. Deursen, van; F.B.M. Horck, van; J. Merwe, van der

doi:10.1163/156939301X00742

A self-optimizing discretization scheme for 2D boundary element calculations

A.P.J. Deursen, van, F.B.M. Horck, van, J. Merwe, van der

Research output: Contribution to journal › Article › Academic › peer-review

7 Citations (Scopus)

Abstract

A self-optimizing discretization adjustment scheme is described for boundary element calculations. The aim is to obtain high accuracy with limited computer resources. Examples will be given of two-dimensional static field calculations, where small capacitances are accurately determined in presence of others with three up to five orders larger values. To demonstrate the power of the scheme, the simplest basis function is used: a constant charge density per boundary segment. Several results are compared to exact calculations, and fast convergence and good agreement are demonstrated.

Original language	English
Pages (from-to)	461-476
Number of pages	6
Journal	Journal of Electromagnetic Waves and Applications
Volume	15
Issue number	4
DOIs	https://doi.org/10.1163/156939301X00742
Publication status	Published - 2001

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title = "A self-optimizing discretization scheme for 2D boundary element calculations",

abstract = "A self-optimizing discretization adjustment scheme is described for boundary element calculations. The aim is to obtain high accuracy with limited computer resources. Examples will be given of two-dimensional static field calculations, where small capacitances are accurately determined in presence of others with three up to five orders larger values. To demonstrate the power of the scheme, the simplest basis function is used: a constant charge density per boundary segment. Several results are compared to exact calculations, and fast convergence and good agreement are demonstrated.",

author = "{Deursen, van}, A.P.J. and {Horck, van}, F.B.M. and {Merwe, van der}, J.",

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AU - Deursen, van, A.P.J.

AU - Horck, van, F.B.M.

AU - Merwe, van der, J.

PY - 2001

Y1 - 2001

N2 - A self-optimizing discretization adjustment scheme is described for boundary element calculations. The aim is to obtain high accuracy with limited computer resources. Examples will be given of two-dimensional static field calculations, where small capacitances are accurately determined in presence of others with three up to five orders larger values. To demonstrate the power of the scheme, the simplest basis function is used: a constant charge density per boundary segment. Several results are compared to exact calculations, and fast convergence and good agreement are demonstrated.

AB - A self-optimizing discretization adjustment scheme is described for boundary element calculations. The aim is to obtain high accuracy with limited computer resources. Examples will be given of two-dimensional static field calculations, where small capacitances are accurately determined in presence of others with three up to five orders larger values. To demonstrate the power of the scheme, the simplest basis function is used: a constant charge density per boundary segment. Several results are compared to exact calculations, and fast convergence and good agreement are demonstrated.

U2 - 10.1163/156939301X00742

DO - 10.1163/156939301X00742

M3 - Article

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VL - 15

SP - 461

EP - 476

JO - Journal of Electromagnetic Waves and Applications

JF - Journal of Electromagnetic Waves and Applications

IS - 4

ER -

A self-optimizing discretization scheme for 2D boundary element calculations

Abstract

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