A high order mixed vector finite element method for solving the time dependent Maxwell equations on unstructured grids

A high order mixed vector finite element method for solving the time dependent Maxwell equations on unstructured grids

We present a mixed vector finite element method for solving the time dependent coupled Ampere and Faraday laws of Maxwell’s equations on unstructured hexahedral grids that employs high order discretization in both space and time. The method is of arbitrary order accuracy in space and up to 4th order...

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Veröffentlicht in:Journal of computational physics 2005-04, Vol.204 (2), p.490-519
Hauptverfasser: Rieben, R.N., Rodrigue, G.H., White, D.A.
Format: Artikel
Sprache:eng
Schlagworte:
Computational electromagnetics
Discrete differential forms
H(Curl) and H(Div) – conforming methods
High order methods
Maxwell’s equations
Numerical dispersion
Spurious modes
Vector finite elements
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Zusammenfassung:We present a mixed vector finite element method for solving the time dependent coupled Ampere and Faraday laws of Maxwell’s equations on unstructured hexahedral grids that employs high order discretization in both space and time. The method is of arbitrary order accuracy in space and up to 4th order accurate in time, making it well suited for electrically large problems where grid anisotropy and numerical dispersion have plagued other methods. In addition, the method correctly models both the jump discontinuities and the divergence-free properties of the electric and magnetic fields, is charge and energy conserving, conditionally stable, and free of spurious modes. Several computational experiments are performed to demonstrate the accuracy, efficiency and benefits of the method.
ISSN:0021-9991
1090-2716
DOI:10.1016/j.jcp.2004.10.030