A joint vector and scalar potential formulation for driven high frequency problems using hybrid edge and nodal finite elements

Author

Dyczij-Edlinger, Romanus ; Biro, Oszkar

Author_Institution

Graz Univ. of Technol., Austria

Volume

44

Issue

1

fYear

1996

fDate

1/1/1996 12:00:00 AM

Firstpage

15

Lastpage

23

Abstract

An advanced A-V method employing edge-based finite elements for the vector potential A and nodal shape functions for the scalar potential V is proposed. Both gauged and ungauged formulations are considered. The novel scheme is particularly well suited for efficient iterative solvers such as the preconditioned conjugate gradient method, since it leads to significantly faster numerical convergence rates than pure edge element schemes. In contrast to nodal finite element implementations, spurious solutions do not occur and the inherent singularities of the electromagnetic fields in the vicinity of perfectly conducting edges and corners are handled correctly. Several numerical examples are presented to verify the suggested approach

Keywords

conjugate gradient methods; convergence of numerical methods; electromagnetic fields; finite element analysis; A-V method; corners; driven high frequency problems; electromagnetic fields; gauged formulations; hybrid edge/nodal finite elements; iterative solvers; numerical convergence rates; perfectly conducting edges; preconditioned conjugate gradient method; ungauged formulations; vector/scalar potential formulation; Convergence of numerical methods; Electromagnetic fields; Finite element methods; Frequency; Gradient methods; Inorganic materials; Iterative methods; Lead; Magnetic fields; Shape;

fLanguage

English

Journal_Title

Microwave Theory and Techniques, IEEE Transactions on

Publisher

ieee

ISSN

0018-9480

Type

jour

DOI

10.1109/22.481380

Filename

481380