Title :
Differential Forms, Galerkin Duality, and Sparse Inverse Approximations in Finite Element Solutions of Maxwell Equations
Author :
He, Bo ; Teixeira, Fernando L.
Author_Institution :
Dept. of Electr. & Comput. Eng., Ohio State Univ., Columbus, OH
fDate :
5/1/2007 12:00:00 AM
Abstract :
We identify primal and dual formulations in the finite element method (FEM) solution of the vector wave equation using a geometric discretization based on differential forms. These two formulations entail a mathematical duality denoted as Galerkin duality. Galerkin-dual FEM formulations yield identical nonzero (dynamical) eigenvalues (up to machine precision), but have static (zero eigenvalue) solution spaces of different dimensions. Algebraic relationships among the degrees of freedom of primal and dual formulations are explained using a deep-rooted connection between the Hodge-Helmholtz decomposition of differential forms and Descartes-Euler polyhedral formula, and verified numerically. In order to tackle the fullness of dual formulation, algebraic and topological thresholdings are proposed to approximate inverse mass matrices by sparse matrices
Keywords :
Galerkin method; Maxwell equations; duality (mathematics); finite element analysis; sparse matrices; wave equations; Descartes-Euler polyhedral formula; FEM; Galerkin duality; Hodge-Helmholtz decomposition; Maxwell equations; algebraic-topological thresholding; differential forms; finite element method; geometric discretization; sparse inverse approximation; vector wave equation; Eigenvalues and eigenfunctions; Electromagnetic fields; Finite element methods; Helium; Laboratories; Matrix decomposition; Maxwell equations; Partial differential equations; Sparse matrices; Stability; Differential forms; Maxwell equations; finite element methods (FEMs); sparse matrices;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2007.895619
