Title :
Integral formulation of the measured equation of invariance: a novel sparse matrix boundary element method
Author :
Rius, Juan M. ; Pous, Rafael ; Cardama, Angel
Author_Institution :
Dept. de Teoria del Senyal i Comunicacions, Univ. Politecnica de Catalunya, Barcelona, Spain
fDate :
5/1/1996 12:00:00 AM
Abstract :
A novel integral formulation of the measured equation of invariance method is derived from the reciprocity theorem and implemented for perfectly conducting (PEC) 2-D scattering problems. This formulation uses the electric and magnetic Green´s functions of the environment to obtain a matrix equation for the induced surface current with the same number of unknowns as the conventional boundary element-method of moments (BE-MoM) approach. However, the matrix that must be inverted in the new formulation is sparse and circulant, with only three non-zero elements per row. Sample results for two-dimensional TM and TE problems with perfectly conducting scatterers show enormous CPU time and memory savings over the conventional BEM-MoM approach. The new formulation has important advantages over the original finite difference formulation of MEI, but also shares some of its limitations
Keywords :
Green´s function methods; boundary-elements methods; conductors (electric); electrical engineering; electrical engineering computing; electromagnetic wave scattering; integral equations; matrix inversion; method of moments; sparse matrices; 2D scattering problems; BE-MoM; CPU memory savings; CPU time savings; boundary element-method of moments; circulant matrix; electric Green´s function; finite difference formulation; induced surface current; integral formulation; magnetic Green´s function; matrix equation; matrix inversion; measured equation of invariance; perfectly conducting scatterers; reciprocity theorem; sparse matrix boundary element method; two-dimensional TM problems; Boundary conditions; Boundary element methods; Electromagnetic scattering; Finite difference methods; Finite element methods; Green´s function methods; Integral equations; Moment methods; Robustness; Scattering; Sparse matrices; Tellurium;
Journal_Title :
Magnetics, IEEE Transactions on
