Matrix singular value decomposition for pole-free solutions of homogeneous matrix equations as applied to numerical modeling methods

Author

Labay, Vladimir A. ; Bornemann, Jens

Author_Institution

Dept. of Electr. & Comput. Eng., Victoria Univ., BC, Canada

Volume

2

Issue

2

fYear

1992

Firstpage

49

Lastpage

51

Abstract

A general technique for solving homogeneous matrix equations as applied to numerical modeling procedures in microwave and millimeter-wave structures is introduced. By using singular value decomposition, well-known numerical problems related to poles and steep gradients in the determinant function are eliminated. The proposed technique is generally applicable, improves the accuracy and reliability of computed results, and significantly reduces the CPU time due to a more moderate behavior of the function to be analyzed. A dispersion characteristics example of a conductor-backed slotline MMIC structure illustrates the advantage of the pole-free formulation over conventional determinant calculations.<>

Keywords

dispersion (wave); matrix algebra; microwave devices; numerical methods; poles and zeros; waveguide components; MMIC structure; conductor-backed slotline; determinant function; dispersion characteristics; homogeneous matrix equations; millimeter-wave structures; numerical modeling methods; pole-free solutions; singular value decomposition; steep gradients; Equations; MMICs; Matrix decomposition; Microwave theory and techniques; Millimeter wave technology; Numerical models; Poles and zeros; Propagation constant; Singular value decomposition; Slotline;

fLanguage

English

Journal_Title

Microwave and Guided Wave Letters, IEEE

Publisher

ieee

ISSN

1051-8207

Type

jour

DOI

10.1109/75.122406

Filename

122406