DocumentCode
1473814
Title
Quasi-TEM analysis of multilayered, multiconductor coplanar structures with dielectric and magnetic anisotropy including substrate losses
Author
Horno, Manuel ; Mesa, Francisco L. ; Medina, Francisco ; Marqués, Ricardo
Author_Institution
Dept. de Electron. y Electromagn., Sevilla Univ., Spain
Volume
38
Issue
8
fYear
1990
Firstpage
1059
Lastpage
1068
Abstract
A quasi-TEM (transverse electromagnetic) analysis of multiconductor planar lines embedded in a layered structure involving lossy iso/anisotropic electric and/or magnetic materials is achieved. Conditions under which a quasi-TEM assumption is valid are theoretically determined. An efficient spectral-domain analysis is used to determine the complex capacitance and inductance matrices characterizing the transmission system. computation of the inductance matrix is reduced to the computation of an equivalent capacitance matrix when media characterized for a fully general permeability tensor are present. It is also shown that most actual monolithic microwave integrated circuit (MMIC) microstrip-type structures (where semiconductor substrates are present) and possible future applications including lossy magnetic materials can be analyzed by using the simple quasi-TEM model. The validity of the results has been verified by comparison with full-wave theoretical and experimental data on microstrip lines on magnetic substrates and slow-wave structures.<>
Keywords
MMIC; dielectric losses; magnetic anisotropy; strip lines; capacitance matrix; complex capacitance; complex inductance; dielectric anisotropy; electric materials; inductance matrix; layered structure; lossy anisotropic materials; lossy isotropic materials; magnetic anisotropy; magnetic materials; microstrip-type structures; monolithic microwave integrated circuit; multiconductor coplanar structures; permeability tensor; quasi-TEM; slow-wave structures; spectral-domain analysis; substrate losses; Capacitance; Dielectric losses; Dielectric substrates; Inductance; Integrated circuit modeling; MMICs; Magnetic analysis; Magnetic anisotropy; Magnetic materials; Transmission line matrix methods;
fLanguage
English
Journal_Title
Microwave Theory and Techniques, IEEE Transactions on
Publisher
ieee
ISSN
0018-9480
Type
jour
DOI
10.1109/22.57331
Filename
57331
Link To Document