Reduced-order modeling of large linear passive multi-terminal circuits using matrix-Pade approximation

Author

Freund, Roland W. ; Feldmann, Peter

Author_Institution

Lucent Technol., AT&T Bell Labs., Murray Hill, NJ, USA

fYear

1998

fDate

23-26 Feb 1998

Firstpage

530

Lastpage

537

Abstract

This paper introduces SyMPVL, an algorithm for the approximation of the symmetric multi-port transfer function of an RLC circuit. The algorithm employs a symmetric block-Lanczos algorithm to reduce the original circuit matrices to a pair of typically much smaller, banded, symmetric matrices. These matrices determine a matrix-Pade approximation of the multi-port transfer function, and can serve as a reduced-order model of the original circuit. They can be “stamped” directly into the Jacobian matrix of a SPICE-type circuit simulator, or can be used to synthesize an equivalent smaller circuit. We also prove stability and passivity of the reduced-order models in the RL, RC, and LC special cases, and report numerical results for SyMPVL applied to example circuits

Keywords

approximation theory; circuit analysis computing; circuit stability; linear network analysis; multiterminal networks; passive networks; transfer function matrices; Jacobian matrix; RLC circuits; SPICE-type circuit simulator; SyMPVL algorithm; large multiterminal circuits; linear passive multi-terminal circuits; matrix-Pade approximation; reduced-order modeling; stability; symmetric block-Lanczos algorithm; symmetric matrices; symmetric multiport transfer function; Circuit stability; Circuit synthesis; Equations; Integrated circuit modeling; Jacobian matrices; RLC circuits; Reduced order systems; Symmetric matrices; Transfer functions; Voltage;

fLanguage

English

Publisher

ieee

Conference_Titel

Design, Automation and Test in Europe, 1998., Proceedings

Conference_Location

Paris

Print_ISBN

0-8186-8359-7

Type

conf

DOI

10.1109/DATE.1998.655909

Filename

655909