Title :
Iterative, monotonically convergent hybrid-mode simulation of complex, multiply-branched (M)MIC conductor geometries
Author :
Wertgen, W. ; Jansen, R.H.
Author_Institution :
Dept. of Electr. Eng., Duisburg Univ., West Germany
Abstract :
The unconditionally and monotonically convergent iterative full-wave simulation of multiply branched (M)MIC shielded conductor geometries is described. With this approach, the electromagnetic, hybrid-mode characterization of shielded (M)MIC configurations of very high geometrical complexity has become feasible in an efficient, stable and monotonically convergent manner up to high millimeter-wave frequencies. For the unsegmented configurations considered in such analyses, frequency-dependent S-parameter datafiles are generated for direct use in layout-oriented microwave CAD. It is possible to set up parallel computers with a relatively simple architecture, consisting mainly of an FFT signal processor array, to achieve dramatic computing time reduction for such iterative solutions.<>
Keywords :
MMIC; S-parameters; circuit layout CAD; digital simulation; microwave integrated circuits; parallel algorithms; FFT signal processor array; MMIC; computing time reduction; frequency-dependent S-parameter datafiles; geometrical complexity; hybrid-mode simulation; iterative full-wave simulation; iterative solutions; layout-oriented microwave CAD; microwave IC; monotonically convergent; multiply branched shielded conductor geometries; parallel computers; unsegmented configurations; Concurrent computing; Conductors; Data analysis; Electromagnetic shielding; Frequency; Geometry; Microwave generation; Scattering parameters; Signal processing; Solid modeling;
Conference_Titel :
Microwave Symposium Digest, 1990., IEEE MTT-S International
Conference_Location :
Dallas, TX
DOI :
10.1109/MWSYM.1990.99642
