We introduce a novel EM solver for the accurate analysis of complex problems in the areas of MMIC and optical integrated circuits. The basic idea is to construct a unique tool which involves two efficient 3D full-wave methods, GTRD (generalized transverse resonance diffraction) and TLMIE (transmission line matrix integral equation), acting in the frequency and time domains, respectively. This tool is integrated in EM3DS, an existing tool based on the GTRD method, and is equipped with a user-friendly graphic interface and pre/post-processing instruments. The accuracy of the solver is demonstrated by modeling complex structures like MEMS, RF-package and photonic band gap
Development of a novel full-wave 3D-solver for the analysis of MMIC and optical integrated circuits / Pierantoni, Luca; Farina, Marco; Ciandrini, C.; Massaro, A.; Santantoni, C.; Rozzi, Tullio. - (2004), pp. 3313-3316. (Intervento presentato al convegno Antennas and Propagation Society International Symposium, 2004 IEEE tenutosi a Monterey (CA) nel 20-25 June, 2004) [10.1109/APS.2004.1332088].
Development of a novel full-wave 3D-solver for the analysis of MMIC and optical integrated circuits
PIERANTONI, Luca;FARINA, Marco;ROZZI, TULLIO
2004-01-01
Abstract
We introduce a novel EM solver for the accurate analysis of complex problems in the areas of MMIC and optical integrated circuits. The basic idea is to construct a unique tool which involves two efficient 3D full-wave methods, GTRD (generalized transverse resonance diffraction) and TLMIE (transmission line matrix integral equation), acting in the frequency and time domains, respectively. This tool is integrated in EM3DS, an existing tool based on the GTRD method, and is equipped with a user-friendly graphic interface and pre/post-processing instruments. The accuracy of the solver is demonstrated by modeling complex structures like MEMS, RF-package and photonic band gapI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
