Title :
Electromagnetic modeling of thin-film bulk acoustic resonators
Author :
Farina, Marco ; Rozzi, Tullio
Author_Institution :
Dept. of Electromagn. & Bioeng., Univ. of Ancona, Italy
Abstract :
This paper introduces a novel technique for the electromagnetic analysis of thin-film bulk acoustic-wave resonators. The piezoelectric/acoustic linear equations are coupled to and solved together with Maxwell´s equations. For the acoustic propagation, locally monodimensional behavior is assumed, while full-wave three-dimensional Maxwell´s equations are rigorously solved for the complete circuit. The proposed approach is validated for single resonators by comparison with experimental data, providing very good agreement with reduced computational resources. Hence, a complete Agilent Technologies´ nine-resonator passband filter is simulated in order to demonstrate a typical application to a real-world complex problem.
Keywords :
Maxwell equations; acoustic resonator filters; acoustic wave propagation; acoustoelectric effects; band-pass filters; bulk acoustic wave devices; computational electromagnetics; mobile communication; mobile handsets; multiplexing equipment; thin film devices; acoustic linear equations; acoustic propagation; complete agilent technologies; electromagnetic analysis; electromagnetic modeling; fullwave three dimensional Maxwells equations; monodimensional behavior; multiplexers; nine resonator passband filter; personal communication; piezoelectric linear equations; thin film bulk acoustic resonators; wireless handsets; Acoustic propagation; Coupling circuits; Electromagnetic analysis; Electromagnetic modeling; Maxwell equations; Passband; Piezoelectric films; Resonator filters; Thin film circuits; Transistors; 65; BAW; Bulk acoustic-wave; EM; analysis; devices; electromagnetic; method of moments;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2004.837152
