Title :
Q-enhancement with electrode materials in the FBAR for timing devices
Author :
Hara, Masaki ; Kuwano, Hiroki
Author_Institution :
Dept. of Nanomech., Tohoku Univ., Sendai, Japan
Abstract :
Thin film bulk acoustic resonators (FBARs) are key components in the timing devices such as FBAR-based voltage controlled oscillators (VCOs) or wake-up-circuits for wireless sensor nodes. For such applications, theoretical analysis of Q-factor is crucial rather than that of the effective electro-mechanical coupling coefficient keff2. We developed the batch calculation program based on Mason´s model in this study. Since the physical model in our program was not constrained by the element size against the finite element method (FEM), resonant frequency and characteristic impedance, which strongly affect the Q-factor, can be easily kept a constant in the calculation models. Thus, their influences for the Q-factor can be cancelled. It was clarified how Q-factor is controlled by the electrode design.
Keywords :
Q-factor; acoustic resonators; bulk acoustic wave devices; electrodes; finite element analysis; timing circuits; voltage-controlled oscillators; FBAR-based voltage controlled oscillators; FEM; Mason´s model; Q-enhancement; Q-factor analysis; VCO; batch calculation program; characteristic impedance; electrode design; electrode materials; element size; finite element method; resonant frequency; thin film bulk acoustic resonators; timing devices; wake-up-circuits; wireless sensor nodes; Attenuation; Materials; Niobium; Platinum; Q-factor; Tungsten; Zinc; FBAR; Mason´s model; timing device;
Conference_Titel :
Ultrasonics Symposium (IUS), 2014 IEEE International
Conference_Location :
Chicago, IL
DOI :
10.1109/ULTSYM.2014.0504
