This paper presents a bulk acoustic wave piezoelectric disk resonator based on a special pair of
degenerative modes, to detect z-axis angular velocity. A single piezoelectric disk is operated in its appropriate
modes in the kHz frequency range to achieve this function. This design combines the bulk acoustic wave drive/sense
mode with lead zirconate titanate resonator which improves device’s performance and simplifies its structural
complexity. The operation principle of piezoelectric disk resonator is given and validated by finite element method,
and the scale factor of piezoelectric disk resonator is 0.977 μV/[(?) · s?1] without any amplification section.
The results of impedance analysis for the prototype in the air, which is fabricated on lead zirconate titanate
wafer by Micro-Electro-Mechanical System process, show that the resonant frequency of the piezoelectric disk
resonator is about 190 kHz. Moreover, the measured frequency split between drive and sense mode is about
290 Hz without any tuning methods. At last, a closed-loop driving and detecting circuit system is designed and
its modulation/demodulation method is studied, preliminary experiments show that this device is not sensitive to
acceleration, but is sensitive to angular velocity, its performance parameters need follow-up experiments.
XU Zhong-xing (许仲兴), ZHANG Wei-ping*(张卫平), TANG Jian (唐健), ZHANG Gong (张弓),CHENG Yu-xiang (成宇翔), CHEN Wen-yuan (陈文元), GUAN Ran (关冉)
. A Micro-Electro-Mechanical System-Based Bulk Acoustic Wave Piezoelectric Disk Resonator for Detecting z-axis Rotation Rate[J]. Journal of Shanghai Jiaotong University(Science), 2015
, 20(3)
: 286
-292
.
DOI: 10.1007/s12204-015-1623-x
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