Title :
Frequency-Mismatch-Tolerant Silicon Vibratory Gyroscope without Vacuum Package for Automotive Applications
Author :
Zhang, Huisui ; Zou, Qiang ; Eun Sok Kim ; Madni, Asad M. ; Costlow, Lynn E. ; Wells, Roger F.
Author_Institution :
Southern California Univ., Los Angeles
Abstract :
This paper describes a low-cost silicon vibratory gyroscope that tolerates a relatively large mismatch between the driving-mode and sensing-mode frequencies. The gyroscope is based on beam-mass structure and realized by one silicon proof mass and two beams for the driving and sensing mode. Piezoelectric actuation is used to produce a large driving mode vibration displacement (about 100 mum) with about 32 Vpeak-to-peak. Two tiny sensing beams are separated from the vertical silicon beam to increase the sensitivity while keeping the sensing-mode resonant frequency high. Piezoresistive and piezoelectrical sensing mechanisms are applied to two different gyroscopes. The gyroscope operating at 1-4 kHz is capable of sub-degree-per-second angular rate sensitivity without any vacuum package.
Keywords :
automobiles; beams (structures); gyroscopes; piezoelectric actuators; silicon; vibrations; automotive applications; beam-mass structure; driving mode vibration displacement; driving-mode frequencies; frequency 1 kHz to 4 kHz; frequency-mismatch-tolerance; piezoelectric actuation; piezoelectrical sensing mechanisms; piezoresistive sensing mechanisms; sensing beams; sensing-mode frequencies; silicon vibratory gyroscope; Automotive applications; Automotive engineering; Control systems; Electronics packaging; Gyroscopes; Piezoresistance; Q factor; Resonant frequency; Silicon; Size control; Frequency Match; Frequency Tolerance; Gyroscope; Piezoelectric Actuation;
Conference_Titel :
Automation Congress, 2006. WAC '06. World
Conference_Location :
Budapest
Print_ISBN :
1-889335-33-9
DOI :
10.1109/WAC.2006.375967
