Title :
In-run bias self-calibration for low-cost MEMS vibratory gyroscopes
Author :
Prikhodko, Igor P. ; Gregory, Jeffrey A. ; Merritt, Carey ; Geen, John A. ; Chang, Joana ; Bergeron, Jarrah ; Clark, William ; Judy, Michael W.
Author_Institution :
Inertial MEMS & Sensors Technol., Analog Devices Inc., Wilmington, MA, USA
Abstract :
We present a method for improving bias instability and Rate Random Walk (RRW) in low-cost MEMS vibratory gyroscopes by periodically reversing polarity of the resonator drive force, yielding a 5 times reduction of RRW noise. The feasibility of the approach was experimentally evaluated using an in-production Analog Devices ADXRS800, a fully integrated MEMS gyroscope with a quadruple mass architecture. The proposed method is to use periods of alternating co-phase and anti-phase drive clock to drive-mode oscillation periods, and sampling the gyroscope sense-mode output during the equal times of co-phase anti-phase drive of the resonator, thereby canceling the drive alignment bias error term. The proposed self-calibration method allows for long and short term stability improvement in low-cost and high performance MEMS vibratory gyroscopes.
Keywords :
calibration; gyroscopes; micromechanical devices; RRW noise; antiphase drive clock; bias instability; cophase drive clock; drive-mode oscillation periods; in-production analog devices ADXRS800; in-run bias self-calibration; long term stability improvement; low-cost MEMS vibratory gyroscopes; quadruple mass architecture; rate random walk; resonator drive force; short term stability improvement; Bandwidth; Gyroscopes; Micromechanical devices; Noise; Real-time systems; Sensor fusion;
Conference_Titel :
Position, Location and Navigation Symposium - PLANS 2014, 2014 IEEE/ION
Conference_Location :
Monterey, CA
Print_ISBN :
978-1-4799-3319-8
DOI :
10.1109/PLANS.2014.6851411
