Abstract
A micromachined electrostatically-suspended accelerometer (MESA) is a kind of three-axis inertial sensor based on fully-contactless electrostatic suspension of the proof mass (PM). It has the potential to offer broad bandwidth, high sensitivity, wide dynamic range and, thus, would be perfectly suited for land seismic acquisition. Previous experiments showed that it is hard to lift up the PM successfully during initial levitation as the mass needs to be levitated simultaneously in all six degrees of freedom (DoFs). By analyzing the coupling electrostatic forces and torques between three lateral axes, it is found there exists a self-locking zone due to the cross-axis coupling effect. To minimize the cross-axis coupling and solve the initial levitation problem, this paper proposes an effective control scheme by delaying the operation of one lateral actuator. The experimental result demonstrates that the PM can be levitated up with six-DoF suspension operation at any initial position. We also propose a feed-forward compensation approach to minimize the negative stiffness effect inherent in electrostatic suspension. The experiment results demonstrate that a more broadband linear amplitude-frequency response and higher suspension stiffness can be achieved, which is crucial to maintain high vector fidelity for potential use as a three-component MEMS geophone. The preliminary performance tests of the three-axis linear accelerometer were conducted under normal atmospheric pressure and room temperature. The main results and noise analysis are presented. It is shown that vacuum packaging of the MEMS sensor is essential to extend the bandwidth and lower the noise floor, especially for low-noise seismic data acquisition.
Highlights
Micromachined accelerometers are widely used in numerous areas, such as inertial navigation systems, smartphones, vehicle safety, tomography studies in oil and gas exploration, etc. [1,2,3,4].In some situations, ultra-sensitive accelerometers are demanded to sense extremely weak motion or vibration information, such as the measurement of very weak acceleration in space missions [5,6]and land seismic wave acquisition [7,8,9]
The characteristics of the three-axis micro-electrical-mechanical system (MEMS) accelerometer have been tested for the device
MEMS and accelerometer have been for the device operated operated under normal atmospheric room temperature
Summary
Micromachined accelerometers are widely used in numerous areas, such as inertial navigation systems, smartphones, vehicle safety, tomography studies in oil and gas exploration, etc. [1,2,3,4].In some situations, ultra-sensitive accelerometers are demanded to sense extremely weak motion or vibration information, such as the measurement of very weak acceleration in space missions [5,6]and land seismic wave acquisition [7,8,9]. Ultra-sensitive accelerometers are demanded to sense extremely weak motion or vibration information, such as the measurement of very weak acceleration in space missions [5,6]. An electrostatically-suspended accelerometer (ESA) usually employs a free proof mass (PM) levitated fully by capacitive position-sensing and electrostatic-forcing feedback, and can offer ultra-high resolutions better than pico-g in micro-gravity space applications by largely decreasing their measuring ranges below micro-g [6]. Several micromachined electrostatically-suspended accelerometers (MESAs) have been reported based on micro-electrical-mechanical system (MEMS). The operation principle of this servo-controlled accelerometer is based on the measurement of the electrostatic force necessary to maintain the PM motionless with respect to the sensor case. The commercialized three-component (3C) geophones in land seismic sensing [19,20], such as DSU3 from Sercel (Carquefou Cedex, France) and SF3600 from
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
