Bias thermal stability improvement of MEMS gyroscope with quadrature motion correction and temperature self‐sensing compensation
Jian Cui, Qiancheng Zhao
Abstract
Bias thermal stability of microelectromechanical system (MEMS) gyroscope is a significant performance parameter for industrial and tactical applications. The quadrature coupling motion and demodulation phase error are two main sources of bias drift. This work presents a MEMS tuning fork gyroscope with dedicated electrostatic correction combs finger structure that can be implemented to suppress the quadrature motion. By utilising a closed‐loop control for the coupling stiffness, the temperature variation of quadrature motion achieves >260 times of magnitude reduction, resulting in the thermal bias drift decreased from 0.98 to 0.18°/s with 5.4 times improvement over the temperature from −40 to 60°C. The results indicate that the variation of the quadrature motion is the dominant factor that determines the temperature bias drift of the custom‐designed gyroscope. The compensated bias stability (1 σ ) is measured to be ∼8.6°/h by using temperature self‐sensing compensation technique over the whole temperature operating range, which demonstrates a considerably competitive result for the tactical‐grade MEMS gyroscope.