Control and damping imperfection compensation for a rate integrating MEMS gyroscope

2015 DGON Inertial Sensors and Systems Symposium (ISS) Pub Date : 2015-11-02 DOI:10.1109/INERTIALSENSORS.2015.7314258

Zhongxu Hu, B. Gallacher

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引用次数: 17

Abstract

This paper presents a DSP based control implementation for a ring type MEMS vibratory gyroscope operating in rate integrating mode, under which, drift rate of the precession angle is reduced to less than 2.5 degrees/second. An automatic electrostatic frequency tuning process is developed to minimize frequency split to a few mille Hertz, which helps the PLL to accurately lock the orbit phase at -90 degrees with phase error less than 0.1 degrees. While a velocity feedback based vibration sustaining control stabilizes the major axis against the average damping, a displacement feedback control for quadrature nulling effectively suppresses the Quad amplitude to less than one thousandth of the major axis, so that the trajectory of vibration remains almost a straight line. Damping imperfections, the amount and distribution along the precession angle are visualized and approximately estimated using the modulation pattern of the control gain of the vibration sustaining loop. These values are then placed in the velocity feedback compensation control to reduce angle drift. Experimental results validate its effectiveness.

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速率积分MEMS陀螺仪的控制和阻尼缺陷补偿

本文提出了一种基于DSP的环型MEMS振动陀螺仪的控制实现方法，该控制方法可以将进动角的漂移率降低到小于2.5度/秒。开发了一种自动静电频率调谐工艺，将频率分裂减小到几兆赫兹，有助于锁相环精确地将轨道相位锁定在-90度，相位误差小于0.1度。基于速度反馈的减振控制在平均阻尼下稳定长轴，而用于正交零的位移反馈控制有效地将四轴振幅抑制到小于长轴的千分之一，从而使振动轨迹几乎保持直线。利用维持振动回路控制增益的调制模式，对系统的阻尼缺陷、数量和沿进动角的分布进行了可视化和近似估计。然后将这些值置于速度反馈补偿控制中以减少角度漂移。实验结果验证了该方法的有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2015 DGON Inertial Sensors and Systems Symposium (ISS)

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