MEMS陀螺随机误差特性研究及补偿 -

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MEMS陀螺随机误差特性研究及补偿

doi:10.3788/CO.20160904.0501

中国科学院长春光学精密机械与物理研究所, 吉林长春 130033

基金项目:

国家自然科学基金资助项目No.51305421

详细信息

通讯作者:
张玉莲(1991-),女,山东济宁人,硕士,研究实习员,主要从事惯性导航系统方面的研究。E-mail:yulian-2009@163.com

中图分类号:V249.322
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- 被引次数:0
出版历程
- 收稿日期:2016-02-29
- 修回日期:2016-04-14
- 刊出日期:2016-08-01

Characterists and compensation method of MEMS gyroscope random error

Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun 130033, China

Funds:

National Natural Science Foundation of ChinaNo.51305421

More Information

Corresponding author:E-mail:yulian-2009@163.com

摘要

摘要:为了提高MEMS陀螺输出角速度的精度，采用Allan分析法以及Kalman滤波算法对MEMS陀螺仪进行随机误差分析和补偿。由Allan方差分析陀螺的输出数据，对Allan方差进行最小二乘法拟合，得到各项随机噪声的定量评价指标；对陀螺的输出数据使用AR模型进行数学建模，采用AIC准则确定了AR模型的阶次，建立了陀螺零漂数据的离散时间表达式；在AR模型所建立的陀螺随机误差模型的基础上，设计了Kalman滤波器，对陀螺输出数据使用Kalman算法进行了滤波处理，对陀螺的随机误差进行了补偿；通过Allan方差对Kalman算法对陀螺随机误差的补偿效果进行分析。实验结果表明：角速率随机游走Kalman滤波前为0.1487°/$\sqrt{h}$，Kalman滤波补偿后为0.0041°/$\sqrt{h}$，通过补偿可减小97.24%的角速率随机游走误差；零偏不稳定性Kalman滤波前为1.9408°/h，Kalman滤波补偿后为0.0542°/h，通过补偿可减小97.21%的零偏不稳定性误差；速率随机游走Kalman滤波前为2.6985°/h ^{$\frac{3}{2}$}，Kalman滤波补偿后为0.3343°/h ^{$\frac{3}{2}$}，通过补偿可减小87.61%的速率随机游走误差。Kalman滤波适用于MEMS陀螺的滤波处理，可有效降低陀螺的随机误差。
- MEMS陀螺/
- 随机误差/
- Allan方差/
- AR模型/
- Kalman滤波
Abstract:In order to improve the accuracy of MEMS gyro angular velocity, Allan analysis and Kalman filter algorithm are used to analyze and compensate the random error of MEMS gyroscope. First, Allan variance is used to analyze the gyro output data, and least squares algorithm is used to fit Allan variance. A quantitative evaluation of the random noise is obtained. Then, AR model is applied to set up a mathematical model of gyro output data, and AIC criterion is used to determine the order of the AR model, establishing a discrete time expression of gyro drift data. After that, the Kalman filter is designed based on gyro random error model established by AR model, and Kalman filtering algorithm is used for filtering processing of gyro output data. The random error of gyro can be compensated. Finally, the compensation effect of Kalman algorithm for the gyro random error is analyzed through Allan variance. Experimental results indicate that after compensation of Kalman filter the angular random walk is reduced by 97.24% from 0.148 7°/$\sqrt{h}$ to 0.004 1°/$\sqrt{h}$, the bias instability is reduced by 97.21% from 1.940 8°/h to 0.0542°/h, and rate random walk is reduced by 87.61% from 2.6985°/h ^{$\frac{3}{2}$}to 0.3343°/h ^{$\frac{3}{2}$}. Kalman filter can be well applied to filtering process of MEMS gyroscope, and it can effectively reduce the gyro random error.
- MEMS gyrocope/
- random error/
- Allan variance/
- AR model/
- Kalman filter

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图 1陀螺随机误差辨识典型Allan方差曲线

Figure 1.Typical Allan variance curve of Gyro random error identification

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图 2陀螺仪测试原理框图

Figure 2.Principle frame chart of gyro test

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图 3MEMS陀螺仪测试平台

Figure 3.Test platform of MEMS gyro

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图 4MSG1100D陀螺输出原始数据

Figure 4.Output raw data of MSG1100D gyro

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图 5MSG1100D的Allan标准差及其拟合曲线

Figure 5.MSG1100D′s Allan standard deviation and it′s fitting curve

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图 6MEMS陀螺随机误差Kalman滤波效果图

Figure 6.Kalman filtering of MEMS Gyro random error

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图 7Kalman滤波前后Allan标准差对比曲线

Figure 7.Allan standard deviation contrast curves before and after Kalman filtering

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图 8动态下MEMS陀螺随机误差Kalman滤波效果图

Figure 8.Kalman filtering effect of MEMS gyro random error under dynamic condition

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表 1MSG1100D陀螺的各项随机误差统计表

Table 1.Random error statistics of MSG1100D gyro

随机误差项	结果
量化噪声Q/urad	3.643 1×10^-5
角随机游走N/(°/ $\sqrt{h}$ )	0.148 7
零偏不稳定性B/(°/h)	1.940 8
速率随机游走K/(°/h^{$\frac{3}{2}$})	2.698 5
速率斜坡R/(°/h²)	24.167 9

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表 2AR模型拟合系数

Table 2.Fitting coefficients of AR model

Model	φ₁	φ₂	φ₃	AIC
AR(1)	0.123 5	0	0	-7.341 6
AR(2)	0.123 7	0.001 9	0	-7.341 6
AR(3)	0.124	0.017 76	0.128 1	-7.358 1

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表 3滤波前后数据均值和方差对比

Table 3.Comparison of mean values and variance before and after filtering

参数	均值/(°/s)	方差/(°/s)²
滤波前	7×10^-3	6.087 8×10^-4
滤波后	1.952 4×10^-4	3.737 3×10^-7

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表 4Kalman滤波后陀螺的各项随机误差统计表

Table 4.Statistics of gyro random errors after Kalman filter

随机误差项	滤波后结果	随机误差降低百分比/%
量化噪声Q/urad	4.1×10^-6	88.75
角随机游走N/(°/ $\sqrt{h}$ )	0.0041	97.24
零偏不稳定性B/(°/h)	0.054 2	97.21
速率随机游走K/(°/h^{$\frac{3}{2}$})	0.334 3	87.61
速率斜坡R/(°/h²)	6.156 3	74.53

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