Micro-Machined Gyroscope Mathematical Model and Error Analysis

Miao Wen Deng; Bing Mo; Chao Dong Ling; Rong Hai Huang; Su Ki Kim

doi:10.4028/www.scientific.net/KEM.609-610.1144

Paper Titles

The Design of Lead Compensator for ΣΔ Micromachined Accelerometer
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High Precision Double-Interferometry for Large Step-Height On-Line Measurement Using Waveform Transforming Technology
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Accuracy Analysis of Quality Factor Measurement Based on Time Domain Method for MEMS Resonators
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A Novel Noise Reduction Algorithm of MEMS Gyroscope Based on Compressive Sensing and Lifting Wavelet Transform
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Micro-Machined Gyroscope Mathematical Model and Error Analysis
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Finite Element Analysis on Thermosonic Ball Bonding Process of MEMS Chip
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Lateral Resolution Test for Confocal Laser Scanning Microscope
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Fabrication and Packaging of Electromagnetic 2D MEMS Scanning Mirror
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 609-610Micro-Machined Gyroscope Mathematical Model and...

Micro-Machined Gyroscope Mathematical Model and Error Analysis

Abstract:

Abstract:The micro-machined gyroscope that uses Coriolis force to measure angular velocity has non-linear error,which makes the amplitude of angular velocity have a relationship with its frequency,and fabrication technology error,which leads gyroscope’s drive shaft and detection shaft not to be vertical.All kinds of errors severely restrict this kind of gyroscope’s measuring accuracy and application range.This article obtained the reason for the formation of all kind of gyroscope’s errors and their mathematical expressions through analyzing the principle of micromachined gyroscope,which uses Coriolis force to measure angular velocity.At the same time,the gyroscope mathematical model was established and used to emulate to analyze each error’s influence on the angular velocity measured by gyroscope.The conclusion obtained by theoretical analysis and simulation provides the basis for gyroscope’s error analysis and elimination,and it has an important significance in improving the measuring accuracy of gyroscope.

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Periodical:

Key Engineering Materials (Volumes 609-610)

Pages:

1144-1152

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.609-610.1144

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Online since:

April 2014

Authors:

Miao Wen Deng, Bing Mo*, Chao Dong Ling, Rong Hai Huang, Su Ki Kim

Keywords:

Gyroscope Error Analysis, Gyroscope Kinetic Equation, Gyroscope Working Principle, Micro-Machined Gyroscope, Micro-Machined Gyroscope Mathematical Model

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* - Corresponding Author

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