A Temperature Drift Suppression Method of Mode-Matched MEMS Gyroscope Based on a Combination of Mode Reversal and Multiple Regression

In recent years, the application prospects of high-precision MEMS gyroscopes have been shown to be very broad, but the large temperature drift of MEMS gyroscopes limits their application in complex temperature environments. In response to this, we propose a method that combines mode reversal and rea...

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Autores principales: Chen, Liangqian, Miao, Tongqiao, Li, Qingsong, Wang, Peng, Wu, Xuezhong, Xi, Xiang, Xiao, Dingbang
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2022
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Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9611125/
https://www.ncbi.nlm.nih.gov/pubmed/36295910
http://dx.doi.org/10.3390/mi13101557
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author Chen, Liangqian
Miao, Tongqiao
Li, Qingsong
Wang, Peng
Wu, Xuezhong
Xi, Xiang
Xiao, Dingbang
author_facet Chen, Liangqian
Miao, Tongqiao
Li, Qingsong
Wang, Peng
Wu, Xuezhong
Xi, Xiang
Xiao, Dingbang
author_sort Chen, Liangqian
collection PubMed
description In recent years, the application prospects of high-precision MEMS gyroscopes have been shown to be very broad, but the large temperature drift of MEMS gyroscopes limits their application in complex temperature environments. In response to this, we propose a method that combines mode reversal and real-time multiple regression compensation to compensate for the temperature drift of gyroscope bias. This method has strong adaptability to the environment, low computational cost, the algorithm is online in real time, and the compensation effect is good. The experimental results show that under the temperature cycle of −20~20 °C and the temperature change rate of 4 °C/min, the method proposed in this paper can reduce the zero-bias stability from about 27.8°/h to 0.4527°/h, and the zero-bias variation is reduced from 65.88°/h to 1.43°/h. This method improves the zero-bias stability of the gyroscope 61-fold and the zero-bias variation 46-fold. Further, the method can effectively suppress the zero-bias drift caused by the heating of the gyroscope during the start-up phase of the gyroscope. The zero-bias stability of the gyroscope can reach 0.0697°/h within 45 min of starting up, and the zero-bias repeatability from 0 to 5 min after startup is reduced from 0.629°/h to 0.095°/h.
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spelling pubmed-96111252022-10-28 A Temperature Drift Suppression Method of Mode-Matched MEMS Gyroscope Based on a Combination of Mode Reversal and Multiple Regression Chen, Liangqian Miao, Tongqiao Li, Qingsong Wang, Peng Wu, Xuezhong Xi, Xiang Xiao, Dingbang Micromachines (Basel) Article In recent years, the application prospects of high-precision MEMS gyroscopes have been shown to be very broad, but the large temperature drift of MEMS gyroscopes limits their application in complex temperature environments. In response to this, we propose a method that combines mode reversal and real-time multiple regression compensation to compensate for the temperature drift of gyroscope bias. This method has strong adaptability to the environment, low computational cost, the algorithm is online in real time, and the compensation effect is good. The experimental results show that under the temperature cycle of −20~20 °C and the temperature change rate of 4 °C/min, the method proposed in this paper can reduce the zero-bias stability from about 27.8°/h to 0.4527°/h, and the zero-bias variation is reduced from 65.88°/h to 1.43°/h. This method improves the zero-bias stability of the gyroscope 61-fold and the zero-bias variation 46-fold. Further, the method can effectively suppress the zero-bias drift caused by the heating of the gyroscope during the start-up phase of the gyroscope. The zero-bias stability of the gyroscope can reach 0.0697°/h within 45 min of starting up, and the zero-bias repeatability from 0 to 5 min after startup is reduced from 0.629°/h to 0.095°/h. MDPI 2022-09-20 /pmc/articles/PMC9611125/ /pubmed/36295910 http://dx.doi.org/10.3390/mi13101557 Text en © 2022 by the authors. https://creativecommons.org/licenses/by/4.0/Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Chen, Liangqian
Miao, Tongqiao
Li, Qingsong
Wang, Peng
Wu, Xuezhong
Xi, Xiang
Xiao, Dingbang
A Temperature Drift Suppression Method of Mode-Matched MEMS Gyroscope Based on a Combination of Mode Reversal and Multiple Regression
title A Temperature Drift Suppression Method of Mode-Matched MEMS Gyroscope Based on a Combination of Mode Reversal and Multiple Regression
title_full A Temperature Drift Suppression Method of Mode-Matched MEMS Gyroscope Based on a Combination of Mode Reversal and Multiple Regression
title_fullStr A Temperature Drift Suppression Method of Mode-Matched MEMS Gyroscope Based on a Combination of Mode Reversal and Multiple Regression
title_full_unstemmed A Temperature Drift Suppression Method of Mode-Matched MEMS Gyroscope Based on a Combination of Mode Reversal and Multiple Regression
title_short A Temperature Drift Suppression Method of Mode-Matched MEMS Gyroscope Based on a Combination of Mode Reversal and Multiple Regression
title_sort temperature drift suppression method of mode-matched mems gyroscope based on a combination of mode reversal and multiple regression
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9611125/
https://www.ncbi.nlm.nih.gov/pubmed/36295910
http://dx.doi.org/10.3390/mi13101557
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