Temperature Characteristics and Error Compensation for Quartz Flexible Accelerometer

Reduction of error due to the influence of temperature on the quartz flexible accelerometer without any heating device is a difficult task, and is also a tendency for research and application. In this paper, static and dynamic temperature compensation models are established in order to reduce the te...

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Bibliographic Details
Published inInternational journal of automation and computing Vol. 12; no. 5; pp. 540 - 550
Main Authors Gao, Jing-Min, Zhang, Ke-Bei, Chen, Fu-Bin, Yang, Hong-Bo
Format Journal Article
LanguageEnglish
Published Beijing Institute of Automation, Chinese Academy of Sciences 01.10.2015
Springer Nature B.V
Subjects
Acceleration;error
Accelerometers
Accuracy
Algorithms
CAE) and Design
charac
compensation;temperature
Computer Applications
Computer-Aided Engineering (CAD
Control
Engineering
Error compensation
Error reduction
Experiments
Mechatronics
Neural networks
Quadratures
Quartz
Regular Paper
Robotics
Scaling factors
Sensors
Temperature
Temperature compensation
error compensation
quadrature experiment
differential mode
Acceleration
temperature characteristics
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Summary:Reduction of error due to the influence of temperature on the quartz flexible accelerometer without any heating device is a difficult task, and is also a tendency for research and application. In this paper, static and dynamic temperature compensation models are established in order to reduce the temperature influence on accelerometer measurement accuracy. Combined with the experiment data, the relationship between the accelerometer output accuracy, temperature and the magnitude of acceleration is analyzed. The data collected from the temperature experiment show that output value of the accelerometer varies with temperature. The method of uniaxial quadrature experiment is adopted and the accelerometer output value is gauged at temperature ranging from-20℃ to 50℃. Having used the static and the dynamic temperature compensation models, the accelerometer temperature error compensation experiment is conducted and the compensated errors by the two models are analyzed. The result shows that the compensated value meets the technical requirements. Two technical indicators, the zero bias K0 and the scaling factor K1, which are used to measure the degree of accelerometers, are both improved and their fluctuation ranges are reduced.
Bibliography:Jing-Min Gao;Ke-Bei Zhang;Fu-Bin Chen;Hong-Bo Yang;Electronic Information and Control Center, Beijing Information Science & Technology University;Beijing Institute of Control Engineering;School of Automation, Beijing Information Science & Technology University
11-5350/TP
Acceleration;error compensation;temperature charac
Reduction of error due to the influence of temperature on the quartz flexible accelerometer without any heating device is a difficult task, and is also a tendency for research and application. In this paper, static and dynamic temperature compensation models are established in order to reduce the temperature influence on accelerometer measurement accuracy. Combined with the experiment data, the relationship between the accelerometer output accuracy, temperature and the magnitude of acceleration is analyzed. The data collected from the temperature experiment show that output value of the accelerometer varies with temperature. The method of uniaxial quadrature experiment is adopted and the accelerometer output value is gauged at temperature ranging from-20℃ to 50℃. Having used the static and the dynamic temperature compensation models, the accelerometer temperature error compensation experiment is conducted and the compensated errors by the two models are analyzed. The result shows that the compensated value meets the technical requirements. Two technical indicators, the zero bias K0 and the scaling factor K1, which are used to measure the degree of accelerometers, are both improved and their fluctuation ranges are reduced.
ISSN:1476-8186
2153-182X
1751-8520
2153-1838
DOI:10.1007/s11633-015-0899-5