Paper Titles
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Preface
Design and Implement of Attitude Sensor for High-Speed-Spin Vehicle
p.1
The Research of Micromachined Gas Pendulum Accelerometer’s Structure
p.7
Research on Signal Demodulation Method of Silicon Micro-Machined Gyroscope
p.11
Analyses on Output Signal of Silicon Micro-Machined Gyroscope
p.17
Study on the Objectives of SCM in E-Commerce Based on ERP Application
p.22
Study on Models of Planning and Scheduling in IT Manufacturing Processes
p.28
Research on Vibration and Shock-Proof Technology of Silicon Micro-Machined Gyroscope
p.34

Design and Implement of Attitude Sensor for High-Speed-Spin Vehicle

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Abstract:

In order to detect the rolling、pitch and yaw angle of high-speed-spin vehicle, a novel attitude sensor system is designed by using a digital signal processor TMS320F2812. The configuration of the sensor consists of two MEMS sensing elements and signal processing circuit and micro-processor. A new silicon MEMS gyroscope based on the Coriolis effect can sense three angular rate of spin vehicle, which can provide a synthesis signal, including roll, yaw and pitch angular rate. And a MEMS accelerometer reacts on demodulating the three angular rates. The design of the hardware circuit, the algorithm and implement of software are presented. The demodulation algorithm is validated by simulation experiment on the ground and the experimental results are presented.

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Periodical:

Applied Mechanics and Materials (Volumes 20-23)

Pages:

1-6

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.20-23.1

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Cite this paper

Online since:

January 2010

Authors:

Li Feng Wu, Z. Peng, Qing Wen Yan, Wei Zhang, Fu Xue Zhang

Keywords:

Angular Rate, Attitude Sensor, MEMS Gyroscope, Pitch, Yaw

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© 2010 Trans Tech Publications Ltd. All Rights Reserved

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References

[1] MU Shu-zhi , BU Xiong-zhu , L I Yong-xin , WAN Gjin-song. Research on Inertial Measurement Unit of High Rotation Vehicle. Journal of Ballistics, 8(4): 88-88, ( 2006).

Google Scholar

[2] Lee Sou-Chen, Huang Yu-Chao. Innovative estimation method with measurement likelihood for all-accelerometer type inertial navigation system. IEEE Transactions on Aerospace and Electronic Systems, 38(1): 339-346, (2002).

DOI: 10.1109/7.993257

Google Scholar

[3] Li Qin, Wendong Zhang, Huixin Zhang, Weixing Xu. Attitude measurement system based on micro-silicon accelerometer array. Chaos, Solitons & Fractals, 29(1): 141-147, ( 2006).

DOI: 10.1016/j.chaos.2005.08.014

Google Scholar

[4] A Gallagher, Y Matsuoka, W T Ang. An efficient real-time human posture tracking algorithm using low-cost inertial and magnetic sensors . / Proceedings of 2004 IEEE/RSJ. Sendai, Japan, 2004: 2967-2972.

DOI: 10.1109/iros.2004.1389860

Google Scholar

[5] C F Kao, T L Chen. Design and analysis of an orientation estimation system using coplanar gyro-free inertial measurement unit and magnetic sensors. Sensors and Actuators A, 144(2): 251-262, (2008).

DOI: 10.1016/j.sna.2008.02.008

Google Scholar

[6] Soderkvist Jan. Micromachined gyroscopes. Sensors and Actuators A: Physical, 43(1-3): 65-71, (1994).

Google Scholar

[7] B. Boxhorn et. al. A vibratory micromechanical gyroscope. Proc. Navigation and Control Conference Minneapolis, Minnesota, 1033-1040, (1998).

Google Scholar

[8] S. An Y, et al.,. Dual-axis microgyroscope with closed-loop detection. Proc. IEEE MicroElectroMechanical Workshop, Heidelberg, Germany, 328-333, (1998).

Google Scholar

[9] Ibrahim, Hassan E.A. Electrostatic gyroscope pull-in study and optimum dimensions using genetic optimization. AEJ - Alexandria Engineering Journal, 44(6): 845-853, (2005).

Google Scholar

[10] Gretillat, Florence, et al. Improved design of a silicon micromachined gyroscope with piezoresistive detection and electromagnetic excitation. Journal of Microelectromechanical Systems, 8(3): 243-250, (1999).

DOI: 10.1109/84.788627

Google Scholar

[11] Lee Sang-Hun, Hong Seung-Wan, Kim Yong-Kweon, Lee Seung-Ki. Planar vibratory gyroscope using electromagnetic force. Sensors and Actuators A: Physical, 65(2-3): 101-108, (1998).

DOI: 10.1016/s0924-4247(97)01670-1

Google Scholar

[12] Wu X. -S, Chen W. -Y, Zhao X. -L., Zhang W. -P. Micromachined rotating gyroscope with electromagnetically levitated rotor. Electronics Letters, 42(16): 912-913, (2006).

DOI: 10.1049/el:20061479

Google Scholar

[13] Bhadbhade, Vikrant, Jalili, Nader, Nima Mahmoodi, S. A novel piezoelectrically actuated flexural/torsional vibrating beam gyroscope. Journal of Sound and Vibration, 311(3-5): 1305-1324, (2008).

DOI: 10.1016/j.jsv.2007.10.017

Google Scholar

[14] Kagawa, et. al. A tubular piezoelectric vibrator gyroscope. IEEE Sensors Journal, 6(2) : 325-330, (2006).

DOI: 10.1109/jsen.2006.870163

Google Scholar