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Proceedings Paper

Temperature compensation for RLG based on neural network
Author(s): Pengxiang Yang; Yongyuan Qin; Jinchuan You
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Paper Abstract

Several static tests indicate that the Ring Laser Gyro (RLG) bias inside of the Strap-down Inertial Navigation System (SINS) varies remarkably as long time working. Further experiments and analyzing results show that the SINS external metal shell could insure the inside temperature rising gently and evenly, and the RLG drifts could be viewed mainly affected by RLG inside temperature field. In order to achieve better RLG stability characteristic within full temperature range, investigated the BP and RBF Artificial Neural Networks (ANN) nonlinear modeling and compensation technology. Firstly, introduced two typical structures for BP and RBF neural networks, and then, take a set of static tests data from 25 °C to 55 °C as training samples, separately built up four-layer BP and two-layer RBF neural networks for RLG drifts. In order to compare the compensation effects, first-order and second-order piecewise Least Square (LS) fitting technologies are also implemented here. Four new experimental data were adopted to check the modeling validity. The compensation results show that the RLG drifts stability could be improved by 20%-40%; the precision of BP network modeling method is better than that of first-order linear piecewise LS fitting, and the precision of RBF is better than that of second-order piecewise LS fitting.

Paper Details

Date Published: 31 December 2010
PDF: 7 pages
Proc. SPIE 7544, Sixth International Symposium on Precision Engineering Measurements and Instrumentation, 75444J (31 December 2010); doi: 10.1117/12.885310
Show Author Affiliations
Pengxiang Yang, Northwestern Polytechnical Univ. (China)
Yongyuan Qin, Northwestern Polytechnical Univ. (China)
Jinchuan You, Northwestern Polytechnical Univ. (China)

Published in SPIE Proceedings Vol. 7544:
Sixth International Symposium on Precision Engineering Measurements and Instrumentation
Jiubin Tan; Xianfang Wen, Editor(s)

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