光纤陀螺仪中光纤与环境相互作用的严格处理

2008 IEEE Region 8 International Conference on Computational Technologies in Electrical and Electronics Engineering Pub Date : 2008-07-21 DOI:10.1109/SIBIRCON.2008.4602634

F. Mohr, F. Schadt

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引用次数: 10

摘要

光纤陀螺仪的热效应和弹性力学效应是误差信号的主要来源，主要由Shupe和Mohr处理。利用Shupepsilas非互易公式计算光纤陀螺仪的热致偏倚误差已成为一种标准。这种效应是由在材料中传播的热波引起的。然而，Shupe公式并没有描述纤维线圈的均匀加热效应，而是描述纤维线圈的瞬态加热效应，这将导致纤维的不均匀变形，从而导致非互易。此外，惯性力(如振动)的影响已在Mohr和Schadt(2004)的工作中首次描述，并将在此贡献中进行扩展。Wepsilall用解析法和(必要时)有限元法描述了光纤线圈的仿真模型。最后，我们将用光纤陀螺的测量结果验证我们的仿真模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Rigorous treatment of fiber-environmental interactions in fiber gyroscopes

Thermal and elastomechanical effects on fiber optic gyroscopes (FOGs) are a major source of error signals and have been dealt with mainly by Shupe and Mohr. It has become a standard to use Shupepsilas nonreciprocity formula for calculating the thermally induced bias error in fibre gyroscopes. This effect is initiated by thermal waves propagating through the material. However, the Shupe formula does not describe the effect of homogeneous, but transient heating of the fiber coil, which leads to an inhomogeneous deformation of the fibers and thus to nonreciprocity. Furthermore, the effect of inertial forces such as vibrations has been described first in the work of Mohr and Schadt (2004) and shall be extended in this contribution. Wepsilall describe a simulation model of the fiber coil using analytical and - where necessary - finite element methods. Finally, wepsilall verify our simulation model with measurement results from an FOG.

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2008 IEEE Region 8 International Conference on Computational Technologies in Electrical and Electronics Engineering

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