Abstract
Frequency response of a laser gyroscope was studied by numerical modeling of a complete system of equations describing it. The calculation results are compared to the results of experimental measurements taken on a precision dynamic test bench. The frequency response was measured for a gyroscope based on a four-mirror ring laser with a non-planar contour, operating on He–Ne active mix at the wavelength of 632.8 nm. In the gyroscope under study, the sign-variable dither was implemented on the basis of Zeeman magnetooptical effect. The relationship between the measured and designed values of the frequency response distortions has been found. The relationship between the frequency response distortions in a laser gyroscope and inequality of field intensities of the counter-propagating waves (CPW) has been numerically calculated and confirmed by experiments. Based on the research results, the parameters of a ring laser can be optimized to improve the accuracy of measurements by means of laser gyroscopes.
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ACKNOWLEDGMENTS
The authors are grateful to A.P. Makeev for his assistance in performing the numerical calculations and obtaining the experimental results, and to E.A. Petrukhin for initiating the interest in the problem being solved in this paper, as well as for useful discussions and assistance in the work.
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Azarova, V.V., Golyaev, Y.D. & Kuznetsov, E.V. Effect of Unequal Intensities of Counter-Propagating Waves on the Frequency Response of Laser Gyroscopes. Gyroscopy Navig. 11, 285–292 (2020). https://doi.org/10.1134/S2075108720040021
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DOI: https://doi.org/10.1134/S2075108720040021