Improved Algorithm for Mathematical Correction of the Zero Drift of the Zeeman Laser Gyro with Switching Longitudinal Mode of Generation
| Authors: Kolbas Yu.Yu., Ivanov M.A. | Published: 17.04.2019 |
| Published in issue: #2(125)/2019 | |
| DOI: 10.18698/0236-3933-2019-2-91-103 | |
| Category: Instrument Engineering, Metrology, Information-Measuring Instruments and Systems | Chapter: Navigation Instruments | |
| Keywords: laser gyroscope, Zeeman effect, zero drift, temperature dependence, temperature sensor | |
The paper addresses time and temperature zero drifts in Zeeman laser gyroscope (RLG) operating in the mode of periodic adjustment of RLG to the longitudinal mode of generation with the opposite circular polarization of the light wave. In such a gyroscope, the zero drift can be divided into magnetic and non-magnetic components having different nature and making a significantly different contribution to the final error. Algorithmic methods are proposed for mathematical compensation of RLG zero drift, both with and without using initial calibration. It is shown that the simultaneous use of reproducible dependencies of the magnetic and non-magnetic zero drifts due to RLG temperature changes allows solving the problem of RLG zero drift correction in the optimal way. The correction factors are calculated from the temperature of a Zeeman laser gyro at the moment of activation. At the same time, using the difference between the temperatures of the gyroscope and gyro case, where it is installed, it is possible to determine the temperature of the Zeeman laser gyroscope at the moment of switching on, thereby eliminating the problem of calculating the correction factors when the gyroscope is turned off and then on again. Experimental results for several Zeeman laser gyroscopes with typical values of zero drifts are presented
References
[1] Golyaev Yu.D., Kolbas Yu.Yu., Rasskazov A.P. Approximation of restored time and temperature dependences of ring laser zero shift. Elektronnaya tekhnika. Lazernaya tekhnika i optoelektronika, 1991, no. 2, pp. 49--52 (in Russ.).
[2] Kolbas Yu.Yu., Ladonkina M.V., Solovyeva S.I. Drift of Zeeman laser gyroscope with switched longitudinal modes of generations. Kachestvo. Innovatsii. Obrazovanie [Quality. Innovation. Education], 2015, no. 3, pp. 35--46 (in Russ.).
[3] Kolbas Yu.Yu., Grushin M.E., Gorshkov V.N. The nonmagnetic component of the zero bias of a Zeeman laser gyroscope. Quantum Electron., 2018, vol. 48, no. 3, pp. 283--289 (in Russ.). DOI: 10.1070/QEL16509
[4] Vakhitov N.G., Golyaev Yu.D., Dronov I.V., et al. Zeeman laser gyro with switching of longitudinal modes of generation. Vestn. Mosk. Gos. Tekh. Univ. im. N.E. Baumana, Priborostr. [Herald of the Bauman Moscow State Tech. Univ., Instrum. Eng.], 2014, no. 2, pp. 10--27 (in Russ.).
[5] Golyaev Yu.D., Kolbas Yu.Yu. Descretisation error of input signal in ring laser with periodic support. ZhTF, 1991, vol. 17, no. 8, pp. 162--165 (in Russ.).
[6] Golyaev Yu.D., Kolbas Yu.Yu. Application of ring lasers to determine the directions to the poles of Earths rotation. Quantum Electron., 2012, vol. 42, no. 10, pp. 949--952. DOI: 10.1070/QE2012v042n10ABEH014898
[7] Kolbas Yu.Yu., Saveliev I.I., Khokhlov N.I. Effect of external and internal magnetic fields on the bias stability in a Zeeman laser gyroscope. Quantum Electron., 2015, vol. 45, no. 6, pp. 573--581. DOI: 10.1070/QE2015v045n06ABEH015538
