Developing algorithms for automatically adjusting an optical system with a two-mirror telescope

Meytin, V.A., Mokshanov, V.N., Oleynikov, I.I., Perikov, A.P.

Full text «Opticheskii Zhurnal»

Full text on elibrary.ru

Publication in Journal of Optical Technology

For Russian citation (Opticheskii Zhurnal):

Мейтин В.А., Мокшанов В.Н., Олейников И.И., Периков А.П. Разработка алгоритмов автоматической юстировки оптической системы с двухзеркальным телескопом // Оптический журнал. 2022. Т. 89. № 1. С. 3–16. http://doi.org/10.17586/1023-5086-2022-89-01-03-16

Meitin V.A., Mokshanov V.N., Oleynikov I.I., Perikov A.P. Developing algorithms for automatically adjusting an optical system with a two-mirror telescope [in Russian] // Opticheskii Zhurnal. 2022. V. 89. № 1. P. 3–16. http://doi.org/10.17586/1023-5086-2022-89-01-03-16

For citation (Journal of Optical Technology):

V. A. Meĭtin, V. N. Mokshanov, I. I. Oleĭnikov, and A. P. Perikov, "Developing algorithms for automatically adjusting an optical system with a two-mirror telescope," Journal of Optical Technology. 89(1), 1-11 (2022). https://doi.org/10.1364/JOT.89.000001

Abstract:

This paper discusses how to develop algorithms for controlling the optical elements in order to solve the complex problem of automatically adjusting an optical system with a two-mirror telescope that serves to output laser radiation and is a component of the reception channel. A control system in the form of adjustment modules built into the telescope is used to provide the adjustment. Mathematical descriptions of their structures and methods of operating with them are presented and used as a basis for proposing automatic-adjustment algorithms.

Keywords:

automatic alignment, optical system, two-mirror telescope, algorithms, main mirror, receiving channel, radiation direction, radiation divergence, sight direction, focusing

OCIS codes: 120.0120, 230.0230, 080.0080

References:

1. Shipunov A.G., Pogorelsky S.L., Savchenko D.I., etc. The sight is a guidance device with radiating channels and a method for verifying the parallelism of optical axes // Russian Patent 2191971. 2002.

2. Gryzulin S. I. Adjustment of optical paths: monograph. M.: MAX Press, 2011. 196 p.

3. Baryshnikov N.V., Karachunsky V.V., Svigach O.A. Modern methods of designing auto-tuning systems for high-precision optoelectronic devices // Bulletin of Bauman Moscow State Technical University. Ser.: Instrumentation. 2011. No. S2. pp. 128-142.

4. Artemov Yu.M., Baryshnikov N.V. Device for determining the angular deviation of the laser beam axis from the nominal position // Patent of Russia 2496098. 2011.

5. Baryshnikov N.V. Development and research of devices for parallel beam transfer of radiation for auto-tuning systems of channels of laser location stations // Measuring equipment. 2011. No. 4. pp. 65-70.

6. Litvyakov S.B., Tareev A.M., Batyushkov V.V. et al. The sight is a guidance device with a laser rangefinder // Patent of Russia 2464601. 2011.

7. Bronstein Yu.L. Large-sized mirror systems (geometry control, alignment). Moscow: DPK Press, 2013. 480 p.

8. Beloivan P.A., Nazarov V.N., Latyev S.M., Salogubova I.S., Pashkevich M.L. Automated alignment of parallelism of the energy axis of the transmitting channel and the axis of the receiving channel of the laser rangefinder // Modern problems of science and education. 2015. No. 2-2. URL: http://science-education.ru/ru/article/view?id=22779 (accessed: 07/24/2021).

9. Sklyarov S.N. Devices for checking the alignment of optical axes of channels of optoelectronic complexes // Izv. vuzov. Instrumentation. 2016. Vol. 59. No. 9. pp. 741-749.

10. Piskunov T.S., Baryshnikov N.V., Zhivotovsky I.V. Investigation of the influence of angular aberrations of the optical-electronic coordinator lens on the measurement errors of the mutual angular misalignment of the axes of laser beams // Science and Education: scientific edition of Bauman Moscow State Technical University. Email No. FS 77-48211. 2012. URL: http://old.technomag.edu.ru/doc/479575.html (accessed: 10.02.2018).

11. Pronin V.V. Adjustment of the transmitting channel of the laser location system // Scientific and technical. bulletin of information technologies, mechanics and optics. 2020. Vol. 1. No. 1. pp. 39-44. doi: 10.17586/2226-1494-2020-20-1-39-44.

12. Papuchon M., Rabault D., Defour M., et al. Device for harmonizing a laser emission path with a passive observation path // Patent 6307623 US. publ. 23.10.2001.

13. Mallik P.C.V., Burge J., Zhao C. Measurement of a 2-meter flat using a pentaprism scanning system // Opt. Eng. 2007. V. 46(2). P. 023602.

14. Gian-The H.D. Multi-beam laser optical alignment method and system // Patent 8186069 US. Publ. 29.05.2012.

15. Hutchin R.A. Laser beam control system and method // Patent 8415600 US. Publ. 09.04.2013.

16. Baryshnikov N.V., Zhivotovskii I.V., Piskunov T.S., et al. The operating stability of an automatic adjustment system with a parallel transfer device using a pentaprism // Measurement Techniques. 2013. V. 55. № 12. P. 1371–1378.

17. Piskunov T.S., Baryshnikov N.V., Zhivotovskii I.V. An investigation of the precision characteristics of a device based on pentaprisms for parallel transfer of a beam of laser radiation // Measurement Techniques. 2015. V. 58. № 3. P. 292–299.

18. Meitin V.A., Mokshanov V.N., Oleinikov I.I. et al. Development of algorithms for automatic adjustment of a two-mirror telescope // Optical Journal. 2020. Vol. 87. No. 4. pp. 66-77.

19. Alexandrov A.B., Meitin V.A., Mokshanov V.N., Moshkov V.L. Device for automatic adjustment of a two-mirror telescopic system with a given direction of output radiation // Russian Patent No. 2611604. 2017.

20. Pogarev G.V. Adjustment of optical devices. L.: Mechanical engineering, 1982. 237 p.

21. Greim I.A. Mirror-prism systems. Moscow: Mashinostroenie, 1981. 125 p.