RAYLEIGH LASER GUIDE STAR FOR THE ZEISS-2000 TELESCOPE AT THE TERSKOL PEAK OBSERVATORY

Bolbasova, L.A.; Kopylov, E.A.; Larichev, A.V.; Iroshnikov, N.G.; Sachkov, M.E.

doi:10.7868/S3034517025060078

PII

S30345170S0004629925060078-1

DOI

10.7868/S3034517025060078

Publication type

Article

Status

Published

Authors

L.A. Bolbasova

Affiliation: Zuev Institute of Atmospheric Optics, Siberian Branch, Russian Academy of Science

E.A. Kopylov

Affiliation: Institute of Astronomy, Russian Academy of Sciences

A.V. Larichev

Affiliation: Lomonosov Moscow State University

N.G. Iroshnikov

Affiliation: Lomonosov Moscow State University

M.E. Sachkov

Affiliation: Institute of Astronomy, Russian Academy of Sciences

Volume/ Edition

Volume 102 / Issue number 6

Pages

515-523

Abstract

This paper describes the design and technical features of the Rayleigh laser guide star (LGS) system as a reference source of an adaptive optical system developed for use on the Zeiss-2000 telescope of the Terskol Peak Astronomical Observatory. Experiments were performed on the Zeiss-2000 telescope to test the developed system. As a result, a signal was received from the LGS sufficient for the operation of the wavefront sensor. The presented numerical estimates of the effectiveness of adaptive correction from the Rayleigh LGS show that in the future, the use of an adaptive optical system on this telescope will significantly improve the quality of the generated image by increasing the Strehl ratio by at least ten times.

Keywords

адаптивная оптика лазерная опорная звезда атмосферная турбулентность

Date of publication

16.01.2025

Year of publication

2025

Number of purchasers

Views

References

1. А.В. Токовинин, Пособие по адаптивной оптике обсерватории Серро-Тололо [Электронный ресурс]. URL: https://www.astronet.ru/db/msg/1205112 (дата обращения 25.09.2024).
2. D. Bonaccini Calia, Y. Feng, W. Hackenberg, R. Holzöhner, L. Taylor, S. Lewis, ESO Messenger 139, 12–19 (2010).
3. V.A. Bogachev, A.A. Vereshchagin, M.V. Volkov, S.G. Garanin, M.A. Glukhov, D.E. Guk, M.O. Kolygin, A.V. Kopalkin, R.S. Kuzin, S.M. Kulikov, F.A. Starikov, Proc. SPIE. 11916, 1191617–1–7 (2021).
4. T.J. Morris, An experimental Rayleigh laser guide star ground layer adaptive optics system for the William Herschel telescope. Durham theses, Durham University 2005. Available at Durham E-Theses [Электронный ресурс]. URL: http://etheses.dur.ac.uk/2717/ (дата обращения 25.09.2024).
5. S. Rabien, R. Angel, L. Bari, U. Beckmann, L. Busoni, S. Belli, M. Bonaglia and et., Astron. and Astrophys. 621, A4 (2019).
6. E.A. Bendek, M. Hart, K.B. Powell, V. Vaitheeswaran, D. McCarthy, C. Kulesa, Proc. SPIE. 8149, 814907 (2011).
7. R. Jensen-Clem, D.A. Duev, R. Riddle, M. Salama, C. Baranec, N.M. Law, S.R. Kulkarni, A.N. Ramprakash, Astron. J. 155, 1, 32 (2017).
8. C. Baranec, J. Ou, R. Riddle, R. Zhang, L. Mckay, R. Rampy, M. Bonnet, I. Hamilton, G. Ching, and el., Proc. SPIE 13097, 13097–15 (2024).
9. A. Tokovinin, R. Cantarutti, R. Tighe, P. Schurter, M. Martinez, S. Thomas, N. van der Bilek, Publ. Astron. Soc. Pacif. 128, 970, 125003–12 (2016).
10. E. Kopylov, A. Larichev, N. Iroshnikov, M. Sachkov, Proc. SPIE. 13097, 1309738 (2024).
11. A.Y. Shikhovtsev, C. Qing, E.A. Kopylov, S.A. Potanin, P.G. Kovadlo, Remote Sensing 16, 12, 2102-1-18 (2024).
12. J.A. Больбасова, B.H. Лукин, Адаптивная коррекция атмосферных искажений оптических изображений на основе искусственного опорного источника (ФИЗМАТЛИТ, 128, 2012).
13. R.K. Tyson, Principles of Adaptive Optics (CRC Press, 299, 2011).
14. L.A. Thompson, S.W. Teare Rayleigh, Publ. Astron. Soc. Pacif. 114, 799, 1029–1042 (2002).
15. A.C. Гурвич, A.H. Кон, В.Л. Миронов, С.С. Хмелевцов, Лазерное излучение в турбулентной атмосфере (M., "Наука", 277, 1976).
16. В.В. Клейменов, И.Ю. Возмищев, Е.В. Новикова, Оптический журнал 88, № 10, 24–32 (2021).
17. ГОСТ Р ИСО 11146-1-2008 ЛАЗЕРЫ И ЛАЗЕРНЫЕ УСТАНОВКИ (СИСТЕМЫ). Методы измерений ширин, углов расходимости и коэффициентов распространения лазерных пучков. Часть 1. Стигматические (гомоцентрические) и слабоастигматические пучки (M.: Стандартинформ, 14, 2010).
18. E. Kopylov, A. Larichev, N. Iroshnikov, M. Sachkov, Proc. SPIE 13097, 1309738 (2024).

GOST	Bolbasova L., Iroshnikov N., Kopylov E., Larichev A., Sachkov M. RAYLEIGH LASER GUIDE STAR FOR THE ZEISS-2000 TELESCOPE AT THE "TERSKOL PEAK" OBSERVATORY // Astronomy Reports. – 2025. – V. 102. – Issue number 6 C. 515-523 . URL: https://astrojournras.ru/s30345170s0004629925060078-1/?version_id=119801. DOI: 10.7868/S3034517025060078
MLA	Bolbasova, L.A, Iroshnikov, N.G, Kopylov, E.A, Larichev, A.V, Sachkov, M.E "RAYLEIGH LASER GUIDE STAR FOR THE ZEISS-2000 TELESCOPE AT THE "TERSKOL PEAK" OBSERVATORY." Astronomy Reports. 102.6 (2025).:515-523. DOI: 10.7868/S3034517025060078
APA	Bolbasova L., Iroshnikov N., Kopylov E., Larichev A., Sachkov M. (2025). RAYLEIGH LASER GUIDE STAR FOR THE ZEISS-2000 TELESCOPE AT THE "TERSKOL PEAK" OBSERVATORY. Astronomy Reports. vol. 102, no. 6, pp.515-523 DOI: 10.7868/S3034517025060078

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