Solar-Terrestrial Physics

2500-0535

13702

10.12737/22282

Results of current research

Progress cargo spacecraft observed with the AZT-33IK optical telescope

Клунко

Евгений Владимирович

Klunko

Evgeny Vladimirovich

eklunko@gmail.com

Еселевич

Максим Викторович

Eselevich

Maxim Viktorovich

mesel@iszf.irk.ru

кандидат физико-математических наук;

candidate of physical and mathematical sciences;

Тергоев

Владимир Иванович

Tergoev

Vladimir Ivanovich

tvi@iszf.irk.ru

Институт солнечно-земной физики СО РАН Иркутск Россия Institute of Solar Terrestrial Physics SB RAS Irkutsk Russian Federation

24 10 2016

2 3 22 31

https://naukaru.ru/en/nauka/article/13702/view

In this paper, we describe a telescope and measuring equipment used for optical observations of Progress cargo spacecraft (PCS), which were made during Radar–Progress space experiment sessions. We also demonstrate object tracking and measurement techniques. The observations were made with the optical telescope AZT-33IK at the Sayan Solar Observatory of ISTP SB RAS. During many of the sessions, we registered optical phenomena that occurred in regions of space surrounding the PCS and appeared due to the work of PCS onboard engines. The data we obtained can be used to independently control the geometry of the experiment and to analyze physical conditions in outer space.

Space experiment Optical signal Spacecraft Low orbit Telescopic observations

Devyatkin A.V., Gorshanov D.L., Kupriyanov V.V., Vereshchagina I.A. Apex I and Apex II software packages for processing astronomical CCD observations. Astronomicheskii vestnik [Solar System Research]. 2010, vol. 44, no. 1, p. 68. (In Russian).

Eselevich M.V., Khakhinov V.V., Klunko E.V. Parameters of the optical signals registered with the AZT-33IK telescope in the “Radar-Progress” active space experiment. Solnechno-zemnaya fizika [Solar-Terrestrial Physics]. 2016, vol. 2, no. 3, pp. 47-55. (In Russian).

Kamus S.F., Tergoev V.I., Papushev P.G., et al. Wide-range astronomical telescope. Opticheskii zhurnal [J. Opt. Technol.]. 2002, vol. 69, iss. 9, pp. 674-676. DOI: 10.1364/JOT.69.000674. (In Russian).

Khakhinov V.V., Potekhin A.P., Lebedev V.P., et al. Results of remote sensing of ionospheric disturbances in active space experiments “Radar-Progress”. Sovremennye problemy distantsionnogo zondirovaniya Zemli iz kosmosa [Modern problems of the Earth remote sensing from the space]. 2012, vol. 9, iss. 3, pp. 199-206. (In Russian).

Khakhinov V.V., Potekhin A.P., Lebedev V.P., et al. Some results of active space experiments “Plasma-Progress” and “Radar-Progress”. Vestnik Sibirskogo gosudarstvennogo aerokosmicheskogo universiteta imeni akademika M.F. Reshetneva [Bulletin of M.F. Reshetnev Siberian State Aerospace University]. 2013, special iss. 5 (51), pp. 160-163. (In Russian).

Klunko E.V., Eselevich M.V. Distributed control system for astronomical CCD cameras. Solnechno-zemnaya fizika [Solar-Terrestrial Physics]. 2012, vol. 20, pp. 139-145. (In Russian).

Lebedev V.P., Khakhinov V.V., Gabdullin F.F., et al. Study of characteristics of plasma environment of low orbit spacecraft using radio sounding methods. Kosmonavtika i raketostroenie [Cosmonautics and Rocket Science]. 2008, iss. 50 (1), pp. 51-60. (In Russian).

Potekhin A.P., Khakhinov V.V., Medvedev A.V., et al. Active space experiments with the use of the transport spacecraft “Progress” and Irkutsk IS Radar. PIERS Proc. Moscow, 2009, pp. 223-227.

Tergoev V.I., Eselevich M.V., Klunko E.V., et al. Design and application of the IR camera for registration of spacecraft thermal portraits. Vestnik Sibirskogo gosudarstvennogo aerokosmicheskogo universiteta imeni akademika M.F. Reshetneva [Bulletin of M.F. Reshetnev Siberian State Aerospace University]. 2011, vol. 6 (39), pp. 165-169. (In Russian).

10.

URL: http://www.tpointsw.uk/index.htm (accessed July 1, 2016).