Engineering Journal: Science and InnovationELECTRONIC SCIENCE AND ENGINEERING PUBLICATION
Certificate of Registration Media number Эл #ФС77-53688 of 17 April 2013. ISSN 2308-6033. DOI 10.18698/2308-6033
  • Русский
  • Английский
Article

Method for restoring the heading orientation of a spacecraft using the orbital gyrocompass

Published: 21.04.2017

Authors: Abezyaev I.N., Andreyanenkova A.V., Velichko P.E., Potselovkin A.I., Fokin D.V.

Published in issue: #5(65)/2017

DOI: 10.18698/2308-6033-2017-5-1621

Category: Aviation and Rocket-Space Engineering | Chapter: Aircraft Dynamics, Ballistics, Motion Control

At present, the development of algorithms for controlling the angular orientation and stabilization of the orbital spacecraft is one of the most relevant and dynamically developing areas in the field of astronautics and control theory. A special role in the algorithm for reducing the bound coordinate system to the orbital coordinate system is the stage of the heading motion. The current orientation systems, including the orbital gyrocompass, do not have the proper quality of transient processes that would satisfy the requirements of customers. Such systems require solving the problem of reducing the time for constructing OCS in the course channel and improving the quality of the transitional process as a whole. This paper analyzes the "classical" orbital gyrocompassing (OGC) method and shows its shortcomings. A new method to restore heading orientation using OGC is proposed. It significantly reduces the time of transient processes and improves their quality. The graphs reflecting the behavior of spacecraft in the process of restoring the heading orientation using the proposed method are presented.


References
[1] Alekseev K.B., Bebenin G.G. Upravlenie kosmicheskim letatelnym apparatom [Control of spacecraft]. 2nd ed. Moscow, Mashinostroenie Publ., 1974, 343 p.
[2] Besekerskiy V.A., Ivanov V.A., Samotokin B.B. Orbitalnoe girokompasirovanie [Orbital gyrocompassing]. St. Petersburg, Politekhnika Publ., 1993, 250 p.
[3] Raushenbakh B.V., Tokar E.N. Upravlenie orientatsiey kosmicheskikh apparatov [Control of space vehicle orientation]. Moscow, Nauka Publ., 1974, 600 p.
[4] Seleznev V.P. Navigatsionnye ustroystva [Navigation devices]. Moscow, Mashinostroenie Publ., 1974, 600 p.
[5] Bowers J.R., Rodden J.J., Scott E.D., Debra D.B. Orbital Gyrocompassing Heading Reference. AIAA Journal of Spacecraft and Rockets, 1968, vol. 5, no. 8, 903 p.
[6] Boyarchuk K.A., Vilenskiy V.V., Grishin V.Yu., Eremeev P.M., Zaytsev S.E., Zimin S.N., Morozova L.M., Nekhamkin L.I., Ryabikov V.S., Salikhov R.S. Sistema orientatsii i stabilizatsii KA "Kondor-E" [The system of orientation and stabilization of the "Condor-E" spacecraft]. Trudy sektsii 22 imeni akademika V.N. Chelomeya XXXVIII Akademicheskikh chteniy po kosmonavtike: Raketnye kompleksy i raketno-kosmicheskie sistemy - proektirovanie, eksperimentalnaya otrabotka, letnye ispytaniya, ekspluatatsiya [Proceedings of the section 22 named after academician V.N. Chelomey of XXXVIII Scientific conference on cosmonautics: Missile systems and rocket and space systems - design, experimental development, flight testing, operation]. JSC MIC NPO Mashinostroyenia. Reutov town, 2014, pp. 408-424.
[7] Abezyaev I.N., Bolshakov M.V., Potselovkin A.I. Sistema orbitalnogo girokompasirovaniya - proshloe, nastoyashchee, budushchee [Orbital gyrocompassing system - past, present, future]. Trudy sektsii 22 imeni akademika V.N. Chelomeya XXXVIII Akademicheskikh chteniy po kosmonavtike: Raketnye kompleksy i raketno-kosmicheskie sistemy - proektirovanie, eksperimentalnaya otrabotka, letnye ispytaniya, ekspluatatsiya [Proceedings of the section 22 named after academician V.N. Chelomey of XXXVIII Scientific conference on cosmonautics: Missile systems and rocket and space systems-design, experimental development, flight testing, operation]. JSC MIC NPO Mashinostroyenia. Reutov town, 2014, pp. 317-326.
[8] Bryson A.E., Kortum V. Vychislenie mestnogo uglovogo polozheniya orbitalnogo kosmicheskogo apparata. [Analysis of the local angular position of the orbital space vehicle.]. Upravlenie v kosmose. Trudy III Mezhdunarodnogo simpoziuma IFAK po avtomaticheskomu upravleniyu v mirnom ispolzovanii kosmicheskogo prostranstva. Frantsiya, Tuluza, Mart 1970. V2 tomakh [Control in space. Proceedings of III International Symposium on automatic control in the peaceful use of space. France, Toulouse. March 1970. In 2 vol.]. Moscow, Nauka Publ., 1972, vol. 2, 394 p.
[9] Abezyaev I.N., Zimin S.N. Ustroystvo upravleniya polozheniem kosmicheskogo apparata v prostranstve s ispolzovaniem orbitalnogo girokompasa [The device for controlling the spacecraft position in space using the orbital gyrocompass]. Patent RF, no. 2509690, 2014, bulletin no. 8, 7 p.