Correction of spacecraft trajectory during its transition into circular satellite orbit using atmospheric braking with uncertain atmospheric parameters
| Authors: Kazakovtsev V.P. , Koryanov V.V. , Zaw Min Tun | Published: 06.10.2015 |
| Published in issue: #5(104)/2015 | |
| Category: Aviation and Rocket-Space Engineering | Chapter: Aircraft Dynamics, Ballistics, Motion Control | |
| Keywords: orbit, spatial motion, spacecraft, braking in atmosphere, heat flow, dynamic pressure | |
The current stage of space exploration is characterized by complication of the problems being solved in space that require quite cumbersome auxiliary systems and tools. A considerable mass of fuel is consumed during the spacecraft transition from the planet gravitation assist trajectory into the planet satellite orbit. The use of an intermediate elliptical orbit with the pericenter located in the planet’s upper atmosphere can reduce the fuel consumption. The article is devoted to the use of the planet’s atmosphere for slowing down the spacecraft during its transition into the satellite orbit with uncertain atmospheric parameters.
References
[1] Kazakovsev V.P., Sukhenko A.V. Use of the Preliminary Brake Impetus for Launching Spacecraft into Orbit of a Satellite of Mars. Vestn. Mosk. Gos. Tekh. Univ. im. N.E. Baumana, Mashinostr. [Herald of the Bauman Moscow State Tech. Univ., Mech. Eng.], 2005, no. 4, pp. 3-11 (in Russ.).
[2] Ivanov V.M., Sokolov N.L. Optimal control of a spacecraft due to the change of the trust vector of the propulsion system during interorbital maneuvers. Kosmonavtika i raketostroenie [Cosmonautic and Rocket Engineering], 2014, no. 2, pp. 80-88 (in Russ.).
[3] Golomazov M.M., Litvinov L.A., Litvinov I.A., Ivankov A.A., Finchenko V.S. Numerical simulation of flow past descent vehicles during planetary entry. Vestn. Mosk. Gos. Tekh. Univ. im. N.E. Baumana, Mashinostr. [Herald of the Bauman Moscow State Tech. Univ., Mech. Eng.], 2011, no. 4, pp. 42-53 (in Russ.).
[4] Spencer David A., Tolson Robert. Airobraking Cost and Risk Decisions. J. of Spacecraft and Rockets, 2007, vol. 44, no. 6, pp. 1285-1293.
[5] Smith John C., Bell Julia L. 2001 Mars Odyssey Airobraking. J. of Spacecraft and Rockets, 2005, vol. 42, no. 3, pp. 406-415.
[6] Kazakovsev V.P., Karanov V.V. Dynamics of motion of descent spacecraft with inflatable break device in the planet’s atmosphere. Estestvennye i tekhnicheskie nauki [Natural and Technical Sciences], 2013, no. 6, pp. 266-270 (in Russ.).
[7] Ivanov N.M., Martynov A.I. Dvizhenie kosmicheskikh letatel’nykh apparatov v atmosferakh planet [Motion of spacecraft in planetary atmospheres]. Мoscow, Nauka Publ., 1985. 384 p.
[8] Novitsky V., Zelentsov V. One Task of Maneuvering in the Atmosphere of Mars. Upravlyayushchie sistemy i mashiny [Control Systems and Machines], 1999, no. 1, pp. 3-9 (in Russ.).
[9] Novitsky V., Zelentsov V.V. Optimization of atmospheric maneuver during insertion of an artificial satellite of Mars. Problemy upravleniya i informatiki [Problems of Control and Informatics], 1999, no. 4, pp. 143-157 (in Russ.).
[10] Yaroshevsky V.A. Vkhod v atmosferu kosmicheskikh letatel’nykh apparatov [The Entry of Spacecraft]. Moscow, Nauka Publ., 1988. 336 p.
[11] Saplin S.V., Bolychev S.A., Romanov A.E. Teploobmen v kosmose [Heat Transfer in Space]. Samara, Samara University Publ., 2013. 53 p.
[12] Andreevskiy V.V. Dinamika spuska kosmicheskikh apparatov na Zemlyu [Dynamics of Spacecraft Descent to the Ground]. Moscow, Mashinostroenie Publ., 1970. 235 p.
