Hostname: page-component-848d4c4894-pjpqr Total loading time: 0 Render date: 2024-06-18T22:51:05.091Z Has data issue: false hasContentIssue false
  • English
  • Français

Effect of Environmental Forces on the Attitude of Gravity Orientated Satellites

Part 1. High Altitude Orbits

Published online by Cambridge University Press:  04 July 2016

V. J. Modi  and
R. C. Flanagan
V. J. Modi
Affiliation:
The University of British Columbia, Vancouver, Canada
R. C. Flanagan
Affiliation:
The University of British Columbia, Vancouver, Canada
Get access Rights & Permissions [Opens in a new window]

Extract

There are several situations of practical importance where it is essential to maintain a satellite in a fixed orientation relative to the earth. Of the numerous methods proposed for such station keeping, gravity gradient stabilisation has gained considerable attention primarily due to the passive nature of the system. The pioneering work for pure gravity orientated satellites was carried out by Klemperer who obtained the exact solution for planar librations of a dumbbell satellite in circular orbit, and by Baker who found periodic solutions of the problem for small orbit eccentricity. Schechter attempted, with limited success, to extend Klemperer's solution to non-circular orbital motion by perturbation methods. Zlatousov et al and, more recently, Brereton and Modi successfully employed numerical methods, involving the use of the stroboscopic phase plane, to analyse motion in the large for orbits of arbitrary eccentricity.

Type
Technical Notes
Information
The Aeronautical Journal , Volume 75 , Issue 731 , November 1971 , pp. 783 - 793
Copyright
Copyright © Royal Aeronautical Society 1971 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Klemperer, W. B. Satellite librations of large amplitude. ARS Journal, Vol 30, No 1, pp. 123124, January 1960.Google Scholar
2. Baker, Robert M. L. JR. Librations on a slightly eccentric orbit. ARS Journal, Vol 30, No 1, pp. 124126, January 1960.Google Scholar
3. Schechter, Hans B. Dumbbell librations in elliptic orbits. A1AA Journal, Vol 2, No 6, pp. 10001003, June 1964.Google Scholar
4. Zlatousov, V. A., Okhotsimsky, D. E., Sarghev, V. A. and Torzhevsky, A. P. Investigation of a satellite oscillations in the plane of an elliptic orbit. Proceedings of the Eleventh International Congress of Applied Mechanics. Gortler, Henry, ed. Springer-Verlag, Berlin, pp. 436439, 1964.Google Scholar
5. Brereton, R. C. and Modi, V. J. On the stability of planar librations of a dumbbell satellite in an elliptic orbit. The Aeronautical Journal of the Royal Aeronautical Society, Vol 70, No 12, pp. 10981102, 1966.Google Scholar
6. Brereton, R. C. and Modi, V. J. Stability of the planar librational motion of a satellite in an elliptic orbit. Proceedings of the XVIIth International Astronautical Congress, Vol IV, Gordon and Breach Inc., New York, pp. 179192, 1967.Google Scholar
7. Modi, V. J. and Brereton, R. C. Planar librational stability of a long flexible satellite. AIAA Journal, Vol 6, No 3, pp. 511517, March 1968.Google Scholar
8. Modi, V. J. and Brereton, R. C. On the periodic solutions associated with the gravity gradient oriented system: part I—analytical and numerical determination. AIAA Journal, Vol 7, pp. 12171225, July 1969.Google Scholar
9. Modi, V. J. and Brereton, R. C. On the periodic solutions associated with the gravity gradient oriented system: Part II—stability analysis. AIAA Journal, Vol 7, pp. 14651468, August 1969.Google Scholar
10. Modi, V. J. and Brereton, R. C. Stability of a dumbbell satellite in a circular orbit during coupled librational motions. Proceedings of the XVlllth International Astro-nautical Congress, Pergamon Press, London, pp. 109120, 1968.Google Scholar
11. Brereton, R. C. A stability study of gravity oriented satellites. Ph.D. dissertation, University of British Columbia, November 1967.Google Scholar
12. Flanagan, R. C. and Modi, V. J. Radiation forces on a flat plate in close earth orbits. Transactions of the Canadian Aeronautics and Space Institute, Vol 3, No 2, pp. 147158, September 1970.Google Scholar
13. Piscane, Vincent L., Pardoe, Peter P. and Hook, P. J. Stabilisation system analysis and performance of the GEOS-A gravity-gradient satellite (Explorer XXIX). Proceedings of the AIAA|JACC Guidance and Control Conference, American Institute of Aeronautics and Astronautics, pp. 226237, 1966.Google Scholar
14. Hamming, R. W. Numerical Methods for Scientists and Engineers, McGraw-Hill Book Company Inc., New York, pp. 183222, 1962.Google Scholar
15. Moser, Jurgen. Perturbation theory for almost periodic solutions for undamped nonlinear differential equations. International Symposium on Nonlinear Differential Equations and Nonlinear Mechanics, edited by La Salle, J. P. and Lefsohetz, S.. Academic Press, New York, pp. 7179, 1963.Google Scholar
16. Henon, M. and Heiles, C. The applicability of the third integral of motion: some numerical experiments. Astronomical Journal, Vol 69, No 1, pp. 7379, 1964.Google Scholar
17. Neilson, J. E. On the attitude dynamics of slowly spinning axisymmetric satellites under the influence of gravity-gradient torques. Ph.D. dissertation. University of British Columbia, November 1968.Google Scholar
18. Minorsky, Nicholas. Nonlinear Oscillations, D. Van Nostrand Company Inc., Princeton, pp. 127133, 390-415, 1962.Google Scholar