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Space astrometry prospects and limitations

Published online by Cambridge University Press:  04 August 2017

J. Kovalevsky ,
F. Mignard  and
M. Froeschlé
J. Kovalevsky
Affiliation:
C E R G A, Avenue Copernic, 06130 Grasse, France
F. Mignard
Affiliation:
C E R G A, Avenue Copernic, 06130 Grasse, France
M. Froeschlé
Affiliation:
C E R G A, Avenue Copernic, 06130 Grasse, France

Abstract

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Among the few parameters that describe the generalized space time metrics, astrometric techniques are essentially sensitive to the displacement of the apparent positions of celestial bodies. This includes the relativistic light deflection and aberration. The possibilities of small field and wide field astrometry in measuring these effects are described. The case of the second order aberration terms is considered with some detail from the theoretical point of view, both for stellar and planetary aberration. New results are presented in the latter case.

A section is devoted to a description of the existing space astrometry projects among which Space Telescope and HIPPARCOS are approved but will not contribute significantly to relativistic studies. Several “second generation” projects exist that aim at 2 or 3 orders of magnitude improvement in precision. They would yield results on second order relativistic effects and may be used to determine masses of some single stars. However, the present state of engineering of space astrometric missions has permitted to identify several limitations of the present and future missions. They will not all be readily suppressed and one should be very careful in assessing now their potentialities. It seems however that interferometric techniques have more chance to reach the 10−4 and 10−5 arc second precision than the imaging methods.

Type
Future Observations of Relativity Effects
Information
Symposium - International Astronomical Union , Volume 114: Relativity in Celestial Mechanics and Astrometry , 1986 , pp. 369 - 382
Copyright
Copyright © Reidel 1986 

References

Boyce, P.B. and Reasenberg, R.D. (ed), 1984, Bull. Am. Astr. Soc. 16, n°3, II pp 795837.Google Scholar
Chollet, F., 1979, Comptes Rendus Ac. Sc. Paris, 288, ser. B, 163.Google Scholar
Duncombe, R.L., Benedict, G.F., Hemenway, P.D., Jefferys, W.H. and Shelus, P.D., 1982, in Hall, N. B. (ed), “The Space Telescope Observatory”, NASA Publ. CP-2244, p 114.Google Scholar
Faucherre, M., Lacasse, M.G., Nisenson, P., Reasenberg, R.D., Shao, M., Stachnik, R.V. and Traub, W.A., 1984, Bull. Am. Astr. Soc. 16, 793.Google Scholar
Fock, V., 1976, “The theory of space, time and gravitation”, Pergamon Press.Google Scholar
Froeschlé, M. and Mignard, F., 1986, Astronomy and Astrophysics (in press).Google Scholar
Gatewood, G.D., 1986, “Three astrometric systems”, in “Astrometric techniques”, I.A.U. Symp. 109, Eichhorn, H. (ed), Reidel Publ. Co., in press.Google Scholar
Kovalevsky, J., 1984, Space Science Rev., 39, 1.CrossRefGoogle Scholar
Labeyrie, A., Authier, B., Boit, J.L., De Graauw, T., Kibblewhite, E., Koechlin, L., Rabout, P. and Weigelt, G., 1984, Bull. Am. Astr. Soc. 16, 828.Google Scholar
Reasenberg, R.D., 1984, Bull. Am. Astr. Soc. 16, 758.Google Scholar
Reasenberg, R.D., 1986, “Microarc-second astrometric interferometry”, IAU Symp. 109, Eichhorn, H. (ed), Reidel Publ. Co., in press.CrossRefGoogle Scholar
Reasenberg, R.D. and Shapiro, I.I., 1986, “Prospects for future relativistic observations”, this symposium.Google Scholar
Silverglate, P., 1984, Bull. Am. Astr. Soc. 16, 787.Google Scholar
Shao, M., Colavita, M., Staelin, D. and Johnston, K., 1984, Bull. Am. Astr. Soc. 16, 750.Google Scholar
Soderhjelm, S. and Lindegren, L., 1986, “Accuracy estimates for the determination of the solar space-time metric by HIPPARCOS”, this symposium.CrossRefGoogle Scholar
Stachnick, R.V., Ashlin, K. and Hamilton, S., 1984, Bull. Am. Astr. Soc. 16, 818.Google Scholar
Stumpff, P., 1979, Astron. and Astrophys., 78, 229.Google Scholar
Stumpff, P., 1980, Astron. and Astrophys., 84, 257.Google Scholar
Will, C.M., 1986, “General relativity confronts experiment”, this symposium.CrossRefGoogle Scholar
York, D.G., Jones, B., Faber, S., Lin, D., Van Altena, W., Demarque, P., Hughes, J., Johnson, K. and Bunner, A., 1984, Bull. Am. Astr. Soc. 16, 775.Google Scholar