Planetary equations in terms of vectorial elements

R. R. Allan; G. N. Ward

doi:10.1017/S0305004100037336

Abstract

The planetary equations for natural elements, which do not depend upon the choice of a particular frame of reference, are derived by using the theory of Poisson brackets. These natural elements include vectorial elements which lead to the introduction of vector and dyadic Poisson brackets. The use of vectorial elements can also lead to redundancy in the set of elements; this idea is extended to show that as many redundant elements as desired can be used and that the evaluation of the derivatives of the disturbing function can be simplified thereby.

References

REFERENCES

(1)Milankovitch, M., Ueber die Verwendung vectorieller Bahnelemente in der Störungsrechnung. Acad. Serbe. Bull. Acad. Sci. Mat. Nat. A, no. 6 (Belgrade, 1939).Google Scholar

(2)Musen, P., On the long-period lunar and solar effects on the motion of an artificial satellite, 2. J. Geophys. Res. 66 (1961), 2797–2805.CrossRef Google Scholar

(3)Goldstein, H., Classical mechanics, chap. 8 (Addison-Wesley; Reading, Mass., 1959).Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Roy, A. E. and Moran, P. E. 1973. Studies in the application of recurrence relations to special perturbation methods. Celestial Mechanics, Vol. 7, Issue. 2, p. 236.

Moran, P. E. Roy, A. E. and Black, W. 1973. Studies in the application of recurrence relations to special perturbation methods. Celestial Mechanics, Vol. 8, Issue. 3, p. 405.

Hestenes, David 1983. Celestial mechanics with geometric algebra. Celestial Mechanics, Vol. 30, Issue. 2, p. 151.

Ulivieri, C. and d'Avanzo, P. 1996. Passive stabilized high lunar orbits.

2004. Orbital Motion, Fourth Edition. p. 234.

Breiter, S. and Ratajczak, R. 2005. Vectorial elements for the Galactic disc tide effects in cometary motion. Monthly Notices of the Royal Astronomical Society, Vol. 364, Issue. 4, p. 1222.

Rosengren, Aaron J. and Scheeres, Daniel J. 2014. On the Milankovitch orbital elements for perturbed Keplerian motion. Celestial Mechanics and Dynamical Astronomy, Vol. 118, Issue. 3, p. 197.

Hamers, Adrian S. Perets, Hagai B. Antonini, Fabio and Portegies Zwart, Simon F. 2015. Secular dynamics of hierarchical quadruple systems: the case of a triple system orbited by a fourth body. Monthly Notices of the Royal Astronomical Society, Vol. 449, Issue. 4, p. 4221.

Condoleo, Ennio Cinelli, Marco Ortore, Emiliano and Circi, Christian 2016. Frozen Orbits with Equatorial Perturbing Bodies: The Case of Ganymede, Callisto, and Titan. Journal of Guidance, Control, and Dynamics, Vol. 39, Issue. 10, p. 2264.

Hamers, Adrian S. and Portegies Zwart, Simon F. 2016. Secular dynamics of hierarchical multiple systems composed of nested binaries, with an arbitrary number of bodies and arbitrary hierarchical structure. First applications to multiplanet and multistar systems. Monthly Notices of the Royal Astronomical Society, Vol. 459, Issue. 3, p. 2827.

Circi, Christian Condoleo, Ennio and Ortore, Emiliano 2016. Moon’s influence on the plane variation of circular orbits. Advances in Space Research, Vol. 57, Issue. 1, p. 153.

Hamers, Adrian S. and Lai, Dong 2017. Secular chaotic dynamics in hierarchical quadruple systems, with applications to hot Jupiters in stellar binaries and triples. Monthly Notices of the Royal Astronomical Society, Vol. 470, Issue. 2, p. 1657.

Condoleo, Ennio Circi, Christian and Ortore, Emiliano 2017. Constant orbit elements under the third body effect. Advances in Space Research, Vol. 59, Issue. 5, p. 1259.

Circi, Christian Condoleo, Ennio and Ortore, Emiliano 2017. A vectorial approach to determine frozen orbital conditions. Celestial Mechanics and Dynamical Astronomy, Vol. 128, Issue. 2-3, p. 361.

Hamers, Adrian S 2020. Secular dynamics of hierarchical multiple systems composed of nested binaries, with an arbitrary number of bodies and arbitrary hierarchical structure – III. Suborbital effects: hybrid integration techniques and orbit-averaging corrections. Monthly Notices of the Royal Astronomical Society, Vol. 494, Issue. 4, p. 5492.

Zhang, Ming-Jiang Zhao, Chang-Yin Xiong, Jian-Ning Zhu, Ting-Lei and Zhang, Wei 2020. Quantitative and Qualitative Results from Orbital Plane Precession of Medium-high Near-circular Orbits. The Astronomical Journal, Vol. 159, Issue. 4, p. 162.

Baù, Giulio and Roa, Javier 2020. Uniform formulation for orbit computation: the intermediate elements. Celestial Mechanics and Dynamical Astronomy, Vol. 132, Issue. 2,

Carbone, Andrea Cinelli, Marco Circi, Christian and Ortore, Emiliano 2020. Observing Mercury by a quasi-propellantless mission. Celestial Mechanics and Dynamical Astronomy, Vol. 132, Issue. 1,

Lara, M. Rosengren, A. J. and Fantino, E. 2020. Nonsingular recursion formulas for third-body perturbations in mean vectorial elements. Astronomy & Astrophysics, Vol. 634, Issue. , p. A61.

Lara, Martin and Urrutxua, Hodei 2023. Revisiting Hansen’s Ideal Frame Propagation with Special Perturbations—1: Basic Algorithms for Osculating Elements. Universe, Vol. 9, Issue. 11, p. 470.

Download full list

Article contents

Planetary equations in terms of vectorial elements

Abstract

Access options

References

REFERENCES

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Planetary equations in terms of vectorial elements

Abstract

Access options

References

REFERENCES

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests