Explicit evolution relations with orbital elements for eccentric, inclined, elliptic and hyperbolic restricted few-body problems

• Published in: Celestial mechanics and dynamical astronomy Vol. 118; no. 4; pp. 315 - 353
• Main Author: Veras, Dimitri
• Format: Journal Article
• Language: English
• Published: Dordrecht Springer Netherlands 01.04.2014; Springer Nature B.V
• Subjects: Aerospace Technology and Astronautics; Astrophysics; Astrophysics and Astroparticles; Classical Mechanics; Dynamical Systems and Ergodic Theory; Few-body systems; Geophysics/Geodesy; Gravity; Original Article; Physics; Physics and Astronomy; Solar system; Circumbinary case; Perturbation equations; Averaged equations; Restricted problems; Gravitational N-body problem; Planetary systems
• ISSN: 0923-2958; 1572-9478
• DOI: 10.1007/s10569-014-9537-8

Planetary, stellar and galactic physics often rely on the general restricted gravitational N -body problem to model the motion of a small-mass object under the influence of much more massive objects. Here, I formulate the general restricted problem entirely and specifically in terms of the commonly used orbital elements of semimajor axis, eccentricity, inclination, longitude of ascending node, argument of pericentre, and true anomaly, without any assumptions about their magnitudes. I derive the equations of motion in the general, unaveraged case, as well as specific cases, with respect to both a bodycentric and barycentric origin. I then reduce the equations to three-body systems, and present compact singly- and doubly-averaged expressions which can be readily applied to systems of interest. This method recovers classic Lidov–Kozai and Laplace–Lagrange theory in the test particle limit to any order, but with fewer assumptions, and reveals a complete analytic solution for the averaged planetary pericentre precession in coplanar circular circumbinary systems to at least the first three nonzero orders in semimajor axis ratio. Finally, I show how the unaveraged equations may be used to express resonant angle evolution in an explicit manner that is not subject to expansions of eccentricity and inclination about small nor any other values.