Kepler's third law of n-body periodic orbits in a Newtonian gravitation field

Abstract

This study considers the periodic orbital period of an n-body system from the perspective of dimension analysis. According to characteristics of the n-body system with point masses (m1,m2,...,mn), the gravitational field parameter, α Gmimj, the n-body system reduction mass Mn, and the area, An, of the periodic orbit are selected as the basic parameters, while the period, Tn, and the system energy, |En|, are expressed as the three basic parameters. Using the Buckingham π theorem, We obtained an epic result, by working with a reduced gravitation parameter αn, then predicting a dimensionless relation Tn|En|3/2=const × αn μn (μn is reduced mass). The const=π2 is derived by matching with the 2-body Kepler's third law, and then a surprisingly simple relation for Kepler's third law of an n-body system is derived by invoking a symmetry constraint inspired from Newton's gravitational law: Tn|En|3/2=π2 G(Σi=1nΣj=i+1n(mimj)3Σk=1n mk)1/2. This formulae is, of course, consistent with the Kepler's third law of 2-body system, but yields a non-trivial prediction of the Kepler's third law of 3-body: T3|E3|3/2= π2 G [(m1m2)3+(m1m3)3+(m2m3)3m1+m2+m3]1/2. A numerical validation and comparison study was conducted. This study provides a shortcut in search of the periodic solutions of three-body and n-body problems and has valuable application prospects in space exploration.