Revisiting Kepler: new symmetries of an old problem

TL;DR

This paper explores the symmetry properties of Kepler orbits, revealing a maximum 7-dimensional symmetry group for the family of all such orbits and analyzing subfamilies with fixed energy or angular momentum using projective geometry.

Contribution

It introduces a new geometric perspective on Kepler orbits, identifying their maximal symmetry group and simplifying the analysis with a projective geometric model.

Findings

Kepler orbits form a flat 3-parameter family with a 7-dimensional symmetry group.

Subfamilies with fixed energy admit PSL(2,R) symmetry groups.

The projective geometric model simplifies symmetry analysis and reveals dualities.

Abstract

The $Kepler$ $orbits$ form a 3-parameter family of $unparametrized$ plane curves, consisting of all conics sharing a focus at a fixed point. We study the geometry and symmetry properties of this family, as well as natural 2-parameter subfamilies, such as those of fixed energy or angular momentum. Our main result is that Kepler orbits is a `flat' family, that is, the local diffeomorphisms of the plane preserving this family form a 7-dimensional local group, the maximum dimension possible for the symmetry group of a 3-parameter family of plane curves. These symmetries are different from the well-studied `hidden' symmetries of the Kepler problem, acting on energy levels in the 4-dimensional phase space of the Kepler system. Each 2-parameter subfamily of Kepler orbits with fixed non-zero energy (Kepler ellipses or hyperbolas with fixed length of major axis) admits $\mathrm{PSL}_2(\mathbb{R})$ as its (local) symmetry group, corresponding to one of the items of a classification due to A. Tresse (1896) of 2-parameter families of plane curves admitting a 3-dimensional local group of symmetries. The 2-parameter subfamilies with zero energy (Kepler parabolas) or fixed non-zero angular momentum are flat (locally diffeomorphic to the family of straight lines). These results can be proved using techniques developed in the 19th century by S. Lie to determine `infinitesimal point symmetries' of ODEs, but our proofs are much simpler, using a projective geometric model for the Kepler orbits (plane sections of a cone in projective 3-space). In this projective model all symmetry groups act globally. Another advantage of the projective model is a duality between Kepler's plane and Minkowski's 3-space parametrizing the space of Kepler orbits. We use this duality to deduce several results on the Kepler system, old and new.