Quantitative Linear Stability Analysis of Elliptic Relative Equilibria in the Planar N-Body Problem

Abstract

An elliptic relative equilibrium (ERE) is a special solution of the planar N-body problem generated by a central configuration. Its linear stability depends on the eccentricity e and the masses of the bodies. However, for e>0, the variational equations become non-autonomous and highly complex, particularly near e=1, where the system exhibits a singularity. This complicates the stability analysis as e approaches one, making it challenging to derive a rigorous quantitative estimate for the stable region across e∈[0,1). In this work, we address this problem. Using trace formulas for the non-degenerate Hamiltonian system of EREs, we establish an upper bound ensuring non-degeneracy for all e∈[0,1). As key applications, we provide explicit stability estimates for the Lagrange, Euler, and regular (1+n)-gon EREs over the full range of eccentricity.