An asymptotic universal focal decomposition for non-isochronous potentials

TL;DR

This paper investigates the long-term dynamics of non-isochronous potentials, revealing a universal asymptotic focal decomposition through a renormalization scheme, with implications for semiclassical quantization of pendulum-like systems.

Contribution

It introduces a renormalization approach to analyze long-term dynamics of non-isochronous systems, establishing a universal asymptotic focal decomposition.

Findings

Universal asymptotic limit of the renormalization scheme

Focal decomposition is universal across the considered class

Foundation for semiclassical quantization of pendulum systems

Abstract

Galileo, in the XVII century, observed that the small oscillations of a pendulum seem to have constant period. In fact, the Taylor expansion of the period map of the pendulum is constant up to second order in the initial angular velocity around the stable equilibrium. It is well known that, for small oscillations of the pendulum and small intervals of time, the dynamics of the pendulum can be approximated by the dynamics of the harmonic oscillator. We study the dynamics of a family of mechanical systems that includes the pendulum at small neighbourhoods of the equilibrium but after long intervals of time so that the second order term of the period map can no longer be neglected. We analyze such dynamical behaviour through a renormalization scheme acting on the dynamics of this family of mechanical systems. The main theorem states that the asymptotic limit of this renormalization scheme is universal: it is the same for all the elements in the considered class of mechanical systems. As a consequence, we obtain an universal asymptotic focal decomposition for this family of mechanical systems. This paper is intended to be the first of a series of articles aiming at a semiclassical quantization of systems of the pendulum type as a natural application of the focal decomposition associated to the two-point boundary value problem.