Saved in:
Bibliographic Details
Main Authors: Alexandrov, Artem, Glutsyuk, Alexey, Gorsky, Alexander
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.20181
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912352782254080
author Alexandrov, Artem
Glutsyuk, Alexey
Gorsky, Alexander
author_facet Alexandrov, Artem
Glutsyuk, Alexey
Gorsky, Alexander
contents In this study, we discuss the Prufer transform that connects the dynamical system on the torus and the Hill equation, which is interpreted as either the equation of motion for the parametric oscillator or the Schrodinger equation with periodic potential. The structure of phase-locking domains in the dynamical system on torus is mapped into the band-gap structure of the Hill equation. For the parametric oscillator, we provide the relation between the non-adiabatic Hannay angle and the Poincare rotation number of the corresponding dynamical system. In terms of quantum mechanics, the integer rotation number is connected to the quantization number via the Milne quantization approach and exact WKB. Using recent results concerning the exact WKB approach in quantum mechanics, we discuss the possible non-perturbative effects in the dynamical systems on the torus and for parametric oscillator. The semiclassical WKB is interpreted in the framework of a slow-fast dynamical system. The link between the classification of the coadjoint Virasoro orbits and the Hill equation yields a classification of the phase-locking domains in the parameter space in terms of the classification of Virasoro orbits. Our picture is supported by numerical simulations for the model of the Josephson junction and Mathieu equation.
format Preprint
id arxiv_https___arxiv_org_abs_2504_20181
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Phase-locking in dynamical systems and quantum mechanics
Alexandrov, Artem
Glutsyuk, Alexey
Gorsky, Alexander
Statistical Mechanics
High Energy Physics - Theory
Dynamical Systems
Pattern Formation and Solitons
Quantum Physics
In this study, we discuss the Prufer transform that connects the dynamical system on the torus and the Hill equation, which is interpreted as either the equation of motion for the parametric oscillator or the Schrodinger equation with periodic potential. The structure of phase-locking domains in the dynamical system on torus is mapped into the band-gap structure of the Hill equation. For the parametric oscillator, we provide the relation between the non-adiabatic Hannay angle and the Poincare rotation number of the corresponding dynamical system. In terms of quantum mechanics, the integer rotation number is connected to the quantization number via the Milne quantization approach and exact WKB. Using recent results concerning the exact WKB approach in quantum mechanics, we discuss the possible non-perturbative effects in the dynamical systems on the torus and for parametric oscillator. The semiclassical WKB is interpreted in the framework of a slow-fast dynamical system. The link between the classification of the coadjoint Virasoro orbits and the Hill equation yields a classification of the phase-locking domains in the parameter space in terms of the classification of Virasoro orbits. Our picture is supported by numerical simulations for the model of the Josephson junction and Mathieu equation.
title Phase-locking in dynamical systems and quantum mechanics
topic Statistical Mechanics
High Energy Physics - Theory
Dynamical Systems
Pattern Formation and Solitons
Quantum Physics
url https://arxiv.org/abs/2504.20181