Limiting Phase Trajectories: a new paradigm for the study of highly non-stationary processes in Nonlinear Physics

TL;DR

This paper introduces Limiting Phase Trajectories (LPTs), a new framework for understanding highly non-stationary energy transfer processes in nonlinear dynamical systems, extending beyond traditional normal mode analysis.

Contribution

The paper develops the LPT concept as a unified approach to describe non-stationary resonance energy transfer in classical and quantum systems, addressing limitations of existing paradigms.

Findings

LPTs characterize maximum energy exchange scenarios.

Application of LPTs to nonlinear problems reveals transition to chaos.

LPTs extend the understanding of non-stationary energy transfer beyond normal modes.

Abstract

This Report discusses a recently developed concept of Limiting Phase Trajectories (LPTs) providing a unified description of resonant energy transport in a wide range of classical and quantum dynamical systems with constant and time-varying parameters. It is shown that strongly modulated non-stationary processes occurring in a nonlinear oscillator array under certain initial conditions may characterize either maximum possible energy exchange between the clusters of oscillators (effective particles) or maximum energy transfer from an external source of energy to the system. The trajectories corresponding to these processes are referred to as LPTs. The development and the use of the LPT concept are motivated by the fact that highly non-stationary resonance processes occurring in a broad variety of finite-dimensional physical models are beyond the well-known paradigm of the nonlinear normal modes (NNMs), fully justified only for stationary processes, their stability and bifurcations, as well as for non-stationary processes described approximately by some combinations of non-resonating normal modes. Thus, the role of LPTs in understanding and description of non-stationary energy transfer is similar to the role of NNMs for the stationary processes. Several applications of the LPT concept to significant nonlinear problems and a scenario of the transition from regular to chaotic behavior with the LPTs implication are presented. In order to highlight the novelty and perspectives of the developed approach, we place the LPT concept into the context of complex dynamical phenomena related to energy transfer problems.