Fast phase randomisation via two-folds

TL;DR

This paper investigates how two-fold singularities in piecewise-smooth systems can rapidly randomize the phase of oscillators, offering a fast alternative to traditional phase desynchronization methods.

Contribution

It introduces a control law that leverages invisible two-folds to quickly randomize oscillator phases, enhancing synchronization control techniques.

Findings

Phase distribution depends on global nonlinear dynamics.

Applying a discontinuous control law induces rapid phase randomization.

The method outperforms existing slow phase desynchronization techniques.

Abstract

A two-fold is a singular point on the discontinuity surface of a piecewise-smooth vector field, at which the vector field is tangent to the discontinuity surface on both sides. If an orbit passes through an invisible two-fold (also known as a Teixeira singularity) before settling to regular periodic motion, then the phase of that motion cannot be determined from initial conditions, and in the presence of small noise the asymptotic phase of a large number of sample solutions is highly random. In this paper we show how the probability distribution of the asymptotic phase depends on the global nonlinear dynamics. We also show how the phase of a smooth oscillator can be randomised by applying a simple discontinuous control law that generates an invisible two-fold. We propose that such a control law can be used to desynchronise a collection of oscillators, and that this manner of phase randomisation is fast compared to existing methods (which use fixed points as phase singularities) because there is no slowing of the dynamics near a two-fold.