Dynamics of singularly perturbed sliding flow in Filippov systems

TL;DR

This paper analyzes how singular perturbations affect sliding motion in Filippov systems, revealing six phase space topologies and showing that perturbations can induce complex behaviors like micro chaos without altering flow direction significantly.

Contribution

It classifies six distinct phase space topologies caused by singular perturbations in Filippov systems and studies their effects on sliding and switching behaviors.

Findings

Six phase space topologies identified under singular perturbations.

Most topologies involve sliding segments, one involves switchings without sliding.

Singular perturbations can induce micro chaotic behavior in the flow.

Abstract

In this article, we present an analysis of the effects of singular perturbations on the sliding motion in Filippov systems. We show that singular perturbations may lead to qualitatively distinct topologies of phase space on the switching manifold, which we classify into six distinct topologies. Five of these topologies imply that singularly perturbed trajectory includes a segment (or segments) of sliding, and one topology, which we study here, implies the evolution characterised by switchings between trajectory segments along the switching surface, but without any sliding. In particular, we show that in the case of $n$-dimensional Filippov systems with one switching surface and $m$-dimensional fast dynamics, which plays the role of a stable singular perturbation, the flow follows sliding motion of the reduced system, but the perturbation becomes time dependent and may create a micro chaotic behaviour. However, a significant change in the flow direction is not possible. In the particular case of $1$-dimensional fast dynamics, the singular perturbation implies regular perturbation of $O(\varepsilon)$ of the perturbed flow at the points of switching between vector fields.