The influence of localised randomness on regular grazing bifurcations with applications to impacting dynamics

TL;DR

This paper investigates how localized stochastic perturbations influence grazing bifurcations in impact oscillators, deriving stochastic Nordmark maps to understand the impact of different noise sources on system dynamics.

Contribution

It introduces three novel stochastic Nordmark maps modeling impact oscillator dynamics under various noise influences, highlighting the importance of noise type on bifurcation behavior.

Findings

Stochastic dynamics vary significantly with noise source.

Derived maps show nonlinear and multiplicative noise effects.

Impact of noise type on bifurcation structure is demonstrated.

Abstract

This paper concerns stochastic perturbations of piecewise-smooth ODE systems relevant for vibro-impacting dynamics, where impact events constitute the primary source of randomness. Such systems are characterised by the existence of switching manifolds that divide the phase space into regions where the system is smooth. The initiation of impacts is captured by a grazing bifurcation, at which a periodic orbit describing motion without impacts develops a tangential intersection with a switching manifold. Oscillatory dynamics near regular grazing bifurcations are described by piecewise-smooth maps involving a square-root singularity, known as Nordmark maps. We consider three scenarios where coloured noise only affects impacting dynamics, and derive three two-dimensional stochastic Nordmark maps with the noise appearing in different nonlinear or multiplicative ways, depending on the source of the noise. Consequently the stochastic dynamics differs between the three noise sources, and is fundamentally different to that of a Nordmark map with additive noise. This critical dependence on the nature of the noise is illustrated with a prototypical one-degree-of-freedom impact oscillator.