Slow-fast systems with stochastic resetting

Abstract

In this paper we explore the effects of instantaneous stochastic resetting on a planar slow-fast dynamical system of the form x=f(x)-y and y=ε (x-y) with 0<ε 1. We assume that only the fast variable x(t) resets to its initial state x0 at a random sequence of times generated from a Poisson process of rate r. Fixing the slow variable, we determine the parameterized probability density p(x,t|y), which is the solution to a modified Liouville equation. We then show how for r ε the slow dynamics can be approximated by the averaged equation dy/dτ=[x|y]-y where τ=ε t, [x|y]=∫ x p*(x|y)dx and p*(x|y)=t→ ∞p(x,t|y). We illustrate the theory for f(x) given by the cubic function of the FitzHugh-Nagumo equation. We find that the slow variable typically converges to an r-dependent fixed point y* that is a solution of the equation y*=[x|y*]. Finally, we numerically explore deviations from averaging theory when r=O(ε).

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