Random Switching between Vector Fields Having a Common Zero

Abstract

Let E be a finite set, \Fi\i ∈ E a family of vector fields on Rd leaving positively invariant a compact set M and having a common zero p ∈ M. We consider a piecewise deterministic Markov process (X,I) on M × E defined by Xt = FIt(Xt) where I is a jump process controlled by X: (It+s = j | (Xu, Iu)u ≤ t) = ai j(Xt) s + o(s) for i ≠ j on \It = i \. We show that the behavior of (X,I) is mainly determined by the behavior of the linearized process (Y,J) where Yt = AJt Yt, Ai is the Jacobian matrix of Fi at p and J is the jump process with rates (aij(p)). We introduce two quantities - and + respectively %called the minimal and maximal average growth rate. - (respectively +) is defined as the minimal (respectively maximal) growth rate of \|Yt\|, where the minimum (respectively maximum) is taken over all the ergodic measures of the angular process (, J) with t = Yt\|Yt\|. It is shown that + coincides with the top Lyapunov exponent (in the sense of ergodic theory) of (Y,J) and that under general assumptions - = +. We then prove that, under certain irreducibility conditions, Xt p exponentially fast when + < 0 and (X,I) converges in distribution at an exponential rate toward a (unique) invariant measure supported by M \p\ × E when - > 0. Some applications to certain epidemic models in a fluctuating environment are discussed and illustrate our results.