Averaging for stochastic perturbations of integrable systems

Abstract

We are concerned with averaging theorems for ε-small stochastic perturbations of integrable equations in Rd × Tn =\(I,)\ I(t) =0, (t) = θ(I), (1) and in R2n = \v=(v1, …, vn), \; vj ∈ R2\, vk(t) =Wk(I) vk, k=1, …, n, (2) where I=(I1, …, In) is the vector of actions, Ij = 12 \| vj\|2. The vector-functions θ and W are locally Lipschitz and non-degenerate. Perturbations of these equations are assumed to be locally Lipschitz and such that some few first moments of the norms of their solutions are bounded uniformly in ε, for 0 t ε-1 T. For I-components of solutions for perturbations of (1) we establish their convergence in law to solutions of the corresponding averaged I-equations, when 0 τ := ε t T and ε0. Then we show that if the system of averaged I-equations is mixing, then the convergence is uniform in the slow time τ=ε t0. Next using these results, for ε-perturbed equations of (2) we construct well posed effective stochastic equations for v(τ)∈ R2n (independent from ε) such that when ε0, actions of solutions of the perturbed equations of (2) with t:= τ/ε converge in distribution to actions of solutions for the effective equations. Again, if the effective system is mixing, this convergence is uniform in the slow time τ 0. We provide easy sufficient conditions on the perturbed equations which ensure that our results apply to their solutions.