Existence and non-existence of the CLT for a family of SDEs driven by stable process
Abstract
Stochastic differential equations (SDEs) without global Lipschitz drift often demonstrate unusual phenomena. In this paper, we consider the following SDE on Rd: align* d Xt=b(Xt) d t+ dZt, X0=x ∈ Rd, align* where Zt is the rotationally symmetric α-stable process with α ∈(1,2) and b:Rd → Rd is a differentiable function satisfying the following condition: there exist some θ 0, and K1 , K2 , L>0, so that b(x)-b(y), x-y ≤slant K1 |x-y|2, \ \ ∀ \ \ |x-y| ≤slant L, b(x)-b(y), x-y ≤slant -K2 |x-y|2+θ, \ \ ∀ \ \ |x-y| > L. Under this assumption, the SDE admits a unique invariant measure μ. We investigate the normal central limit theorem (CLT) of the empirical measures Etx(·)=1t ∫0t δXs (·) d s, \ \ \ \ X0=x ∈ Rd, \ \ t>0, where δx(·) is the Dirac delta measure. Our results reveal that, for the bounded measurable function h, t (Etx(h)-μ(h))=1 t ∫0t (h(Xsx)-μ(h)) d s admits a normal CLT for θ ≥slant 0. For the Lipschitz continuous function h, the normal CLT does not necessarily hold when θ=0, but it is satisfied for θ>1-α2.
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