Limit Theorems in Warsserstein Distance for Empirical Measures of Diffusion Processes on Riemannian Manifolds

Abstract

Let M be a compact connected Riemannian manifold possibly with a boundary, let V∈ C2(M) such that μ(d x):=eV(x)d x is a probability measure, and let \λi\i 1 be all non-trivial eigenvalues of -L with Neumann boundary condition if the boundary exists. Then the empirical measures \μt\t>0 of the diffusion process generated by L (with reflecting boundary if the boundary exists) satisfy t ∞ \t Ex [W2(μt,μ)2]\= Σi=1∞ 2 λi2\ uniformly\ in\ x∈ M, where Ex denotes the expectation for the diffusion process starting at point x, W2 is the L2-Warsserstein distance induced by the Riemannian metric. The limit is finite if and only if d 3, and in this case we derive the following central limit theorem: t∞ x∈ M | Px(t W2(μt,μ)2<a)- P( Σk=1∞ 2k2λk2<a)|=0, \ \ a 0, where Px is the probability with respect to Ex, and \k\k 1 are i.i.d. standard Gaussian random variables. Moreover, when d 4 we prove that the main order of Ex[W2(μt,μ)2] is t- 2 d-2 as t∞. Moreover, when d 4 the main order of Ex[W2(μt,μ)2] is t- 2 d-2 as t∞. Finally, we establish the long-time large deviation principle for \W2(μt,μ)2\t 0 with a good rate function given by the information with respect to μ.