Rate of convergence of the smoothed empirical Wasserstein distance
Abstract
Consider an empirical measure Pn induced by n iid samples from a d-dimensional K-subgaussian distribution P and let γ = N(0,σ2 Id) be the isotropic Gaussian measure. We study the speed of convergence of the smoothed Wasserstein distance W2(Pn * γ, P*γ) = n-α + o(1) with * being the convolution of measures. For K<σ and in any dimension d 1 we show that α = 12. For K>σ in dimension d=1 we show that the rate is slower and is given by α = (σ2 + K2)2 4 (σ4 + K4) < 1/2. This resolves several open problems in [GGNWP20], and in particular precisely identifies the amount of smoothing σ needed to obtain a parametric rate. In addition, for any d-dimensional K-subgaussian distribution P, we also establish that DKL(Pn * γ \|P*γ) has rate O(1/n) for K<σ but only slows down to O(( n)d+1 n) for K>σ. The surprising difference of the behavior of W22 and KL implies the failure of T2-transportation inequality when σ < K. Consequently, it follows that for K>σ the log-Sobolev inequality (LSI) for the Gaussian mixture P * N(0, σ2) cannot hold. This closes an open problem in [WW+16], who established the LSI under the condition K<σ and asked if their bound can be improved.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.