The fast rate of convergence of the smooth adapted Wasserstein distance
Abstract
Estimating a d-dimensional distribution μ by the empirical measure μn of its samples is an important task in probability theory, statistics and machine learning. It is well known that E[Wp(μn, μ)] n-1/d for d>2p, where Wp denotes the p-Wasserstein metric. An effective tool to combat this curse of dimensionality is the smooth Wasserstein distance W(σ)p, which measures the distance between two probability measures after having convolved them with isotropic Gaussian noise N(0,σ2I). In this paper we apply this smoothing technique to the adapted Wasserstein distance. We show that the smooth adapted Wasserstein distance AWp(σ) achieves the fast rate of convergence E[AWp(σ)(μn, μ)] n-1/2, if μ is subgaussian. This result follows from the surprising fact, that any subgaussian measure μ convolved with a Gaussian distribution has locally Lipschitz kernels.
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