Estimating causal distances with non-causal ones

Abstract

The adapted Wasserstein (AW) distance refines the classical Wasserstein (W) distance by incorporating the temporal structure of stochastic processes. This makes the AW-distance well-suited as a robust distance for many dynamic stochastic optimization problems where the classical W-distance fails. However, estimating the AW-distance is a notably challenging task, compared to the classical W-distance. In the present work, we build a sharp estimate for the AW-distance in terms of the W-distance, for smooth measures. This reduces estimating the AW-distance to estimating the W-distance, where many well-established classical results can be leveraged. As an application, we prove a fast convergence rate of the kernel-based empirical estimator under the AW-distance, which approaches the Monte-Carlo rate (n-1/2) in the regime of highly regular densities. These results are accomplished by deriving a sharp bi-Lipschitz estimate of the adapted total variation distance by the classical total variation distance.