Convergence of the Adapted Smoothed Empirical Measures

The adapted Wasserstein distance controls the calibration errors of optimal values in various stochastic optimization problems, pricing and hedging problems, optimal stopping problems, etc. Motivated by approximating the true underlying distribution by empirical data, we consider empirical measures of $\mathbb{R}^d$-valued stochastic process in finite discrete-time. It is known that the empirical measures do not converge under the adapted Wasserstein distance. To address this issue, we consider convolutions of Gaussian kernels and empirical measures as an alternative, which we refer to the Gaussian-smoothed empirical measures. By setting the bandwidths of Gaussian kernels depending on the number of samples, we prove the convergence of the Gaussian-smoothed empirical measures to the true underlying measure in terms of mean, deviation, and almost sure convergence. Although Gaussian-smoothed empirical measures converge to the true underlying measure and can potentially enlarge data, they are not discrete measures and therefore not applicable in practice. Therefore, we combine Gaussian-smoothed empirical measures and the adapted empirical measures in \cite{acciaio2022convergence} to introduce the adapted smoothed empirical measures, which are discrete substitutes of the smoothed empirical measures. We establish the polynomial mean convergence rate, the exponential deviation convergence rate and the almost sure convergence of the adapted smoothed empirical measures.