Convergence of the adapted empirical measure for mixing observations
Abstract
The adapted Wasserstein distance AW is a modification of the classical Wasserstein metric, that provides robust and dynamically consistent comparisons of laws of stochastic processes, and has proved particularly useful in the analysis of stochastic control problems, model uncertainty, and mathematical finance. In applications, the law of a stochastic process μ is not directly observed, and has to be inferred from a finite number of samples. As the empirical measure is not AW-consistent, Backhoff, Bartl, Beiglb\"ock and Wiesel introduced the adapted empirical measure μN, a suitable modification, and proved its AW-consistency when observations are i.i.d. In this paper we study AW-convergence of the adapted empirical measure μN to the population distribution μ, for observations satisfying a generalization of the η-mixing condition introduced by Kontorovich and Ramanan. We establish moment bounds and sub-exponential concentration inequalities for AW(μ,μN), and prove consistency of μN. In addition, we extend the Bounded Differences inequality of Kontorovich and Ramanan for η-mixing observations to uncountable spaces, a result that may be of independent interest. Numerical simulations illustrating our theory are also provided.
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