Mathematics > Probability
[Submitted on 30 Apr 2024]
Title:Specific Wasserstein divergence between continuous martingales
View PDF HTML (experimental)Abstract:Defining a divergence between the laws of continuous martingales is a delicate task, owing to the fact that these laws tend to be singular to each other. An important idea, put forward by N. Gantert, is to instead consider a scaling limit of the relative entropy between such continuous martingales sampled over a finite time grid. This gives rise to the concept of specific relative entropy. In order to develop a general theory of divergences between continuous martingales, it is only natural to replace the role of the relative entropy in this construction by a different notion of discrepancy between finite dimensional probability distributions. In the present work we take a first step in this direction, taking a power $p$ of the Wasserstein distance instead of the relative entropy. We call the newly obtained scaling limit the specific $p$-Wasserstein divergence.
In our first main result we prove that the specific $p$-Wasserstein divergence is well-defined, and exhibit an explicit expression for it in terms of the quadratic variations of the martingales involved. This is obtained under vastly weaker assumptions than the corresponding results for the specific relative entropy. Next we illustrate the usefulness of the concept, by considering the problem of optimizing the specific $p$-Wasserstein divergence over the set of win-martingales. In our second main result we characterize the solution of this optimization problem for all $p>0$ and, somewhat surprisingly, we single out the case $p=1/2$ as the one with the best probabilistic properties. For instance, the optimal martingale in this case is very explicit and can be connected, through a space transformation, to the solution of a variant of the Schrödinger problem.
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