PDE Methods For Optimal Skorokhod Embeddings
Abstract
We consider cost minimizing stopping time solutions to Skorokhod embedding problems, which deal with transporting a source probability measure to a given target measure through a stopped Brownian process. PDEs and a free boundary problem approach are used to address the problem in general dimensions with space-time inhomogeneous costs given by Lagrangian integrals along the paths. We introduce an Eulerian---mass flow---formulation of the problem, whose dual is given by Hamilton-Jacobi-Bellman type variational inequalities. Our key result is the existence (in a Sobolev class) of optimizers for this new dual problem, which in turn determines a free boundary, where the optimal Skorokhod transport drops the mass in space-time. This complements and provides a constructive PDE alternative to recent results of Beiglb\"ock, Cox, and Huesmann, and is a first step towards developing a general optimal mass transport theory involving mean field interactions and noise.
Cite
@article{arxiv.1807.10347,
title = {PDE Methods For Optimal Skorokhod Embeddings},
author = {Nassif Ghoussoub and Young-Heon Kim and Aaron Zeff Palmer},
journal= {arXiv preprint arXiv:1807.10347},
year = {2019}
}
Comments
This version contains revisions based on comments from an anonymous referee for the journal Calculus of Variations and PDE