Operator Splitting, Policy Iteration, and Machine Learning for Stochastic Optimal Control
Abstract
We propose a splitting approach to solve the second-order Hamilton--Jacobi equation, reducing it to a heat step and a purely first-order step. The latter is implemented using a gradient value policy iteration algorithm, enabling efficient characteristic-based machine learning methods. We establish convergence rates for the splitting method. In particular, with the splitting step, the error is bounded between and for Lipschitz data, improving to for semiconcave data. In the periodic setting, we also obtain an error of order . For the first-order step, we provide a weighted error analysis that shows exponential convergence. Each iteration solves linear characteristic equations and learns the value function by minimizing a weighted value gradient loss. The approach yields stable and accurate numerical results.
Cite
@article{arxiv.2603.12167,
title = {Operator Splitting, Policy Iteration, and Machine Learning for Stochastic Optimal Control},
author = {Alain Bensoussan and Thien P. B. Nguyen and Minh-Binh Tran and Son N. T. Tu},
journal= {arXiv preprint arXiv:2603.12167},
year = {2026}
}
Comments
37 pages, with improved results for Theorem 1.1