Monotone Causality in Opportunistically Stochastic Shortest Path Problems
Abstract
When traveling through a graph with an accessible deterministic path to a target, is it ever preferable to resort to stochastic node-to-node transitions instead? And if so, what are the conditions guaranteeing that such a stochastic optimal routing policy can be computed efficiently? We aim to answer these questions here by defining a class of Opportunistically Stochastic Shortest Path (OSSP) problems and deriving sufficient conditions for applicability of non-iterative label-setting methods. The usefulness of this framework is demonstrated in two very different contexts: numerical analysis and autonomous vehicle routing. We use OSSPs to derive causality conditions for semi-Lagrangian discretizations of anisotropic Hamilton-Jacobi equations. We also use a Dijkstra-like method to solve OSSPs optimizing the timing and urgency of lane change maneuvers for an autonomous vehicle navigating road networks with a heterogeneous traffic load.
Cite
@article{arxiv.2310.14121,
title = {Monotone Causality in Opportunistically Stochastic Shortest Path Problems},
author = {Mallory E. Gaspard and Alexander Vladimirsky},
journal= {arXiv preprint arXiv:2310.14121},
year = {2025}
}
Comments
Submitted to and under review for INFORMS Mathematics of Operations Research. Revised to address first round feedback from reviewers for this journal