A Truncated Newton Method for Optimal Transport
Abstract
Developing a contemporary optimal transport (OT) solver requires navigating trade-offs among several critical requirements: GPU parallelization, scalability to high-dimensional problems, theoretical convergence guarantees, empirical performance in terms of precision versus runtime, and numerical stability in practice. With these challenges in mind, we introduce a specialized truncated Newton algorithm for entropic-regularized OT. In addition to proving that locally quadratic convergence is possible without assuming a Lipschitz Hessian, we provide strategies to maximally exploit the high rate of local convergence in practice. Our GPU-parallel algorithm exhibits exceptionally favorable runtime performance, achieving high precision orders of magnitude faster than many existing alternatives. This is evidenced by wall-clock time experiments on 24 problem sets (12 datasets 2 cost functions). The scalability of the algorithm is showcased on an extremely large OT problem with , solved approximately under weak entopric regularization.
Cite
@article{arxiv.2504.02067,
title = {A Truncated Newton Method for Optimal Transport},
author = {Mete Kemertas and Amir-massoud Farahmand and Allan D. Jepson},
journal= {arXiv preprint arXiv:2504.02067},
year = {2025}
}
Comments
Accepted to ICLR 2025