Quadratically Regularized Optimal Transport: Localization Bounds and Affine Case Analysis
摘要
Quadratic regularization has emerged as a potential alternative to the popular entropic regularization in computational optimal transport, offering the theoretical advantage of producing sparse couplings through its hinge density structure. Despite recent progress in one-dimensional settings and general upper bounds, fundamental questions about the localization rate of QOT optimizers around the Monge coupling have remained open. In this work, we establish a general lower bound showing that the support of the QOT optimizer cannot concentrate around the Monge graph faster than order in the directed Hausdorff distance, matching the conjectured optimal exponent under standard regularity assumptions in \citet{wiesel2025sparsity}. We also show that the QOT value gap controls the mean-squared deviation by the scale of . As a corollary, in the affine Brenier regime, which includes Gaussian-to-Gaussian transport, we derive a sharp pointwise tube bound of order by reducing the problem to self-transport and applying recent self-transport sparsity results. Finally, we validate our theoretical bound with a synthetic experiment in high-dimensional settings.
引用
@article{arxiv.2605.24644,
title = {Quadratically Regularized Optimal Transport: Localization Bounds and Affine Case Analysis},
author = {Long Nguyen-Chi and Nam Nguyen and Binh Nguyen},
journal= {arXiv preprint arXiv:2605.24644},
year = {2026}
}