Robust Sublinear Convergence Rates for Iterative Bregman Projections
Abstract
Entropic regularization provides a simple way to approximate linear programs whose constraints split into two or more tractable blocks. The resulting objectives are amenable to cyclic Kullback-Leibler (KL) Bregman projections, with Sinkhorn-type algorithms for optimal transport, matrix scaling, and barycenters as canonical examples. This paper gives a general blueprint for proving dual convergence rate with a constant that scales only linearly in , where is the entropic regularization parameter. We call such rates "robust", because this mild dependence on underpins favorable complexity bounds for approximating the unregularized problem via alternating KL projections. The blueprint reduces the proof to a uniform primal bound and a dual bound for a quotient norm induced by the constraint split. To make these inputs usable, we propose two helper results, which rely on the non-expansiveness of the dual iterations in this quotient dual norm. Instantiating this blueprint for graph-structured transport yields a new flow-Sinkhorn algorithm for the Wasserstein-1 distance on graphs. It achieves -additive accuracy on the transshipment cost in arithmetic operations (up to logarithmic factors), where is the number of edges. We also provide a machine-checked Lean formalization of the core blueprint and its graph- instantiation.
Cite
@article{arxiv.2602.01372,
title = {Robust Sublinear Convergence Rates for Iterative Bregman Projections},
author = {Gabriel Peyré},
journal= {arXiv preprint arXiv:2602.01372},
year = {2026}
}