English

First-Order Algorithms for Min-Max Optimization in Geodesic Metric Spaces

Optimization and Control 2022-09-29 v2 Machine Learning Differential Geometry

Abstract

From optimal transport to robust dimensionality reduction, a plethora of machine learning applications can be cast into the min-max optimization problems over Riemannian manifolds. Though many min-max algorithms have been analyzed in the Euclidean setting, it has proved elusive to translate these results to the Riemannian case. Zhang et al. [2022] have recently shown that geodesic convex concave Riemannian problems always admit saddle-point solutions. Inspired by this result, we study whether a performance gap between Riemannian and optimal Euclidean space convex-concave algorithms is necessary. We answer this question in the negative-we prove that the Riemannian corrected extragradient (RCEG) method achieves last-iterate convergence at a linear rate in the geodesically strongly-convex-concave case, matching the Euclidean result. Our results also extend to the stochastic or non-smooth case where RCEG and Riemanian gradient ascent descent (RGDA) achieve near-optimal convergence rates up to factors depending on curvature of the manifold.

Keywords

Cite

@article{arxiv.2206.02041,
  title  = {First-Order Algorithms for Min-Max Optimization in Geodesic Metric Spaces},
  author = {Michael I. Jordan and Tianyi Lin and Emmanouil-Vasileios Vlatakis-Gkaragkounis},
  journal= {arXiv preprint arXiv:2206.02041},
  year   = {2022}
}

Comments

39 pages, 12 figures, under submission

R2 v1 2026-06-24T11:39:21.788Z