Accelerated Methods for Riemannian Min-Max Optimization Ensuring Bounded Geometric Penalties

Abstract

In this work, we study optimization problems of the form x y f(x, y), where f(x, y) is defined on a product Riemannian manifold M × N and is μx-strongly geodesically convex (g-convex) in x and μy-strongly g-concave in y, for μx, μy ≥ 0. We design accelerated methods when f is (Lx, Ly, Lxy)-smooth and M, N are Hadamard. To that aim we introduce new g-convex optimization results, of independent interest: we show global linear convergence for metric-projected Riemannian gradient descent and improve existing accelerated methods by reducing geometric constants. Additionally, we complete the analysis of two previous works applying to the Riemannian min-max case by removing an assumption about iterates staying in a pre-specified compact set.