Accelerated Bregman proximal gradient methods for relatively smooth convex optimization

Abstract

We consider the problem of minimizing the sum of two convex functions: one is differentiable and relatively smooth with respect to a reference convex function, and the other can be nondifferentiable but simple to optimize. We investigate a triangle scaling property of the Bregman distance generated by the reference convex function and present accelerated Bregman proximal gradient (ABPG) methods that attain an $$O(k^{-\gamma })$$ convergence rate, where $$\gamma \in (0,2]$$ is the triangle scaling exponent (TSE) of the Bregman distance. For the Euclidean distance, we have $$\gamma =2$$ and recover the convergence rate of Nesterov’s accelerated gradient methods. For non-Euclidean Bregman distances, the TSE can be much smaller (say $$\gamma \le 1$$ ), but we show that a relaxed definition of intrinsic TSE is always equal to 2. We exploit the intrinsic TSE to develop adaptive ABPG methods that converge much faster in practice. Although theoretical guarantees on a fast convergence rate seem to be out of reach in general, our methods obtain empirical $$O(k^{-2})$$ rates in numerical experiments on several applications and provide posterior numerical certificates for the fast rates.