Rate of convergence of the Nesterov accelerated gradient method in the subcritical case α ≤ 3

Abstract

In a Hilbert space setting H, given : H R a convex continuously differentiable function, and α a positive parameter, we consider the inertial system with Asymptotic Vanishing Damping equation* (AVD)α x(t) + αt x(t) + ∇ (x(t)) =0. equation* Depending on the value of α with respect to 3, we give a complete picture of the convergence properties as t + ∞ of the trajectories generated by (AVD)α, as well as iterations of the corresponding algorithms. Our main result concerns the subcritical case α ≤ 3, where we show that (x(t))- = O (t-23α). Then we examine the convergence of trajectories to optimal solutions. As a new result, in the one-dimensional framework, for the critical value α = 3 , we prove the convergence of the trajectories without any restrictive hypothesis on the convex function . In the second part of this paper, we study the convergence properties of the associated forward-backward inertial algorithms. They aim to solve structured convex minimization problems of the form := + , with smooth and nonsmooth. The continuous dynamics serves as a guideline for this study. We obtain a similar rate of convergence for the sequence of iterates (xk): for α ≤ 3 we have (xk)- = O (k-p) for all p <2α3 , and for α > 3 \ (xk)- = o (k-2) . We conclude this study by showing that the results are robust with respect to external perturbations.