A Near-Optimal Total Complexity for the Inexact Accelerated Proximal Gradient Method via Quadratic Growth

Abstract

We consider the optimization problem x∈ RnF(x):=f(x)+ω(Ax), where f is an L-Lipschitz smooth function, and ω is a proper, lower semicontinuous, and convex function. We prove in this paper that when ω is a conic polyhedral function, the inexact accelerated proximal gradient method (IAPG), employed in a double-loop structure, achieves a total complexity of O((1/)/) measured by the total number of calls to the proximal operator of the convex conjugate ω and the gradient of f to achieve -optimality in function value. To the best of our knowledge, this improves upon the best-known complexity for IAPG. The key theoretical ingredient is a quadratic growth condition on the dual of the inexact proximal problem, which arises from the conic polyhedral structure of ω and implies linear convergence of the inner proximal gradient loop. To validate these findings, we conduct numerical experiments on a robust TV-2 signal recovery problem, demonstrating fast convergence.