English

Exact Worst-case Performance of First-order Methods for Composite Convex Optimization

Optimization and Control 2019-11-22 v4

Abstract

We provide a framework for computing the exact worst-case performance of any algorithm belonging to a broad class of oracle-based first-order methods for composite convex optimization, including those performing explicit, projected, proximal, conditional and inexact (sub)gradient steps. We simultaneously obtain tight worst-case guarantees and explicit instances of optimization problems on which the algorithm reaches this worst-case. We achieve this by reducing the computation of the worst-case to solving a convex semidefinite program, generalizing previous works on performance estimation by Drori and Teboulle [13] and the authors [43]. We use these developments to obtain a tighter analysis of the proximal point algorithm and of several variants of fast proximal gradient, conditional gradient, subgradient and alternating projection methods. In particular, we present a new analytical worst-case guarantee for the proximal point algorithm that is twice better than previously known, and improve the standard worst-case guarantee for the conditional gradient method by more than a factor of two. We also show how the optimized gradient method proposed by Kim and Fessler in [22] can be extended by incorporating a projection or a proximal operator, which leads to an algorithm that converges in the worst-case twice as fast as the standard accelerated proximal gradient method [2].

Keywords

Cite

@article{arxiv.1512.07516,
  title  = {Exact Worst-case Performance of First-order Methods for Composite Convex Optimization},
  author = {Adrien B. Taylor and Julien M. Hendrickx and François Glineur},
  journal= {arXiv preprint arXiv:1512.07516},
  year   = {2019}
}

Comments

Published in SIOPT (updated version with corrected typo) Code available at https://github.com/AdrienTaylor/Performance-Estimation-Toolbox

R2 v1 2026-06-22T12:16:49.424Z