Interpolation Conditions for Linear Operators and Applications to Performance Estimation Problems
Abstract
The Performance Estimation Problem methodology makes it possible to determine the exact worst-case performance of an optimization method. In this work, we generalize this framework to first-order methods involving linear operators. This extension requires an explicit formulation of interpolation conditions for those linear operators. We consider the class of linear operators where matrix has bounded singular values, and the class of linear operators where is symmetric and has bounded eigenvalues. We describe interpolation conditions for these classes, i.e. necessary and sufficient conditions that, given a list of pairs , characterize the existence of a linear operator mapping to for all . Using these conditions, we first identify the exact worst-case behavior of the gradient method applied to the composed objective , and observe that it always corresponds to being a scaling operator. We then investigate the Chambolle-Pock method applied to , and improve the existing analysis to obtain a proof of the exact convergence rate of the primal-dual gap. In addition, we study how this method behaves on Lipschitz convex functions, and obtain a numerical convergence rate for the primal accuracy of the last iterate. We also show numerically that averaging iterates is beneficial in this setting.
Cite
@article{arxiv.2302.08781,
title = {Interpolation Conditions for Linear Operators and Applications to Performance Estimation Problems},
author = {Nizar Bousselmi and Julien M. Hendrickx and François Glineur},
journal= {arXiv preprint arXiv:2302.08781},
year = {2024}
}
Comments
Proof of the main interpolation theorem is streamlined. Added results about the Chambolle-Pock algorithm including the exact convergence rate of the primal-dual gap in a standard setting