English

On the Optimal Lower and Upper Complexity Bounds for a Class of Composite Optimization Problems

Optimization and Control 2023-08-15 v1

Abstract

We study the optimal lower and upper complexity bounds for finding approximate solutions to the composite problem minx f(x)+h(Axb)\min_x\ f(x)+h(Ax-b), where ff is smooth and hh is convex. Given access to the proximal operator of hh, for strongly convex, convex, and nonconvex ff, we design efficient first order algorithms with complexities O~(κAκflog(1/ϵ))\tilde{O}\left(\kappa_A\sqrt{\kappa_f}\log\left(1/{\epsilon}\right)\right), O~(κALfD/ϵ)\tilde{O}\left(\kappa_A\sqrt{L_f}D/\sqrt{\epsilon}\right), and O~(κALfΔ/ϵ2)\tilde{O}\left(\kappa_A L_f\Delta/\epsilon^2\right), respectively. Here, κA\kappa_A is the condition number of the matrix AA in the composition, LfL_f is the smoothness constant of ff, and κf\kappa_f is the condition number of ff in the strongly convex case. DD is the initial point distance and Δ\Delta is the initial function value gap. Tight lower complexity bounds for the three cases are also derived and they match the upper bounds up to logarithmic factors, thereby demonstrating the optimality of both the upper and lower bounds proposed in this paper.

Keywords

Cite

@article{arxiv.2308.06470,
  title  = {On the Optimal Lower and Upper Complexity Bounds for a Class of Composite Optimization Problems},
  author = {Zhenyuan Zhu and Fan Chen and Junyu Zhang and Zaiwen Wen},
  journal= {arXiv preprint arXiv:2308.06470},
  year   = {2023}
}
R2 v1 2026-06-28T11:54:09.945Z