English

Linear Convergence Analysis of Single-loop Algorithm for Bilevel Optimization via Small-gain Theorem

Optimization and Control 2024-12-03 v1

Abstract

Bilevel optimization has gained considerable attention due to its broad applicability across various fields. While several studies have investigated the convergence rates in the strongly-convex-strongly-convex (SC-SC) setting, no prior work has proven that a single-loop algorithm can achieve linear convergence. This paper employs a small-gain theorem in {robust control theory} to demonstrate that a single-loop algorithm based on the implicit function theorem attains a linear convergence rate of O(ρk)\mathcal{O}(\rho^{k}), where ρ(0,1)\rho\in(0,1) is specified in Theorem 3. Specifically, We model the algorithm as a dynamical system by identifying its two interconnected components: the controller (the gradient or approximate gradient functions) and the plant (the update rule of variables). We prove that each component exhibits a bounded gain and that, with carefully designed step sizes, their cascade accommodates a product gain strictly less than one. Consequently, the overall algorithm can be proven to achieve a linear convergence rate, as guaranteed by the small-gain theorem. The gradient boundedness assumption adopted in the single-loop algorithm (\cite{hong2023two, chen2022single}) is replaced with a gradient Lipschitz assumption in Assumption 2.2. To the best of our knowledge, this work is first-known result on linear convergence for a single-loop algorithm.

Keywords

Cite

@article{arxiv.2412.00659,
  title  = {Linear Convergence Analysis of Single-loop Algorithm for Bilevel Optimization via Small-gain Theorem},
  author = {Jianhui Li and Shi Pu and Jianqi Chen and Junfeng Wu},
  journal= {arXiv preprint arXiv:2412.00659},
  year   = {2024}
}
R2 v1 2026-06-28T20:18:19.117Z