Second-Order Bilevel Optimization with Accelerated Convergence Rates
Abstract
This paper studies second-order methods for nonconvex-strongly-convex bilevel optimization. We propose a novel fully second-order bilevel approximation method (FSBA) that achieves an iteration complexity of for finding the second-order stationary point of the hyper-objective function. Our results demonstrate that second-order methods can achieve an accelerated convergence rate than first-order methods in bilevel optimization. To address the heavy computational cost associated with the second-order oracle, we introduce a lazy variant of FSBA, called LFSBA, which reuses second-order information across several iterations. We prove that LFSBA exhibits better computational complexity than FSBA by a factor of , where is the dimension of the problem. We also apply a similar idea to nonconvex strongly-concave minimax optimization and propose the lazy minimax cubic-regularized Newton (LMCN) method with better computational complexity compared to existing second-order methods.
Cite
@article{arxiv.2605.06431,
title = {Second-Order Bilevel Optimization with Accelerated Convergence Rates},
author = {Sheng Yang and Chengchang Liu and Lesi Chen and John C. S. Lui},
journal= {arXiv preprint arXiv:2605.06431},
year = {2026}
}
Comments
This paper is accepted by ICML 26