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A Regularized Newton Method for Nonconvex Optimization with Global and Local Complexity Guarantees

Optimization and Control 2025-11-03 v3 Machine Learning

Abstract

Finding an ϵ\epsilon-stationary point of a nonconvex function with a Lipschitz continuous Hessian is a central problem in optimization. Regularized Newton methods are a classical tool and have been studied extensively, yet they still face a trade-off between global and local convergence. Whether a parameter-free algorithm of this type can simultaneously achieve optimal global complexity and quadratic local convergence remains an open question. To bridge this long-standing gap, we propose a new class of regularizers constructed from the current and previous gradients, and leverage the conjugate gradient approach with a negative curvature monitor to solve the regularized Newton equation. The proposed algorithm is adaptive, requiring no prior knowledge of the Hessian Lipschitz constant, and achieves a global complexity of O(ϵ3/2)O(\epsilon^{-3/2}) in terms of the second-order oracle calls, and O~(ϵ7/4)\tilde{O}(\epsilon^{-7/4}) for Hessian-vector products, respectively. When the iterates converge to a point where the Hessian is positive definite, the method exhibits quadratic local convergence. Preliminary numerical results, including training the physics-informed neural networks, illustrate the competitiveness of our algorithm.

Keywords

Cite

@article{arxiv.2502.04799,
  title  = {A Regularized Newton Method for Nonconvex Optimization with Global and Local Complexity Guarantees},
  author = {Yuhao Zhou and Jintao Xu and Bingrui Li and Chenglong Bao and Chao Ding and Jun Zhu},
  journal= {arXiv preprint arXiv:2502.04799},
  year   = {2025}
}

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NeurIPS 2025

R2 v1 2026-06-28T21:35:55.549Z