English

Second-order Optimization under Heavy-Tailed Noise: Hessian Clipping and Sample Complexity Limits

Optimization and Control 2025-10-14 v1 Machine Learning

Abstract

Heavy-tailed noise is pervasive in modern machine learning applications, arising from data heterogeneity, outliers, and non-stationary stochastic environments. While second-order methods can significantly accelerate convergence in light-tailed or bounded-noise settings, such algorithms are often brittle and lack guarantees under heavy-tailed noise -- precisely the regimes where robustness is most critical. In this work, we take a first step toward a theoretical understanding of second-order optimization under heavy-tailed noise. We consider a setting where stochastic gradients and Hessians have only bounded pp-th moments, for some p(1,2]p\in (1,2], and establish tight lower bounds on the sample complexity of any second-order method. We then develop a variant of normalized stochastic gradient descent that leverages second-order information and provably matches these lower bounds. To address the instability caused by large deviations, we introduce a novel algorithm based on gradient and Hessian clipping, and prove high-probability upper bounds that nearly match the fundamental limits. Our results provide the first comprehensive sample complexity characterization for second-order optimization under heavy-tailed noise. This positions Hessian clipping as a robust and theoretically sound strategy for second-order algorithm design in heavy-tailed regimes.

Keywords

Cite

@article{arxiv.2510.10690,
  title  = {Second-order Optimization under Heavy-Tailed Noise: Hessian Clipping and Sample Complexity Limits},
  author = {Abdurakhmon Sadiev and Peter Richtárik and Ilyas Fatkhullin},
  journal= {arXiv preprint arXiv:2510.10690},
  year   = {2025}
}

Comments

Accepted for publication at NeurIPS 2025

R2 v1 2026-07-01T06:32:27.685Z