CaCuTe: Casual Cubic-Model Technique for Faster Optimization
Abstract
We establish a local rate for the gradient update under a -Hessian--Lipschitz assumption. Regime detection relies on Hessian--vector products, avoiding Hessian formation or factorization. Incorporating this certificate into cubic-regularized Newton (CRN) and an accelerated variant enables per-iterate switching between the cubic and gradient steps while preserving CRN's global guarantees. The technique achieves the lowest wall-clock time among compared baselines in our experiments. In the first-order setting, the technique yields a monotone, adaptive, parameter-free method that inherits the local rate. Despite backtracking, the method shows superior wall-clock performance. Additionally, we cover smoothness relaxations beyond classical gradient--Lipschitzness, enabling tighter bounds, including global rates. Finally, we generalize the technique to the stochastic setting.
Cite
@article{arxiv.2509.18508,
title = {CaCuTe: Casual Cubic-Model Technique for Faster Optimization},
author = {Nazarii Tupitsa},
journal= {arXiv preprint arXiv:2509.18508},
year = {2025}
}