Saved in:
Bibliographic Details
Main Authors: Tsingalis, Ioannis, Kotropoulos, Constantine, Briat, Corentin
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.09437
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910119551303680
author Tsingalis, Ioannis
Kotropoulos, Constantine
Briat, Corentin
author_facet Tsingalis, Ioannis
Kotropoulos, Constantine
Briat, Corentin
contents A novel regularization technique, AdaCubic, is proposed that adapts the weight of the cubic term. The heart of AdaCubic is an auxiliary optimization problem with cubic constraints that dynamically adjusts the weight of the cubic term in Newton's cubic regularized method. We use Hutchinson's method to approximate the Hessian matrix, thereby reducing computational cost. We demonstrate that AdaCubic inherits the cubically regularized Newton method's local convergence guarantees. Our experiments in Computer Vision, Natural Language Processing, and Signal Processing tasks demonstrate that AdaCubic outperforms or competes with several widely used optimizers. Unlike other adaptive algorithms that require hyperparameter fine-tuning, AdaCubic is evaluated with a fixed set of hyperparameters, rendering it a highly attractive optimizer in settings where fine-tuning is infeasible. This makes AdaCubic an attractive option for researchers and practitioners alike. To our knowledge, AdaCubic is the first optimizer to leverage cubic regularization in scalable deep learning applications.
format Preprint
id arxiv_https___arxiv_org_abs_2604_09437
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle AdaCubic: An Adaptive Cubic Regularization Optimizer for Deep Learning
Tsingalis, Ioannis
Kotropoulos, Constantine
Briat, Corentin
Machine Learning
A novel regularization technique, AdaCubic, is proposed that adapts the weight of the cubic term. The heart of AdaCubic is an auxiliary optimization problem with cubic constraints that dynamically adjusts the weight of the cubic term in Newton's cubic regularized method. We use Hutchinson's method to approximate the Hessian matrix, thereby reducing computational cost. We demonstrate that AdaCubic inherits the cubically regularized Newton method's local convergence guarantees. Our experiments in Computer Vision, Natural Language Processing, and Signal Processing tasks demonstrate that AdaCubic outperforms or competes with several widely used optimizers. Unlike other adaptive algorithms that require hyperparameter fine-tuning, AdaCubic is evaluated with a fixed set of hyperparameters, rendering it a highly attractive optimizer in settings where fine-tuning is infeasible. This makes AdaCubic an attractive option for researchers and practitioners alike. To our knowledge, AdaCubic is the first optimizer to leverage cubic regularization in scalable deep learning applications.
title AdaCubic: An Adaptive Cubic Regularization Optimizer for Deep Learning
topic Machine Learning
url https://arxiv.org/abs/2604.09437