English

Scaling Law for Stochastic Gradient Descent in Quadratically Parameterized Linear Regression

Machine Learning 2025-02-14 v1

Abstract

In machine learning, the scaling law describes how the model performance improves with the model and data size scaling up. From a learning theory perspective, this class of results establishes upper and lower generalization bounds for a specific learning algorithm. Here, the exact algorithm running using a specific model parameterization often offers a crucial implicit regularization effect, leading to good generalization. To characterize the scaling law, previous theoretical studies mainly focus on linear models, whereas, feature learning, a notable process that contributes to the remarkable empirical success of neural networks, is regretfully vacant. This paper studies the scaling law over a linear regression with the model being quadratically parameterized. We consider infinitely dimensional data and slope ground truth, both signals exhibiting certain power-law decay rates. We study convergence rates for Stochastic Gradient Descent and demonstrate the learning rates for variables will automatically adapt to the ground truth. As a result, in the canonical linear regression, we provide explicit separations for generalization curves between SGD with and without feature learning, and the information-theoretical lower bound that is agnostic to parametrization method and the algorithm. Our analysis for decaying ground truth provides a new characterization for the learning dynamic of the model.

Keywords

Cite

@article{arxiv.2502.09106,
  title  = {Scaling Law for Stochastic Gradient Descent in Quadratically Parameterized Linear Regression},
  author = {Shihong Ding and Haihan Zhang and Hanzhen Zhao and Cong Fang},
  journal= {arXiv preprint arXiv:2502.09106},
  year   = {2025}
}
R2 v1 2026-06-28T21:42:48.223Z