English

Component-based Sketching for Deep ReLU Nets

Machine Learning 2024-09-24 v1 Statistics Theory Statistics Theory

Abstract

Deep learning has made profound impacts in the domains of data mining and AI, distinguished by the groundbreaking achievements in numerous real-world applications and the innovative algorithm design philosophy. However, it suffers from the inconsistency issue between optimization and generalization, as achieving good generalization, guided by the bias-variance trade-off principle, favors under-parameterized networks, whereas ensuring effective convergence of gradient-based algorithms demands over-parameterized networks. To address this issue, we develop a novel sketching scheme based on deep net components for various tasks. Specifically, we use deep net components with specific efficacy to build a sketching basis that embodies the advantages of deep networks. Subsequently, we transform deep net training into a linear empirical risk minimization problem based on the constructed basis, successfully avoiding the complicated convergence analysis of iterative algorithms. The efficacy of the proposed component-based sketching is validated through both theoretical analysis and numerical experiments. Theoretically, we show that the proposed component-based sketching provides almost optimal rates in approximating saturated functions for shallow nets and also achieves almost optimal generalization error bounds. Numerically, we demonstrate that, compared with the existing gradient-based training methods, component-based sketching possesses superior generalization performance with reduced training costs.

Keywords

Cite

@article{arxiv.2409.14174,
  title  = {Component-based Sketching for Deep ReLU Nets},
  author = {Di Wang and Shao-Bo Lin and Deyu Meng and Feilong Cao},
  journal= {arXiv preprint arXiv:2409.14174},
  year   = {2024}
}
R2 v1 2026-06-28T18:52:25.904Z