A Generalized Neural Tangent Kernel Analysis for Two-layer Neural Networks
Abstract
A recent breakthrough in deep learning theory shows that the training of over-parameterized deep neural networks can be characterized by a kernel function called \textit{neural tangent kernel} (NTK). However, it is known that this type of results does not perfectly match the practice, as NTK-based analysis requires the network weights to stay very close to their initialization throughout training, and cannot handle regularizers or gradient noises. In this paper, we provide a generalized neural tangent kernel analysis and show that noisy gradient descent with weight decay can still exhibit a "kernel-like" behavior. This implies that the training loss converges linearly up to a certain accuracy. We also establish a novel generalization error bound for two-layer neural networks trained by noisy gradient descent with weight decay.
Keywords
Cite
@article{arxiv.2002.04026,
title = {A Generalized Neural Tangent Kernel Analysis for Two-layer Neural Networks},
author = {Zixiang Chen and Yuan Cao and Quanquan Gu and Tong Zhang},
journal= {arXiv preprint arXiv:2002.04026},
year = {2020}
}
Comments
33 pages. This version changes the title and improves the presentation