Stochastic Normalized Gradient Descent with Momentum for Large-Batch Training
Abstract
Stochastic gradient descent~(SGD) and its variants have been the dominating optimization methods in machine learning. Compared to SGD with small-batch training, SGD with large-batch training can better utilize the computational power of current multi-core systems such as graphics processing units~(GPUs) and can reduce the number of communication rounds in distributed training settings. Thus, SGD with large-batch training has attracted considerable attention. However, existing empirical results showed that large-batch training typically leads to a drop in generalization accuracy. Hence, how to guarantee the generalization ability in large-batch training becomes a challenging task. In this paper, we propose a simple yet effective method, called stochastic normalized gradient descent with momentum~(SNGM), for large-batch training. We prove that with the same number of gradient computations, SNGM can adopt a larger batch size than momentum SGD~(MSGD), which is one of the most widely used variants of SGD, to converge to an -stationary point. Empirical results on deep learning verify that when adopting the same large batch size, SNGM can achieve better test accuracy than MSGD and other state-of-the-art large-batch training methods.
Cite
@article{arxiv.2007.13985,
title = {Stochastic Normalized Gradient Descent with Momentum for Large-Batch Training},
author = {Shen-Yi Zhao and Chang-Wei Shi and Yin-Peng Xie and Wu-Jun Li},
journal= {arXiv preprint arXiv:2007.13985},
year = {2024}
}