Online Learning and Information Exponents: On The Importance of Batch size, and Time/Complexity Tradeoffs

Abstract

We study the impact of the batch size nb on the iteration time T of training two-layer neural networks with one-pass stochastic gradient descent (SGD) on multi-index target functions of isotropic covariates. We characterize the optimal batch size minimizing the iteration time as a function of the hardness of the target, as characterized by the information exponents. We show that performing gradient updates with large batches nb d2 minimizes the training time without changing the total sample complexity, where is the information exponent of the target to be learned arous2021online and d is the input dimension. However, larger batch sizes than nb d2 are detrimental for improving the time complexity of SGD. We provably overcome this fundamental limitation via a different training protocol, Correlation loss SGD, which suppresses the auto-correlation terms in the loss function. We show that one can track the training progress by a system of low-dimensional ordinary differential equations (ODEs). Finally, we validate our theoretical results with numerical experiments.