Generalization Bounds of Stochastic Gradient Descent in Homogeneous Neural Networks

Abstract

Algorithmic stability is among the most potent techniques in generalization analysis. However, its derivation usually requires a stepsize ηt = O(1/t) under non-convex training regimes, where t denotes iterations. This rigid decay of the stepsize potentially impedes optimization and may not align with practical scenarios. In this paper, we derive the generalization bounds under the homogeneous neural network regimes, proving that this regime enables slower stepsize decay of order (1/t) under mild assumptions. We further extend the theoretical results from several aspects, e.g., non-Lipschitz regimes. This finding is broadly applicable, as homogeneous neural networks encompass fully-connected and convolutional neural networks with ReLU and LeakyReLU activations.