A Neural Scaling Law from the Dimension of the Data Manifold
http://arxiv.org/abs/2004.10802v1
Abstract
When data is plentiful, the loss achieved by well-trained neural networks scales as a power-law in the number of network parameters . This empirical scaling law holds for a wide variety of data modalities, and may persist over many orders of magnitude. The scaling law can be explained if neural models are effectively just performing regression on a data manifold of intrinsic dimension . This simple theory predicts that the scaling exponents for cross-entropy and mean-squared error losses. We confirm the theory by independently measuring the intrinsic dimension and the scaling exponents in a teacher/student framework, where we can study a variety of and by dialing the properties of random teacher networks. We also test the theory with CNN image classifiers on several datasets and with GPT-type language models.