On learning higher-order cumulants in diffusion models
Abstract
To analyse how diffusion models learn correlations beyond Gaussian ones, we study the behaviour of higher-order cumulants, or connected n-point functions, under both the forward and backward process. We derive explicit expressions for the moment- and cumulant-generating functionals, in terms of the distribution of the initial data and properties of forward process. It is shown analytically that during the forward process higher-order cumulants are conserved in models without a drift, such as the variance-expanding scheme, and that therefore the endpoint of the forward process maintains nontrivial correlations. We demonstrate that since these correlations are encoded in the score function, higher-order cumulants are learnt in the backward process, also when starting from a normal prior. We confirm our analytical results in an exactly solvable toy model with nonzero cumulants and in scalar lattice field theory.
Cite
@article{arxiv.2410.21212,
title = {On learning higher-order cumulants in diffusion models},
author = {Gert Aarts and Diaa E. Habibi and Lingxiao Wang and Kai Zhou},
journal= {arXiv preprint arXiv:2410.21212},
year = {2025}
}
Comments
21 pages, many figures. Extended version of contribution awarded "best 'physics for AI' paper award" in the NeurIPS 2024 workshop "Machine Learning and the Physical Sciences"; v2: references and minor clarifications added, version to appear in Machine Learning: Science and Technology