A Sharp Convergence Theory for The Probability Flow ODEs of Diffusion Models
Abstract
Diffusion models, which convert noise into new data instances by learning to reverse a diffusion process, have become a cornerstone in contemporary generative modeling. In this work, we develop non-asymptotic convergence theory for a popular diffusion-based sampler (i.e., the probability flow ODE sampler) in discrete time, assuming access to -accurate estimates of the (Stein) score functions. For distributions in , we prove that iterations -- modulo some logarithmic and lower-order terms -- are sufficient to approximate the target distribution to within total-variation distance. This is the first result establishing nearly linear dimension-dependency (in ) for the probability flow ODE sampler. Imposing only minimal assumptions on the target data distribution (e.g., no smoothness assumption is imposed), our results also characterize how score estimation errors affect the quality of the data generation processes. In contrast to prior works, our theory is developed based on an elementary yet versatile non-asymptotic approach without the need of resorting to SDE and ODE toolboxes.
Cite
@article{arxiv.2408.02320,
title = {A Sharp Convergence Theory for The Probability Flow ODEs of Diffusion Models},
author = {Gen Li and Yuting Wei and Yuejie Chi and Yuxin Chen},
journal= {arXiv preprint arXiv:2408.02320},
year = {2024}
}
Comments
This manuscript presents improved theory for probability flow ODEs compared to its earlier version arXiv:2306.09251