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A Sharp Convergence Theory for The Probability Flow ODEs of Diffusion Models

Machine Learning 2024-08-06 v1 Numerical Analysis Signal Processing Numerical Analysis Statistics Theory Machine Learning Statistics Theory

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 2\ell_2-accurate estimates of the (Stein) score functions. For distributions in Rd\mathbb{R}^d, we prove that d/εd/\varepsilon iterations -- modulo some logarithmic and lower-order terms -- are sufficient to approximate the target distribution to within ε\varepsilon total-variation distance. This is the first result establishing nearly linear dimension-dependency (in dd) 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 2\ell_2 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.

Keywords

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

R2 v1 2026-06-28T18:03:59.614Z