Riemannian Diffusion Models
Abstract
Diffusion models are recent state-of-the-art methods for image generation and likelihood estimation. In this work, we generalize continuous-time diffusion models to arbitrary Riemannian manifolds and derive a variational framework for likelihood estimation. Computationally, we propose new methods for computing the Riemannian divergence which is needed for likelihood estimation. Moreover, in generalizing the Euclidean case, we prove that maximizing this variational lower-bound is equivalent to Riemannian score matching. Empirically, we demonstrate the expressive power of Riemannian diffusion models on a wide spectrum of smooth manifolds, such as spheres, tori, hyperboloids, and orthogonal groups. Our proposed method achieves new state-of-the-art likelihoods on all benchmarks.
Cite
Text
Huang et al. "Riemannian Diffusion Models." Neural Information Processing Systems, 2022.Markdown
[Huang et al. "Riemannian Diffusion Models." Neural Information Processing Systems, 2022.](https://mlanthology.org/neurips/2022/huang2022neurips-riemannian/)BibTeX
@inproceedings{huang2022neurips-riemannian,
title = {{Riemannian Diffusion Models}},
author = {Huang, Chin-Wei and Aghajohari, Milad and Bose, Joey and Panangaden, Prakash and Courville, Aaron C.},
booktitle = {Neural Information Processing Systems},
year = {2022},
url = {https://mlanthology.org/neurips/2022/huang2022neurips-riemannian/}
}