Equivariant Flow Matching with Hybrid Probability Transport for 3D Molecule Generation
Abstract
The generation of 3D molecules requires simultaneously deciding the categorical features (atom types) and continuous features (atom coordinates). Deep generative models, especially Diffusion Models (DMs), have demonstrated effectiveness in generating feature-rich geometries. However, existing DMs typically suffer from unstable probability dynamics with inefficient sampling speed. In this paper, we introduce geometric flow matching, which enjoys the advantages of both equivariant modeling and stabilized probability dynamics. More specifically, we propose a hybrid probability path where the coordinates probability path is regularized by an equivariant optimal transport, and the information between different modalities is aligned. Experimentally, the proposed method could consistently achieve better performance on multiple molecule generation benchmarks with 4.75$\times$ speed up of sampling on average.
Cite
Text
Song et al. "Equivariant Flow Matching with Hybrid Probability Transport for 3D Molecule Generation." Neural Information Processing Systems, 2023.Markdown
[Song et al. "Equivariant Flow Matching with Hybrid Probability Transport for 3D Molecule Generation." Neural Information Processing Systems, 2023.](https://mlanthology.org/neurips/2023/song2023neurips-equivariant/)BibTeX
@inproceedings{song2023neurips-equivariant,
title = {{Equivariant Flow Matching with Hybrid Probability Transport for 3D Molecule Generation}},
author = {Song, Yuxuan and Gong, Jingjing and Xu, Minkai and Cao, Ziyao and Lan, Yanyan and Ermon, Stefano and Zhou, Hao and Ma, Wei-Ying},
booktitle = {Neural Information Processing Systems},
year = {2023},
url = {https://mlanthology.org/neurips/2023/song2023neurips-equivariant/}
}