Quotient-Space Diffusion Models
Yixian Xu, Yusong Wang, Shengjie Luo, Kaiyuan Gao, Tianyu He, Di He, Chang Liu
We propose a principled way to leverage group symmetry of the target distribution by defining a diffusion model on the quotient space, which achieves both easier learning and correct sampling for the first time.
Abstract
Diffusion-based generative models have reformed generative AI, and have enabled new capabilities in the science domain, for example, generating 3D structures of molecules. Due to the intrinsic problem structure of certain tasks, there is often a symmetry in the system, which identifies objects that can be converted by a group action as equivalent, hence the target distribution is essentially defined on the quotient space with respect to the group. In this work, we establish a formal framework for diffusion modeling on a general quotient space, and apply it to molecular structure generation which follows the special Euclidean group SE(3) symmetry. The framework reduces the necessity of learning the component corresponding to the group action, hence simplifies learning difficulty over conventional group-equivariant diffusion models, and the sampler guarantees recovering the target distribution, while heuristic alignment strategies lack proper samplers. The arguments are empirically validated on structure generation for small molecules and proteins, indicating that the principled quotient-space diffusion model provides a new framework that outperforms previous symmetry treatments.
Quotient-space diffusion models reduce learning difficulty for molecular structure generation via SE(3) symmetry handling.
- Establishes formal framework for diffusion modeling on quotient spaces with respect to group actions
- Reduces necessity of learning group action component, simplifying learning difficulty
- Guarantees sampler recovers target distribution while removing unnecessary group-direction movement
- Demonstrates better generation quality and design success rate on small molecules and proteins
- Diffusion models
- Quotient space mathematics
- SE(3) symmetry
- Group-equivariant methods
- GEOM-QM9
- GEOM-DRUGS
Authors did not state explicit limitations.
Authors did not state explicit future directions.
Author keywords
- Diffusion Models
- Generative Modeling
- Geometric Deep Learning
- Molecular Structure Generation
Related orals
Universal Inverse Distillation for Matching Models with Real-Data Supervision (No GANs)
RealUID provides universal distillation for matching models without GANs, incorporating real data into one-step generator training.
GLASS Flows: Efficient Inference for Reward Alignment of Flow and Diffusion Models
GLASS Flows samples Markov transitions via inner flow matching models to improve inference-time reward alignment in flow and diffusion models.
Neon: Negative Extrapolation From Self-Training Improves Image Generation
Neon inverts model degradation from self-training by extrapolating away from it, improving generative models with minimal compute.
Generative Human Geometry Distribution
Introduces distribution-over-distribution model combining geometry distributions with two-stage flow matching for human 3D generation.
Cross-Domain Lossy Compression via Rate- and Classification-Constrained Optimal Transport
Cross-domain lossy compression unifies rate and classification constraints via optimal transport framework.