Geometry of Score Based Generative Models
This work provides a foundational geometric interpretation for diffusion models, potentially accelerating sampling for applications in image generation and other domains.
The paper tackles the problem of slow sampling in score-based generative models by introducing a geometric perspective, proving that both forward and backward processes are Wasserstein gradient flows, and demonstrating that adding a projection step reduces sampling steps while maintaining high-quality image generation.
In this work, we look at Score-based generative models (also called diffusion generative models) from a geometric perspective. From a new view point, we prove that both the forward and backward process of adding noise and generating from noise are Wasserstein gradient flow in the space of probability measures. We are the first to prove this connection. Our understanding of Score-based (and Diffusion) generative models have matured and become more complete by drawing ideas from different fields like Bayesian inference, control theory, stochastic differential equation and Schrodinger bridge. However, many open questions and challenges remain. One problem, for example, is how to decrease the sampling time? We demonstrate that looking from geometric perspective enables us to answer many of these questions and provide new interpretations to some known results. Furthermore, geometric perspective enables us to devise an intuitive geometric solution to the problem of faster sampling. By augmenting traditional score-based generative models with a projection step, we show that we can generate high quality images with significantly fewer sampling-steps.