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Main Authors: Lyu, Yang, Nguyen, Tan Minh, Qian, Yuchun, Tong, Xin T.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.02508
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author Lyu, Yang
Nguyen, Tan Minh
Qian, Yuchun
Tong, Xin T.
author_facet Lyu, Yang
Nguyen, Tan Minh
Qian, Yuchun
Tong, Xin T.
contents Diffusion models are popular tools for generating new data samples, using a forward process that adds noise to data and a reverse process to denoise and produce samples. However, when the data distribution consists of n points, empirical diffusion models tend to reproduce existing data points, a phenomenon known as the memorization effect. Current literature often addresses this with complex machine learning techniques. This work shows that the memorization issue can be solved simply by applying an inertia update at the end of the empirical diffusion simulation. Our inertial diffusion model requires only the empirical score function and no additional training. We demonstrate that the distribution of samples from this model approximates the true data distribution on a $C^2$ manifold of dimension $d$, within a Wasserstein-1 distance of order $O(n^{-\frac{2}{d+4}})$. This bound significantly shrinks the Wasserstein distance between the population and empirical distributions, confirming that the inertial diffusion model produces new and diverse samples. Remarkably, this estimate is independent of the ambient space dimension, as no further training is needed. Our analysis shows that the inertial diffusion samples resemble Gaussian kernel density estimations on the manifold, revealing a novel connection between diffusion models and manifold learning.
format Preprint
id arxiv_https___arxiv_org_abs_2505_02508
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Resolving Memorization in Empirical Diffusion Model for Manifold Data in High-Dimensional Spaces
Lyu, Yang
Nguyen, Tan Minh
Qian, Yuchun
Tong, Xin T.
Machine Learning
Statistics Theory
Diffusion models are popular tools for generating new data samples, using a forward process that adds noise to data and a reverse process to denoise and produce samples. However, when the data distribution consists of n points, empirical diffusion models tend to reproduce existing data points, a phenomenon known as the memorization effect. Current literature often addresses this with complex machine learning techniques. This work shows that the memorization issue can be solved simply by applying an inertia update at the end of the empirical diffusion simulation. Our inertial diffusion model requires only the empirical score function and no additional training. We demonstrate that the distribution of samples from this model approximates the true data distribution on a $C^2$ manifold of dimension $d$, within a Wasserstein-1 distance of order $O(n^{-\frac{2}{d+4}})$. This bound significantly shrinks the Wasserstein distance between the population and empirical distributions, confirming that the inertial diffusion model produces new and diverse samples. Remarkably, this estimate is independent of the ambient space dimension, as no further training is needed. Our analysis shows that the inertial diffusion samples resemble Gaussian kernel density estimations on the manifold, revealing a novel connection between diffusion models and manifold learning.
title Resolving Memorization in Empirical Diffusion Model for Manifold Data in High-Dimensional Spaces
topic Machine Learning
Statistics Theory
url https://arxiv.org/abs/2505.02508