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Main Authors: Li, Xiang, Shen, Zebang, Hsieh, Ya-Ping, He, Niao
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.24912
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author Li, Xiang
Shen, Zebang
Hsieh, Ya-Ping
He, Niao
author_facet Li, Xiang
Shen, Zebang
Hsieh, Ya-Ping
He, Niao
contents Score-based methods, such as diffusion models and Bayesian inverse problems, are often interpreted as learning the data distribution in the low-noise limit ($σ\to 0$). In this work, we propose an alternative perspective: their success arises from implicitly learning the data manifold rather than the full distribution. Our claim is based on a novel analysis of scores in the small-$σ$ regime that reveals a sharp separation of scales: information about the data manifold is $Θ(σ^{-2})$ stronger than information about the distribution. We argue that this insight suggests a paradigm shift from the less practical goal of distributional learning to the more attainable task of geometric learning, which provably tolerates $O(σ^{-2})$ larger errors in score approximation. We illustrate this perspective through three consequences: i) in diffusion models, concentration on data support can be achieved with a score error of $o(σ^{-2})$, whereas recovering the specific data distribution requires a much stricter $o(1)$ error; ii) more surprisingly, learning the uniform distribution on the manifold-an especially structured and useful object-is also $O(σ^{-2})$ easier; and iii) in Bayesian inverse problems, the maximum entropy prior is $O(σ^{-2})$ more robust to score errors than generic priors. Finally, we validate our theoretical findings with preliminary experiments on large-scale models, including Stable Diffusion.
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publishDate 2025
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spellingShingle When Scores Learn Geometry: Rate Separations under the Manifold Hypothesis
Li, Xiang
Shen, Zebang
Hsieh, Ya-Ping
He, Niao
Machine Learning
Score-based methods, such as diffusion models and Bayesian inverse problems, are often interpreted as learning the data distribution in the low-noise limit ($σ\to 0$). In this work, we propose an alternative perspective: their success arises from implicitly learning the data manifold rather than the full distribution. Our claim is based on a novel analysis of scores in the small-$σ$ regime that reveals a sharp separation of scales: information about the data manifold is $Θ(σ^{-2})$ stronger than information about the distribution. We argue that this insight suggests a paradigm shift from the less practical goal of distributional learning to the more attainable task of geometric learning, which provably tolerates $O(σ^{-2})$ larger errors in score approximation. We illustrate this perspective through three consequences: i) in diffusion models, concentration on data support can be achieved with a score error of $o(σ^{-2})$, whereas recovering the specific data distribution requires a much stricter $o(1)$ error; ii) more surprisingly, learning the uniform distribution on the manifold-an especially structured and useful object-is also $O(σ^{-2})$ easier; and iii) in Bayesian inverse problems, the maximum entropy prior is $O(σ^{-2})$ more robust to score errors than generic priors. Finally, we validate our theoretical findings with preliminary experiments on large-scale models, including Stable Diffusion.
title When Scores Learn Geometry: Rate Separations under the Manifold Hypothesis
topic Machine Learning
url https://arxiv.org/abs/2509.24912