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Shallow diffusion networks provably learn hidden low-dimensional structure

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arxiv 2410.11275 v1 pith:JLDIDQLY submitted 2024-10-15 cs.LG stat.ML

Shallow diffusion networks provably learn hidden low-dimensional structure

classification cs.LG stat.ML
keywords modelsdiffusiondistributionlearningresultssamplestructureadapt
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Diffusion-based generative models provide a powerful framework for learning to sample from a complex target distribution. The remarkable empirical success of these models applied to high-dimensional signals, including images and video, stands in stark contrast to classical results highlighting the curse of dimensionality for distribution recovery. In this work, we take a step towards understanding this gap through a careful analysis of learning diffusion models over the Barron space of single layer neural networks. In particular, we show that these shallow models provably adapt to simple forms of low dimensional structure, thereby avoiding the curse of dimensionality. We combine our results with recent analyses of sampling with diffusion models to provide an end-to-end sample complexity bound for learning to sample from structured distributions. Importantly, our results do not require specialized architectures tailored to particular latent structures, and instead rely on the low-index structure of the Barron space to adapt to the underlying distribution.

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Cited by 2 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. An exact information theory of generalization phase transitions in Bayesian diffusion models

    cs.LG 2026-07 conditional novelty 8.0

    Bayesian diffusion models memorize training data when mutual information between restricted observations and training data exceeds log dataset size, and generalize otherwise.

  2. Provably Learning Diffusion Models under the Manifold Hypothesis: Collapse and Refine

    cs.LG 2026-05 unverdicted novelty 6.0

    SiLD is a score-matching framework that learns both manifold projection and intrinsic density from a single objective, with proven sample complexity depending only on intrinsic dimension.