English

A Recovery Theory for Diffusion Priors: Deterministic Analysis of the Implicit Prior Algorithm

Machine Learning 2025-09-26 v1 Signal Processing Optimization and Control

Abstract

Recovering high-dimensional signals from corrupted measurements is a central challenge in inverse problems. Recent advances in generative diffusion models have shown remarkable empirical success in providing strong data-driven priors, but rigorous recovery guarantees remain limited. In this work, we develop a theoretical framework for analyzing deterministic diffusion-based algorithms for inverse problems, focusing on a deterministic version of the algorithm proposed by Kadkhodaie \& Simoncelli \cite{kadkhodaie2021stochastic}. First, we show that when the underlying data distribution concentrates on a low-dimensional model set, the associated noise-convolved scores can be interpreted as time-varying projections onto such a set. This leads to interpreting previous algorithms using diffusion priors for inverse problems as generalized projected gradient descent methods with varying projections. When the sensing matrix satisfies a restricted isometry property over the model set, we can derive quantitative convergence rates that depend explicitly on the noise schedule. We apply our framework to two instructive data distributions: uniform distributions over low-dimensional compact, convex sets and low-rank Gaussian mixture models. In the latter setting, we can establish global convergence guarantees despite the nonconvexity of the underlying model set.

Keywords

Cite

@article{arxiv.2509.20511,
  title  = {A Recovery Theory for Diffusion Priors: Deterministic Analysis of the Implicit Prior Algorithm},
  author = {Oscar Leong and Yann Traonmilin},
  journal= {arXiv preprint arXiv:2509.20511},
  year   = {2025}
}
R2 v1 2026-07-01T05:54:53.268Z