Diffusion models (DMs) have emerged as powerful tools for modeling complex data distributions and generating realistic new samples. Over the years, advanced architectures and sampling methods have been developed to make these models practically usable. However, certain synthesis process decisions still rely on heuristics without a solid theoretical foundation. In our work, we offer a novel analysis of the DM's inference process, introducing a comprehensive frequency response perspective. Specifically, by relying on Gaussianity and shift-invariance assumptions, we present the inference process as a closed-form spectral transfer function, capturing how the generated signal evolves in response to the initial noise. We demonstrate how the proposed analysis can be leveraged for optimizing the noise schedule, ensuring the best alignment with the original dataset's characteristics. Our results lead to scheduling curves that are dependent on the frequency content of the data, offering a theoretical justification for some of the heuristics taken by practitioners.
View on arXiv@article{benita2025_2502.00180,
title={ Designing Scheduling for Diffusion Models via Spectral Analysis },
author={ Roi Benita and Michael Elad and Joseph Keshet },
journal={arXiv preprint arXiv:2502.00180},
year={ 2025 }
}