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Main Authors: Yan, Baohua, Kava, Jennifer, Liu, Qingyuan, Di, Xuan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.17873
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author Yan, Baohua
Kava, Jennifer
Liu, Qingyuan
Di, Xuan
author_facet Yan, Baohua
Kava, Jennifer
Liu, Qingyuan
Di, Xuan
contents Standard diffusion models (DMs) rely on the total destruction of data into non-informative white noise, forcing the backward process to denoise from a fully unstructured noise state. While ensuring diversity, this results in a cumbersome and computationally intensive image generation task. We address this challenge by proposing new forward and backward process within a mathematically tractable spectral space. Unlike pixel-based DMs, our forward process converges towards an informative Gaussian prior N(mu_hat,Sigma_hat) rather than white noise. Our method, termed Preserving Spectral Structure and Statistics (PreSS) in diffusion models, guides spectral components toward this informative prior while ensuring that corresponding structural signals remain intact at terminal time. This provides a principled starting point for the backward process, enabling high-quality image reconstruction that builds upon preserved spectral structure while maintaining high generative diversity. Experimental results on CIFAR-10, CelebA and CelebA-HQ demonstrate significant reductions in computational complexity, improved visual diversity, less drift, and a smoother diffusion process compared to pixel-based DMs.
format Preprint
id arxiv_https___arxiv_org_abs_2512_17873
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Preserving Spectral Structure and Statistics in Diffusion Models
Yan, Baohua
Kava, Jennifer
Liu, Qingyuan
Di, Xuan
Computer Vision and Pattern Recognition
Standard diffusion models (DMs) rely on the total destruction of data into non-informative white noise, forcing the backward process to denoise from a fully unstructured noise state. While ensuring diversity, this results in a cumbersome and computationally intensive image generation task. We address this challenge by proposing new forward and backward process within a mathematically tractable spectral space. Unlike pixel-based DMs, our forward process converges towards an informative Gaussian prior N(mu_hat,Sigma_hat) rather than white noise. Our method, termed Preserving Spectral Structure and Statistics (PreSS) in diffusion models, guides spectral components toward this informative prior while ensuring that corresponding structural signals remain intact at terminal time. This provides a principled starting point for the backward process, enabling high-quality image reconstruction that builds upon preserved spectral structure while maintaining high generative diversity. Experimental results on CIFAR-10, CelebA and CelebA-HQ demonstrate significant reductions in computational complexity, improved visual diversity, less drift, and a smoother diffusion process compared to pixel-based DMs.
title Preserving Spectral Structure and Statistics in Diffusion Models
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2512.17873