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DeblurSDI: Blind Image Deblurring Using Self-diffusion

computer-vision › diffusion-models

📄 Abstract

Abstract: Blind image deconvolution is a challenging ill-posed inverse problem, where both the latent sharp image and the blur kernel are unknown. Traditional methods often rely on handcrafted priors, while modern deep learning approaches typically require extensive pre-training on large external datasets, limiting their adaptability to real-world scenarios. In this work, we propose DeblurSDI, a zero-shot, self-supervised framework based on self-diffusion (SDI) that requires no prior training. DeblurSDI formulates blind deconvolution as an iterative reverse self-diffusion process that starts from pure noise and progressively refines the solution. At each step, two randomly-initialized neural networks are optimized continuously to refine the sharp image and the blur kernel. The optimization is guided by an objective function combining data consistency with a sparsity-promoting L1-norm for the kernel. A key innovation is our noise scheduling mechanism, which stabilizes the optimization and provides remarkable robustness to variations in blur kernel size. These allow DeblurSDI to dynamically learn an instance-specific prior tailored to the input image. Extensive experiments demonstrate that DeblurSDI consistently achieves superior performance, recovering sharp images and accurate kernels even in highly degraded scenarios.

Authors (2)

Yanlong Yang

Guanxiong Luo

Submitted

October 31, 2025

arXiv Category

cs.CV

arXiv PDF

Key Contributions

DeblurSDI presents a novel zero-shot, self-supervised framework for blind image deconvolution using self-diffusion. It overcomes the limitations of traditional methods and deep learning approaches by requiring no prior training and iteratively refining both the sharp image and blur kernel through a guided diffusion process.

Business Value

Enables restoration of blurry images without prior knowledge or training, improving image quality in various applications like forensics, medical imaging, and consumer photography, potentially reducing the need for re-capture.

Paper Metadata

Innovation Type

Methodological/Algorithmic

Deployment Feasibility

High feasibility, as it's a self-contained algorithm that doesn't require extensive pre-training. Can be integrated into image processing pipelines.

Limitations Addressed

Addresses the limitations of traditional deconvolution methods relying on handcrafted priors and deep learning methods requiring extensive pre-training. It offers a zero-shot, self-supervised solution adaptable to real-world scenarios.

Technical Tags

blind image deconvolutionself-diffusionzero-shot learningself-supervised learningiterative refinementneural networkssparsity priornoise schedulingDeblurSDI

Research Topics

Image RestorationBlind DeconvolutionGenerative ModelsSelf-Supervised LearningDiffusion Models

Methods & Architectures

self-diffusion (SDI)iterative reverse diffusion processtwo randomly-initialized neural networkscontinuous optimizationnoise scheduling mechanism Diffusion ModelsNeural Networks

Applications & Tasks

Photography Medical Imaging Surveillance Astronomy Ill-posed Inverse ProblemsUnknown Blur KernelsLimited Adaptability of Deep Learning ModelsNeed for Extensive Pre-training Blind Image DeblurringBlur Kernel EstimationImage Restoration

Related Fields

Computer VisionImage ProcessingDeep LearningGenerative ModelsInverse Problems

Keywords

blind deconvolutionimage deblurringdiffusion modelsself-supervised learningzero-shotimage restorationneural networksiterativenoisesparsityDeblurSDI

Academic Context

#Image Restoration#Blind Deconvolution#Generative Models#Self-Supervised Learning#Diffusion Models

Commercial Potential

Potential Products

Image enhancement softwareDeblurring plugins for photo editorsForensic image analysis tools

Target Industries

PhotographyMediaSecurity & SurveillanceMedical DevicesRobotics

Use Case Examples

Restoring blurry security camera footageImproving the clarity of medical scansEnhancing photos taken in low-light or shaky conditions

Competitive Edge

Offers a significant advantage over traditional methods and supervised deep learning by being zero-shot and self-supervised, adaptable to diverse blur types without specific training data.

Market Opportunity

Large market for image enhancement and restoration technologies.

Revenue Models

Software licensingAPI services.

Resource Requirements

Compute Needs

Moderate to high, requires GPUs for iterative optimization.

Data Requirements

No specific training dataset required due to its self-supervised, zero-shot nature.

Deployment Constraints

The iterative nature might lead to longer processing times compared to single-pass methods.

Scalability

Scalable to various image sizes. Computational cost is tied to the number of diffusion steps and network complexity.

Production Readiness

Maturity Level

Research/Prototype

Time to Market

1-2 years

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