Analysis Plug-and-Play Methods for Imaging Inverse Problems

Computer Vision & MultiModal AI
Published: arXiv: 2509.15422v1
Authors

Edward P. Chandler Shirin Shoushtari Brendt Wohlberg Ulugbek S. Kamilov

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Abstract

Plug-and-Play Priors (PnP) is a popular framework for solving imaging inverse problems by integrating learned priors in the form of denoisers trained to remove Gaussian noise from images. In standard PnP methods, the denoiser is applied directly in the image domain, serving as an implicit prior on natural images. This paper considers an alternative analysis formulation of PnP, in which the prior is imposed on a transformed representation of the image, such as its gradient. Specifically, we train a Gaussian denoiser to operate in the gradient domain, rather than on the image itself. Conceptually, this is an extension of total variation (TV) regularization to learned TV regularization. To incorporate this gradient-domain prior in image reconstruction algorithms, we develop two analysis PnP algorithms based on half-quadratic splitting (APnP-HQS) and the alternating direction method of multipliers (APnP-ADMM). We evaluate our approach on image deblurring and super-resolution, demonstrating that the analysis formulation achieves performance comparable to image-domain PnP algorithms.

Paper Summary

Problem
Imaging inverse problems are a type of problem where we try to estimate an image from a set of noisy measurements. This is a common challenge in fields like medical imaging, astronomy, and surveillance. The problem is that traditional methods for solving these problems can introduce reconstruction artifacts, such as staircasing, which can make the reconstructed image look unnatural.
Key Innovation
The researchers in this paper propose a new approach to solving imaging inverse problems using a technique called Plug-and-Play Priors (PnP). Specifically, they train a denoiser to operate in the gradient domain, rather than on the image itself. This is an extension of traditional total variation (TV) regularization to learned TV regularization. They develop two analysis PnP algorithms, called APnP-HQS and APnP-ADMM, which incorporate this gradient-domain prior in image reconstruction algorithms.
Practical Impact
This research has the potential to improve image reconstruction in a variety of fields, including medical imaging, astronomy, and surveillance. By using a learned prior on the gradient domain, the researchers demonstrate that their approach can achieve performance comparable to traditional PnP algorithms. This could lead to more accurate and detailed images, which could have significant practical impacts in fields like healthcare and environmental monitoring.
Analogy / Intuitive Explanation
Think of the image as a puzzle with many pieces. Traditional methods for solving imaging inverse problems try to fit the pieces together based on a simple set of rules, which can lead to unnatural-looking reconstructions. The researchers in this paper propose a new way of fitting the pieces together by using a learned prior on the gradient domain. This is like having a more sophisticated set of rules that can capture the complex patterns and structures in the image, leading to more accurate and detailed reconstructions.
Paper Information
Categories:
eess.IV cs.CV
Published Date:

arXiv ID:

2509.15422v1

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