Your search keyword '"Sebastiani, Andrea"' showing total 3 results

1. Bilevel learning of regularization models and their discretization for image deblurring and super-resolution

Author

Bubba, Tatiana A., Calatroni, Luca, Catozzi, Ambra, Crisci, Serena, Pock, Thomas, Pragliola, Monica, Rautio, Siiri, Riccio, Danilo, and Sebastiani, Andrea

Subjects

Mathematics - Numerical Analysis, Mathematics - Optimization and Control, 65K10, G.1.6, I.4.3, I.4.4, I.4.5, I.2.6, I.2.0

Abstract

Bilevel learning is a powerful optimization technique that has extensively been employed in recent years to bridge the world of model-driven variational approaches with data-driven methods. Upon suitable parametrization of the desired quantities of interest (e.g., regularization terms or discretization filters), such approach computes optimal parameter values by solving a nested optimization problem where the variational model acts as a constraint. In this work, we consider two different use cases of bilevel learning for the problem of image restoration. First, we focus on learning scalar weights and convolutional filters defining a Field of Experts regularizer to restore natural images degraded by blur and noise. For improving the practical performance, the lower-level problem is solved by means of a gradient descent scheme combined with a line-search strategy based on the Barzilai-Borwein rule. As a second application, the bilevel setup is employed for learning a discretization of the popular total variation regularizer for solving image restoration problems (in particular, deblurring and super-resolution). Numerical results show the effectiveness of the approach and their generalization to multiple tasks., Comment: Acknowledgments corrected

Published

2023

2. Plug-and-Play gradient-based denoisers applied to CT image enhancement

Author

Cascarano, Pasquale, Piccolomini, Elena Loli, Morotti, Elena, and Sebastiani, Andrea

Subjects

Mathematics - Numerical Analysis, Computer Science - Computer Vision and Pattern Recognition, 65K10, 65R30, 68U10, 68T07, 65F22, G.1.6, G.1.10, I.4.3, I.4.4, I.4.5, I.4.6, I.2.6, I.2.0

Abstract

Blur and noise corrupting Computed Tomography (CT) images can hide or distort small but important details, negatively affecting the diagnosis. In this paper, we present a novel gradient-based Plug-and-Play algorithm, constructed on the Half-Quadratic Splitting scheme, and we apply it to restore CT images. In particular, we consider different schemes encompassing external and internal denoisers as priors, defined on the image gradient domain. The internal prior is based on the Total Variation functional. The external denoiser is implemented by a deep Convolutional Neural Network (CNN) trained on the gradient domain (and not on the image one, as in state-of-the-art works). We also prove a general fixed-point convergence theorem under weak assumptions on both internal and external denoisers. The experiments confirm the effectiveness of the proposed framework in restoring blurred noisy CT images, both in simulated and real medical settings. The achieved enhancements in the restored images are really remarkable, if compared to the results of many state-of-the-art methods., Comment: Submitted to journal

Published

2021

3. Combining Weighted Total Variation and Deep Image Prior for natural and medical image restoration via ADMM

Author

Cascarano, Pasquale, Sebastiani, Andrea, Comes, Maria Colomba, Franchini, Giorgia, and Porta, Federica

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Mathematics - Numerical Analysis, 65F22, 65K10, G.1.6, G.1.10, I.4.3, I.4.4, I.4.5, I.4.6, I.2.6, I.2.0

Abstract

In the last decades, unsupervised deep learning based methods have caught researchers attention, since in many real applications, such as medical imaging, collecting a great amount of training examples is not always feasible. Moreover, the construction of a good training set is time consuming and hard because the selected data have to be enough representative for the task. In this paper, we focus on the Deep Image Prior (DIP) framework and we propose to combine it with a space-variant Total Variation regularizer with an automatic estimation of the local regularization parameters. Differently from other existing approaches, we solve the arising minimization problem via the flexible Alternating Direction Method of Multipliers (ADMM). Furthermore, we provide a specific implementation also for the standard isotropic Total Variation. The promising performances of the proposed approach, in terms of PSNR and SSIM values, are addressed through several experiments on simulated as well as real natural and medical corrupted images., Comment: conference paper

Published

2020