English

Learning Spatially Adaptive $\ell_1$-Norms Weights for Convolutional Synthesis Regularization

Machine Learning 2025-10-23 v4 Computer Vision and Pattern Recognition Optimization and Control

Abstract

We propose an unrolled algorithm approach for learning spatially adaptive parameter maps in the framework of convolutional synthesis-based 1\ell_1 regularization. More precisely, we consider a family of pre-trained convolutional filters and estimate deeply parametrized spatially varying parameters applied to the sparse feature maps by means of unrolling a FISTA algorithm to solve the underlying sparse estimation problem. The proposed approach is evaluated for image reconstruction of low-field MRI and compared to spatially adaptive and non-adaptive analysis-type procedures relying on Total Variation regularization and to a well-established model-based deep learning approach. We show that the proposed approach produces visually and quantitatively comparable results with the latter approaches and at the same time remains highly interpretable. In particular, the inferred parameter maps quantify the local contribution of each filter in the reconstruction, which provides valuable insight into the algorithm mechanism and could potentially be used to discard unsuited filters.

Keywords

Cite

@article{arxiv.2503.09483,
  title  = {Learning Spatially Adaptive $\ell_1$-Norms Weights for Convolutional Synthesis Regularization},
  author = {Andreas Kofler and Luca Calatroni and Christoph Kolbitsch and Kostas Papafitsoros},
  journal= {arXiv preprint arXiv:2503.09483},
  year   = {2025}
}

Comments

Accepted for publication in the proceedings of the EUSIPCO 2025 conference; corrected typo in equation (3)

R2 v1 2026-06-28T22:17:44.298Z