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Iteratively Reweighted FGMRES and FLSQR for Sparse Reconstruction

Silvia Gazzola, James G. Nagy, Malena Sabaté Landman

2021SIAM Journal on Scientific Computing21 citationsDOIOpen Access PDF

Abstract

This paper presents two new algorithms to compute sparse solutions of large-scale linear discrete ill-posed problems. The proposed approach consists in constructing a sequence of quadratic problems approximating an ` <sub>2</sub>-` <sub>1</sub> regularization scheme (with additional smoothing to ensure differentiability at the origin) and partially solving each problem in the sequence using flexible Krylov–Tikhonov methods. These algorithms are built upon a new solid theoretical justification that guarantees that the sequence of approximate solutions to each problem in the sequence converges to the solution of the considered modified version of the ` <sub>2</sub>-` <sub>1</sub> problem. Compared to other traditional methods, the new algorithms have the advantage of building a single (flexible) approximation (Krylov) subspace that encodes regularization through variable “preconditioning” and that is expanded as soon as a new problem in the sequence is defined. Links between the new solvers and other well-established solvers based on augmenting Krylov subspaces are also established. The performance of these algorithms is shown through a variety of numerical examples modeling image deblurring and computed tomography.

Topics & Concepts

DeblurringMathematicsKrylov subspaceRegularization (linguistics)Tikhonov regularizationSequence (biology)AlgorithmMathematical optimizationLinear subspaceApplied mathematicsImage restorationInverse problemIterative methodComputer scienceImage (mathematics)Image processingArtificial intelligenceMathematical analysisPure mathematicsGeneticsBiologyNumerical methods in inverse problemsSparse and Compressive Sensing TechniquesMedical Imaging Techniques and Applications
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