Laurent Demaret scite author profile

We consider total variation minimization for manifold valued data. We propose a cyclic proximal point algorithm and a parallel proximal point algorithm to minimize TV functionals with p -type data terms in the manifold case. These algorithms are based on iterative geodesic averaging which makes them easily applicable to a large class of data manifolds. As an application, we consider denoising images which take their values in a manifold. We apply our algorithms to diffusion tensor images, interferometric SAR images as well as sphere and cylinder valued images. For the class of Cartan-Hadamard manifolds (which includes the data space in diffusion tensor imaging) we show the convergence of the proposed TV minimizing algorithms to a global minimizer. arXiv:1312.7710v1 [math.OC]

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Image compression by linear splines over adaptive triangulations

Demaret

2006

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Jump-Sparse and Sparse Recovery Using Potts Functionals

Storath

Weinmann

Demaret

2014

IEEE Trans. Signal Process.

101

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Abstract-We recover jump-sparse and sparse signals from blurred incomplete data corrupted by (possibly non-Gaussian) noise using inverse Potts energy functionals. We obtain analytical results (existence of minimizers, complexity) on inverse Potts functionals and provide relations to sparsity problems. We then propose a new optimization method for these functionals which is based on dynamic programming and the alternating direction method of multipliers (ADMM). A series of experiments shows that the proposed method yields very satisfactory jumpsparse and sparse reconstructions, respectively. We highlight the capability of the method by comparing it with classical and recent approaches such as TV minimization (jump-sparse signals), orthogonal matching pursuit, iterative hard thresholding, and iteratively reweighted 1 minimization (sparse signals).

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Adaptive image approximation by linear splines over locally optimal delaunay triangulations

Demaret

Iske

2006

IEEE Signal Process. Lett.

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Mumford–Shah and Potts Regularization for Manifold-Valued Data

2016

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Mumford-Shah and Potts functionals are powerful variational models for regularization which are widely used in signal and image processing; typical applications are edge-preserving denoising and segmentation. Being both non-smooth and non-convex, they are computationally challenging even for scalar data. For manifold-valued data, the problem becomes even more involved since typical features of vector spaces are not available. In this paper, we propose algorithms for Mumford-Shah and for Potts regularization of manifold-valued signals and images. For the univariate problems, we derive solvers based on dynamic programming combined with (convex) optimization techniques for manifold-valued data. For the class of Cartan-Hadamard manifolds (which includes the data space in diffusion tensor imaging), we show that our algorithms compute global minimizers for any starting point. For the multivariate Mumford-Shah and Potts problems (for image regularization) we propose a splitting into suitable subproblems which we can solve exactly using the techniques developed for the corresponding univariate problems. Our method does not require any a priori restrictions on the edge set and we do not have to discretize the data space. We apply our method to diffusion tensor imaging (DTI) as well as Q-ball imaging. Using the DTI model, we obtain a segmentation of the corpus callosum. * Andreas Weinmann and Laurent Demaret are both with the Helmholtz Zentrum München, Germany. Martin Storath is with the Biomedical Imaging Group, École Polytechnique Fédérale de Lausanne, Switzerland.

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Laurent Demaret

Total Variation Regularization for Manifold-Valued Data

Image compression by linear splines over adaptive triangulations

Jump-Sparse and Sparse Recovery Using Potts Functionals

Adaptive image approximation by linear splines over locally optimal delaunay triangulations

Mumford–Shah and Potts Regularization for Manifold-Valued Data

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