Aggregation for Gaussian regression

Image data are often composed of two or more geometrically distinct constituents; in galaxy catalogs, for instance, one sees a mixture of pointlike structures (galaxy superclusters) and curvelike structures (filaments). It would be ideal to process a single image and extract two geometrically 'pure' images, each one containing features from only one of the two geometric constituents. This seems to be a seriously underdetermined problem, but recent empirical work achieved highly persuasive separations.We present a theoretical analysis showing that accurate geometric separation of point and curve singularities can be achieved by minimizing the ℓ 1 norm of the representing coefficients in two geometrically complementary frames: wavelets and curvelets. Driving our analysis is a specific property of the ideal (but unachievable) representation where each content type is expanded in the frame best adapted to it. This ideal representation has the property that important coefficients are clustered geometrically in phase space, and that at fine scales, there is very little coherence between a cluster of elements in one frame expansion and individual elements in the complementary frame. We formally introduce notions of cluster coherence and clustered sparsity and use this machinery to show that the underdetermined systems of linear equations can be stably solved by ℓ 1 minimization; microlocal phase space helps organize the calculations that cluster coherence requires.

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“…Now assume that we observe the 'Signal' 4) however, the component distributions P and C are unknown to us.…”

Section: A Geometric Separation Problemmentioning

confidence: 99%

Microlocal Analysis of the Geometric Separation Problem

Donoho

Kutyniok

2012

Comm Pure Appl Math

100

190

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“…A ßow of publications on aggregation can be seen in mathematical statistics (e.g., Birge [8], Bunea et al [14], Goldenshluger [42]). The problems studied in these works are mainly concentrated on comparison and selection of the best estimator from a given set of estimators.…”

Section: Aggregationmentioning

confidence: 99%

From Local Kernel to Nonlocal Multiple-Model Image Denoising

et al. 2009

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We review the evolution of the nonparametric regression modeling in imaging from the local Nadaraya-Watson kernel estimate to the nonlocal means and further to transform-domain Þltering based on nonlocal block-matching. The considered methods are classiÞed mainly according to two main features: local/nonlocal and pointwise/multipoint. Here nonlocal is an alternative to local, and multipoint is an alternative to pointwise. These alternatives, though obvious simpliÞcations, allow to impose a fruitful and transparent classiÞcation of the basic ideas in the advanced techniques. Within this framework, we introduce a novel single-and multiplemodel transform domain nonlocal approach. The Block Matching and 3-D Filtering (BM3D) algorithm, which is currently one of the best performing denoising algorithms, is treated as a special case of the latter approach.

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“…Note that, in fact, (2) can be proved for other procedures: a first example is given in Bunea et al (2005Bunea et al ( , 2006 where (2) is established for a Lasso typef n in the regression model with squared loss.…”

Section: Mannor Et Al (2003) Lugosi and Vayatismentioning

confidence: 99%

Regularization in statistics

Bickel

Tsybakov

et al. 2006

Test

Self Cite

189

126

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This paper is a selective review of the regularization methods scattered in statistics literature. We introduce a general conceptual approach to regularization and fit most existing methods into it. We have tried to focus on the importance of regularization when dealing with today's high-dimensional objects: data and models. A wide range of examples are discussed, including nonparametric regression, boosting, covariance matrix estimation, principal component estimation, subsampling.

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Aggregation for Gaussian regression

Cited by 267 publications

References 59 publications

Microlocal Analysis of the Geometric Separation Problem

Microlocal Analysis of the Geometric Separation Problem

From Local Kernel to Nonlocal Multiple-Model Image Denoising

Regularization in statistics

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