Adapting to unknown noise level in sparse deconvolution

Claire Boyer; Yohann De Castro; Joseph Salmon

doi:10.1093/imaiai/iaw024

Adapting to unknown noise level in sparse deconvolution

Claire Boyer
, Yohann De Castro
, Joseph Salmon

Sorbonne Université
Laboratoire de Mathématiques d'Orsay
Université Paris-Saclay

Research output: Contribution to journal › Article › peer-review

Abstract

In this article, we study sparse spike deconvolution over the space of complex-valued measures when the input measure is a finite sum of Dirac masses. We introduce a modified version of the Beurling Lasso, a semi-definite program that we refer to as the Concomitant Beurling Lasso. This new procedure estimates the target measure and the unknown noise level simultaneously. Contrary to previous estimators in the literature, theory holds for a tuning parameter that depends only on the sample size, so that it can be used for unknown noise level problems. Consistent noise level estimation is standardly proved. As for Radon measure estimation, theoretical guarantees match the previous state-of-the-art results in Super-Resolution regarding minimax prediction and localization. The proofs are based on a bound on the noise level given by a new tail estimate of the supremum of a stationary non-Gaussian process through the Rice method.

Original language	English
Pages (from-to)	310-348
Number of pages	39
Journal	Information and Inference
Volume	6
Issue number	3
DOIs	https://doi.org/10.1093/imaiai/iaw024
Publication status	Published - 1 Jan 2017
Externally published	Yes

Keywords

Concomitant Beurling Lasso
Convex regularization
Deconvolution
Inverse problems
Model selection
Rice method
Scaled-Lasso
Sparsity
Square-root Lasso

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10.1093/imaiai/iaw024

Cite this

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title = "Adapting to unknown noise level in sparse deconvolution",

abstract = "In this article, we study sparse spike deconvolution over the space of complex-valued measures when the input measure is a finite sum of Dirac masses. We introduce a modified version of the Beurling Lasso, a semi-definite program that we refer to as the Concomitant Beurling Lasso. This new procedure estimates the target measure and the unknown noise level simultaneously. Contrary to previous estimators in the literature, theory holds for a tuning parameter that depends only on the sample size, so that it can be used for unknown noise level problems. Consistent noise level estimation is standardly proved. As for Radon measure estimation, theoretical guarantees match the previous state-of-the-art results in Super-Resolution regarding minimax prediction and localization. The proofs are based on a bound on the noise level given by a new tail estimate of the supremum of a stationary non-Gaussian process through the Rice method.",

keywords = "Concomitant Beurling Lasso, Convex regularization, Deconvolution, Inverse problems, Model selection, Rice method, Scaled-Lasso, Sparsity, Square-root Lasso",

author = "Claire Boyer and \{De Castro\}, Yohann and Joseph Salmon",

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doi = "10.1093/imaiai/iaw024",

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T1 - Adapting to unknown noise level in sparse deconvolution

AU - Boyer, Claire

AU - De Castro, Yohann

AU - Salmon, Joseph

N1 - Publisher Copyright: © The authors 2017.

PY - 2017/1/1

Y1 - 2017/1/1

N2 - In this article, we study sparse spike deconvolution over the space of complex-valued measures when the input measure is a finite sum of Dirac masses. We introduce a modified version of the Beurling Lasso, a semi-definite program that we refer to as the Concomitant Beurling Lasso. This new procedure estimates the target measure and the unknown noise level simultaneously. Contrary to previous estimators in the literature, theory holds for a tuning parameter that depends only on the sample size, so that it can be used for unknown noise level problems. Consistent noise level estimation is standardly proved. As for Radon measure estimation, theoretical guarantees match the previous state-of-the-art results in Super-Resolution regarding minimax prediction and localization. The proofs are based on a bound on the noise level given by a new tail estimate of the supremum of a stationary non-Gaussian process through the Rice method.

AB - In this article, we study sparse spike deconvolution over the space of complex-valued measures when the input measure is a finite sum of Dirac masses. We introduce a modified version of the Beurling Lasso, a semi-definite program that we refer to as the Concomitant Beurling Lasso. This new procedure estimates the target measure and the unknown noise level simultaneously. Contrary to previous estimators in the literature, theory holds for a tuning parameter that depends only on the sample size, so that it can be used for unknown noise level problems. Consistent noise level estimation is standardly proved. As for Radon measure estimation, theoretical guarantees match the previous state-of-the-art results in Super-Resolution regarding minimax prediction and localization. The proofs are based on a bound on the noise level given by a new tail estimate of the supremum of a stationary non-Gaussian process through the Rice method.

KW - Concomitant Beurling Lasso

KW - Convex regularization

KW - Deconvolution

KW - Inverse problems

KW - Model selection

KW - Rice method

KW - Scaled-Lasso

KW - Sparsity

KW - Square-root Lasso

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DO - 10.1093/imaiai/iaw024

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SN - 2049-8772

VL - 6

SP - 310

EP - 348

JO - Information and Inference

JF - Information and Inference

IS - 3

ER -

Adapting to unknown noise level in sparse deconvolution

Abstract

Keywords

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