A Weighted Approach for Sparse Signal Support Estimation with Application to EEG Source Localization

In sparse signal recovery problems, 11-norm minimization is typically used as an alternative to more complex 10-norm minimization. The range space property (RSP) provides the conditions under which the least 11 -norm solution is equal to at most one of the least 10-norm solutions. These conditions d...

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Bibliographic Details
Published inIEEE transactions on signal processing Vol. 65; no. 24; pp. 6551 - 6565
Main Authors Al Hilli, Ahmed, Najafizadeh, Laleh, Petropulu, Athina P.
Format Journal Article
LanguageEnglish
Published IEEE 15.12.2017
Subjects
Brain
Dictionaries
EEG source localization
Electroencephalography
Matching pursuit algorithms
Minimization
range space property
Sensors
Sparse matrices
Sparse signal recovery
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Summary:In sparse signal recovery problems, 11-norm minimization is typically used as an alternative to more complex 10-norm minimization. The range space property (RSP) provides the conditions under which the least 11 -norm solution is equal to at most one of the least 10-norm solutions. These conditions depend on the sensing matrix and the support of the underlying sparse solution. In this paper, we address the problem of recovering sparse signals by weighting the corresponding sensing matrix with a diagonal matrix. We show that by appropriately choosing the weights, we can formulate an 11-norm minimization problem that satisfies the RSP, even if the original problem does not. By solving the weighted problem we can obtain the support of the original problem. We provide the conditions which the weights must satisfy, for both noise free and noisy cases. Although the precise conditions involve information about the support of the sparse vector, the class of good weights is very wide, and in most cases encompasses an estimate of the underlying vector obtained via a conventional method, i.e., a method that does not encourage sparsity. The proposed approach is a good candidate for Electroencephalography (EEG) sparse source localization, where the corresponding sensing matrix has high coherence. The performance of the proposed approach is evaluated via simulations and also via experiments on localizing active sources in the brain corresponding to an auditory task from EEG recordings of a human subject.
ISSN:1053-587X
1941-0476
DOI:10.1109/TSP.2017.2752690