Publication: Regularized multivariate analysis framework for interpretable high-dimensional variable selection
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2016-11
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IEEE
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Abstract
Multivariate Analysis (MVA) comprises a family of well-known methods for feature extraction which exploit correlations among input variables representing the data. One important property that is enjoyed by most such methods is uncorrelation among the extracted features. Recently, regularized versions of MVA methods have appeared in the literature, mainly with the goal to gain interpretability of the solution. In these cases, the solutions can no longer be obtained in a closed manner, and more complex optimization methods that rely on the iteration of two steps are frequently used. This paper recurs to an alternative approach to solve efficiently this iterative problem. The main novelty of this approach lies in preserving several properties of the original methods, most notably the uncorrelation of the extracted features. Under this framework, we propose a novel method that takes advantage of the,2,1 norm to perform variable selection during the feature extraction process. Experimental results over different problems corroborate the advantages of the proposed formulation in comparison to state of the art formulations.
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Feature extraction, Principal component analysis, Input variables, Covariance matrices, Face recognition, Multivariate analysis, Algorithm design and analysis, Adaptation models, Sparse matrices
Bibliographic citation
Munoz-Romero, S., Gomez-Verdejo, V. & Arenas-Garcia, J. (2016). Regularized Multivariate Analysis Framework for Interpretable High-Dimensional Variable Selection. IEEE Computational Intelligence Magazine, 11(4), 24–35.