High-dimensional regression; Dimension Reduction; Random Projection; Screening
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Abstract:
We examine the linear regression problem in a challenging high-dimensional setting with correlated predictors to explain and predict relevant quantities, with explicitly allowing the regression coefficient to vary from sparse to dense. Most classical high-dimensional regression estimators require some degree of sparsity. We discuss the more recent concepts of variable screening and random projection as computationally fast dimension reduction tools, and propose a new random projection matrix tailored to the linear regression problem with a theoretical bound on the gain in expected prediction error over conventional random projections.
Around this new random projection, we built the Sparse Projected Averaged Regression (SPAR) method combining probabilistic variable screening steps with the random projection steps to obtain an ensemble of small linear models. In difference to existing methods, we introduce a thresholding parameter to obtain some degree of sparsity.
In extensive simulations and two real data applications we guide through the elements of this method and compare prediction and variable selection performance to various competitors. For prediction, our method performs at least as good as the best competitors in most settings with a high number of truly active variables, while variable selection remains a hard task for all methods in high dimensions.
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Project title:
Hochdimensionales statistisches Lernen: Neue Methoden zur Förderung der Wirtschafts- und Nachhaltigkeitspolitik: ZK 35-G (FWF - Österr. Wissenschaftsfonds)
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Research Areas:
Mathematical and Algorithmic Foundations: 40% Modeling and Simulation: 20% Fundamental Mathematics Research: 40%