Accelerating model selection with safe screening for L1- regularized L2-SVM

Abstract

The L1-regularized support vector machine (SVM) is a powerful predictive learning model that can generate sparse solutions. Compared to a dense solution, a sparse solution is usually more interoperable and more effective for removing noise and preserving signals. The L1- regularized SVM has been successfully applied in numerous applications to solve problems from text mining, bioinformatics, and image processing. The regularization parameter has a significant impact on the performance of an L1-regularized SVM model. Therefore, model selection needs to be performed to choose a good regularization parameter. In model selection, one needs to learn a solution path using a set of predefined parameter values. Therefore, many L1-regularized SVM models need to be fitted, which is usually very time consuming. This paper proposes a novel safe screening technique to accelerate model selection for the L1-regularized L 2-SVM, which can lead to much better efficiency in many scenarios. The technique can successfully identify most inactive features in an optimal solution of the L1-regularized L2-SVM model and remove them before training. To achieve safe screening, the technique solves a minimization problem for each feature on a convex set that is formed by the intersection of a tight n-dimensional hyperball and the upper half-space. An efficient algorithm is designed to solve the problem based on zero-finding. Every feature that is removed by the proposed technique is guaranteed to have zero weight in the optimal solution. Therefore, an L1-regularized L2-SVM solver achieves exactly the same result by using only the selected features as when it uses the full feature set. Empirical study on high-dimensional benchmark data sets produced promising results and demonstrated the effectiveness of the proposed technique. © 2014 Springer-Verlag.