Sparse Inverse Covariance Matrix Estimation Using Quadratic Approximation

Part of Advances in Neural Information Processing Systems 24 (NIPS 2011)

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Authors

Cho-jui Hsieh, Inderjit Dhillon, Pradeep Ravikumar, Mátyás Sustik

Abstract

The L_1 regularized Gaussian maximum likelihood estimator has been shown to have strong statistical guarantees in recovering a sparse inverse covariance matrix, or alternatively the underlying graph structure of a Gaussian Markov Random Field, from very limited samples. We propose a novel algorithm for solving the resulting optimization problem which is a regularized log-determinant program. In contrast to other state-of-the-art methods that largely use first order gradient information, our algorithm is based on Newton's method and employs a quadratic approximation, but with some modifications that leverage the structure of the sparse Gaussian MLE problem. We show that our method is superlinearly convergent, and also present experimental results using synthetic and real application data that demonstrate the considerable improvements in performance of our method when compared to other state-of-the-art methods.