Robust sparse covariance estimation by thresholding Tyler’s M-estimator
John Goes, Gilad Lerman, Boaz Nadler
Abstract
Estimating a high-dimensional sparse covariance matrix from a limited number of samples is a fundamental task in contemporary data analysis. Most proposals to date, however, are not robust to outliers or heavy tails. Toward bridging this gap, in this work we consider estimating a sparse shape matrix from $n$ samples following a possibly heavy-tailed elliptical distribution. We propose estimators based on thresholding either Tyler’s M-estimator or its regularized variant. We prove that in the joint limit as the dimension $p$ and the sample size $n$ tend to infinity with $p/n\to\gamma>0$, our estimators are minimax rate optimal. Results on simulated data support our theoretical analysis.
Topics & Concepts
ThresholdingEstimatorOutlierMathematicsMinimaxCovariance matrixDimension (graph theory)CovariancePattern recognition (psychology)Estimation of covariance matricesAlgorithmMatrix (chemical analysis)Artificial intelligenceRobust statisticsData MatrixSample size determinationLimit (mathematics)Joint (building)Sparse matrixRobustness (evolution)Computer scienceScatter matrixSample (material)Mathematical optimizationEstimation theoryBridging (networking)StatisticsApplied mathematicsSparse and Compressive Sensing TechniquesAdvanced Statistical Methods and ModelsStatistical Methods and Inference