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Sparse Reduced Rank Huber Regression in High Dimensions

Kean Ming Tan, Qiang Sun, Daniela Witten

2022Journal of the American Statistical Association18 citationsDOIOpen Access PDF

Abstract

We propose a sparse reduced rank Huber regression for analyzing large and complex high-dimensional data with heavy-tailed random noise. The proposed method is based on a convex relaxation of a rank- and sparsity-constrained nonconvex optimization problem, which is then solved using a block coordinate descent and an alternating direction method of multipliers algorithm. We establish nonasymptotic estimation error bounds under both Frobenius and nuclear norms in the high-dimensional setting. This is a major contribution over existing results in reduced rank regression, which mainly focus on rank selection and prediction consistency. Our theoretical results quantify the tradeoff between heavy-tailedness of the random noise and statistical bias. For random noise with bounded (1+δ)th moment with δ∈(0,1), the rate of convergence is a function of δ, and is slower than the sub-Gaussian-type deviation bounds; for random noise with bounded second moment, we obtain a rate of convergence as if sub-Gaussian noise were assumed. We illustrate the performance of the proposed method via extensive numerical studies and a data application. Supplementary materials for this article are available online.

Topics & Concepts

Coordinate descentMathematicsRate of convergenceBounded functionApplied mathematicsRank (graph theory)Moment (physics)Noise (video)Consistency (knowledge bases)GaussianGaussian noiseMathematical optimizationAlgorithmComputer scienceCombinatoricsMathematical analysisArtificial intelligenceDiscrete mathematicsComputer networkChannel (broadcasting)Quantum mechanicsPhysicsImage (mathematics)Classical mechanicsSparse and Compressive Sensing TechniquesStatistical Methods and InferenceAdvanced Statistical Methods and Models
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