English

Exponential Family Matrix Completion under Structural Constraints

Machine Learning 2015-09-16 v1 Machine Learning

Abstract

We consider the matrix completion problem of recovering a structured matrix from noisy and partial measurements. Recent works have proposed tractable estimators with strong statistical guarantees for the case where the underlying matrix is low--rank, and the measurements consist of a subset, either of the exact individual entries, or of the entries perturbed by additive Gaussian noise, which is thus implicitly suited for thin--tailed continuous data. Arguably, common applications of matrix completion require estimators for (a) heterogeneous data--types, such as skewed--continuous, count, binary, etc., (b) for heterogeneous noise models (beyond Gaussian), which capture varied uncertainty in the measurements, and (c) heterogeneous structural constraints beyond low--rank, such as block--sparsity, or a superposition structure of low--rank plus elementwise sparseness, among others. In this paper, we provide a vastly unified framework for generalized matrix completion by considering a matrix completion setting wherein the matrix entries are sampled from any member of the rich family of exponential family distributions; and impose general structural constraints on the underlying matrix, as captured by a general regularizer R(.)\mathcal{R}(.). We propose a simple convex regularized MM--estimator for the generalized framework, and provide a unified and novel statistical analysis for this general class of estimators. We finally corroborate our theoretical results on simulated datasets.

Keywords

Cite

@article{arxiv.1509.04397,
  title  = {Exponential Family Matrix Completion under Structural Constraints},
  author = {Suriya Gunasekar and Pradeep Ravikumar and Joydeep Ghosh},
  journal= {arXiv preprint arXiv:1509.04397},
  year   = {2015}
}

Comments

20 pages, 9 figures

R2 v1 2026-06-22T10:56:48.915Z