English

Support Recovery with Sparsely Sampled Free Random Matrices

Information Theory 2015-03-20 v1 math.IT

Abstract

Consider a Bernoulli-Gaussian complex nn-vector whose components are Vi=XiBiV_i = X_i B_i, with Xi\Cc\Nc(0,\Pcx)X_i \sim \Cc\Nc(0,\Pc_x) and binary BiB_i mutually independent and iid across ii. This random qq-sparse vector is multiplied by a square random matrix \Um\Um, and a randomly chosen subset, of average size npn p, p[0,1]p \in [0,1], of the resulting vector components is then observed in additive Gaussian noise. We extend the scope of conventional noisy compressive sampling models where \Um\Um is typically %A16 the identity or a matrix with iid components, to allow \Um\Um satisfying a certain freeness condition. This class of matrices encompasses Haar matrices and other unitarily invariant matrices. We use the replica method and the decoupling principle of Guo and Verd\'u, as well as a number of information theoretic bounds, to study the input-output mutual information and the support recovery error rate in the limit of nn \to \infty. We also extend the scope of the large deviation approach of Rangan, Fletcher and Goyal and characterize the performance of a class of estimators encompassing thresholded linear MMSE and 1\ell_1 relaxation.

Keywords

Cite

@article{arxiv.1208.5269,
  title  = {Support Recovery with Sparsely Sampled Free Random Matrices},
  author = {Antonia Tulino and Giuseppe Caire and Sergio Verdu' and Shlomo Shamai},
  journal= {arXiv preprint arXiv:1208.5269},
  year   = {2015}
}
R2 v1 2026-06-21T21:55:30.875Z