Information-Theoretic Limits of Matrix Completion

Abstract

We propose an information-theoretic framework for matrix completion. The theory goes beyond the low-rank structure and applies to general matrices of "low description complexity". Specifically, we consider m× n random matrices X of arbitrary distribution (continuous, discrete, discrete-continuous mixture, or even singular). With S an -support set of X, i.e., P[X∈S]≥ 1-, and dimB(S) denoting the lower Minkowski dimension of S, we show that k> dimB(S) trace inner product measurements with measurement matrices Ai, suffice to recover X with probability of error at most . The result holds for Lebesgue a.a. Ai and does not need incoherence between the Ai and the unknown matrix X. We furthermore show that k> dimB(S) measurements also suffice to recover the unknown matrix X from measurements taken with rank-one Ai, again this applies to a.a. rank-one Ai. Rank-one measurement matrices are attractive as they require less storage space than general measurement matrices and can be applied faster. Particularizing our results to the recovery of low-rank matrices, we find that k>(m+n-r)r measurements are sufficient to recover matrices of rank at most r. Finally, we construct a class of rank-r matrices that can be recovered with arbitrarily small probability of error from k<(m+n-r)r measurements.