Invertibility of Sparse non-Hermitian matrices

Abstract

We consider a class of sparse random matrices of the form An =(i,jδi,j)i,j=1n, where \i,j\ are i.i.d.~centered random variables, and \δi,j\ are i.i.d.~Bernoulli random variables taking value 1 with probability pn, and prove a quantitative estimate on the smallest singular value for pn = ( nn), under a suitable assumption on the spectral norm of the matrices. This establishes the invertibility of a large class of sparse matrices. For pn =( n-α) with some α ∈ (0,1), we deduce that the condition number of An is of order n with probability tending to one under the optimal moment assumption on \i,j\. This in particular, extends a conjecture of von Neumann about the condition number to sparse random matrices with heavy-tailed entries. In the case that the random variables \i,j\ are i.i.d.~sub-Gaussian, we further show that a sparse random matrix is singular with probability at most (-c n pn) whenever pn is above the critical threshold pn = ( nn). The results also extend to the case when \i,j\ have a non-zero mean. We further find quantitative estimates on the smallest singular value of the adjacency matrix of a directed Erdos-R\'eyni graph whenever its edge connectivity probability is above the critical threshold ( nn).