Circular law for random discrete matrices of given row sum

Abstract

Let Mn be a random matrix of size n× n and let λ1,...,λn be the eigenvalues of Mn. The empirical spectral distribution μMn of Mn is defined as μMn(s,t)=1n# \k n, (λk) s; (λk) t\. The circular law theorem in random matrix theory asserts that if the entries of Mn are i.i.d. copies of a random variable with mean zero and variance σ2, then the empirical spectral distribution of the normalized matrix 1σnMn of Mn converges almost surely to the uniform distribution μ over the unit disk as n tends to infinity. In this paper we show that the empirical spectral distribution of the normalized matrix of Mn, a random matrix whose rows are independent random (-1,1) vectors of given row-sum s with some fixed integer s satisfying |s| (1-o(1))n, also obeys the circular law. The key ingredient is a new polynomial estimate on the least singular value of Mn.