The smallest singular value of random combinatorial matrices

Abstract

Let Qn be a random n× n matrix with entries in \0,1\ whose rows are independent vectors of exactly n/2 zero components. We show that the smallest singular value sn(Qn) of Qn satisfies \[ P\sn(Qn) n\ C + 2 e-cn ∀ 0, \] which is optimal up to the constants C,c>0. This improves on earlier results of Ferber, Jain, Luh and Samotij, as well as Jain. In particular, for =0, we obtain the first exponential bound in dimension for the singularity probability \[ P\Qn \,\,is singular\ 2 e-cn.\] To overcome the lack of independence between entries of Qn, we introduce an arithmetic-combinatorial invariant of a pair of vectors, which we call a Combinatorial Least Common Denominator (CLCD). We prove a small ball probability inequality for the combinatorial statistic Σi=1naivσ(i) in terms of the CLCD of the pair (a,v), where σ is a uniformly random permutation of \1,2,…,n\ and a:=(a1,…,an), v:=(v1,…,vn) are real vectors. This inequality allows us to derive strong anti-concentration properties for the distance between a fixed row of Qn and the linear space spanned by the remaining rows, and prove the main result.