On the smoothed analysis of the smallest singular value with discrete noise

Abstract

Let A be an n× n real matrix, and let M be an n× n random matrix whose entries are i.i.d sub-Gaussian random variables with mean 0 and variance 1. We make two contributions to the study of sn(A+M), the smallest singular value of A+M. (1) We show that for all ε ≥ 0, P[sn(A + M) ≤ ε] = O(ε n) + 2e-(n), provided only that A has (n) singular values which are O(n). This extends a well-known result of Rudelson and Vershynin, which requires all singular values of A to be O(n). (2) We show that any bound of the form \|A\|≤ nC1P[sn(A+M)≤ n-C3] ≤ n-C2 must have C3 = (C1 C2). This complements a result of Tao and Vu, who proved such a bound with C3 = O(C1C2 + C1 + 1), and counters their speculation of possibly taking C3 = O(C1 + C2).