Probabilistic Rank and Matrix Rigidity

Abstract

We consider a notion of probabilistic rank and probabilistic sign-rank of a matrix, which measures the extent to which a matrix can be probabilistically represented by low-rank matrices. We demonstrate several connections with matrix rigidity, communication complexity, and circuit lower bounds, including: The Walsh-Hadamard Transform is Not Very Rigid. We give surprising upper bounds on the rigidity of a family of matrices whose rigidity has been extensively studied, and was conjectured to be highly rigid. For the 2n × 2n Walsh-Hadamard transform Hn (a.k.a. Sylvester matrices, or the communication matrix of Inner Product mod 2), we show how to modify only 2ε n entries in each row and make the rank drop below 2n(1-(ε2/(1/ε))), for all ε > 0, over any field. That is, it is not possible to prove arithmetic circuit lower bounds on Hadamard matrices, via L. Valiant's matrix rigidity approach. We also show non-trivial rigidity upper bounds for Hn with smaller target rank. Matrix Rigidity and Threshold Circuit Lower Bounds. We give new consequences of rigid matrices for Boolean circuit complexity. We show that explicit n × n Boolean matrices which maintain rank at least 2( n)1-δ after n2/2( n)δ/2 modified entries would yield a function lacking sub-quadratic-size AC0 circuits with two layers of arbitrary linear threshold gates. We also prove that explicit 0/1 matrices over R which are modestly more rigid than the best known rigidity lower bounds for sign-rank would imply strong lower bounds for the infamously difficult class THR THR.