How frequently is a system of 2-linear Boolean equations solvable?

Abstract

We consider a random system of equations xi+xj=b(i,j) (mod 2), (xu∈ \0,1\,\, b(u,v)=b(v,u)∈\0,1\), with the pairs (i,j) from E, a symmetric subset of [n]× [n]. E is chosen uniformly at random among all such subsets of a given cardinality m; alternatively (i,j)∈ E with a given probability p, independently of all other pairs. Also, given E, \be=0\=\be=1\ for each e∈ E, independently of all other be. It is well known that, as m passes through n/2 (p passes through 1/n, resp.), the underlying random graph G(n,\#edges=m), (G(n,(edge)=p), resp.) undergoes a rapid transition, from essentially a forest of many small trees to a graph with one large, multicyclic, component in a sea of small tree components. We should expect then that the solvability probability decreases precipitously in the vicinity of m n/2 (p 1/n), and indeed this probability is of order (1-2m/n)1/4, for m<n/2 ((1-pn)1/4, for p<1/n, resp.). We show that in a near-critical phase m=(n/2)(1+ n-1/3) (p=(1+ n-1/3)/n, resp.), =o(n1/12), the system is solvable with probability asymptotic to c()n-1/12, for some explicit function c()>0. Mike Molloy noticed that the Boolean system with be 1 is solvable iff the underlying graph is 2-colorable, and asked whether this connection might be used to determine an order of probability of 2-colorability in the near-critical case. We answer Mike's question affirmatively and show that probability of 2-colorability is 2-1/4e1/8c(λ)n-1/12, and asymptotic to 2-1/4e1/8c()n-1/12 at a critical phase =O(1), and for -∞. (Submitted to Electronic Journal of Combinatorics on September 7, 2009.)