On the Rank, Kernel, and Core of Sparse Random Graphs

Abstract

We study the rank of the adjacency matrix A of a random Erdos Renyi graph G G(n,p). It is well known that when p = ((n) - ω(1))/n, with high probability, A is singular. We prove that when p = ω(1/n), with high probability, the corank of A is equal to the number of isolated vertices remaining in G after the Karp-Sipser leaf-removal process, which removes vertices of degree one and their unique neighbor. We prove a similar result for the random matrix B, where all entries are independent Bernoulli random variables with parameter p. Namely, we show that if H is the bipartite graph with bi-adjacency matrix B, then the corank of B is with high probability equal to the max of the number of left isolated vertices and the number of right isolated vertices remaining after the Karp-Sipser leaf-removal process on H. Additionally, we show that with high probability, the k-core of G(n, p) is full rank for any k ≥ 3 and p = ω(1/n). This partially resolves a conjecture of Van Vu for p = ω(1/n). Finally, we give an application of the techniques in this paper to gradient coding, a problem in distributed computing.