High-order Phase Transition in Random Hypergrpahs

Abstract

In this paper, we study the high-order phase transition in random r-uniform hypergraphs. For a positive integer n and a real p∈ [0,1], let H:=Hr(n,p) be the random r-uniform hypergraph with vertex set [n], where each r-set is selected as an edge with probability p independently randomly. For 1≤ s ≤ r-1 and two s-sets S and S', we say S is connected to S' if there is a sequence of alternating s-sets and edges S0,F1,S1,F2, …, Fk, Sk such that S0,S1,…, Sk are s-sets, S0=S, Sk=S', F1,F2,…, Fk are edges of H, and Si-1 Si⊂eq Fi for each 1≤ i≤ k. This is an equivalence relation over the family of all s-sets [n] s and results in a partition: V s=i Ci. Each Ci is called an s-th-order connected component and a component Ci is giant if |Ci|=(ns). We prove that the sharp threshold of the existence of the s-th-order giant connected components in Hr(n,p) is 1(r s-1)n r-s. Let c=n r-sp. If c is a constant and c<1rs-1, then with high probability, all s-th-order connected components have size O( n). If c is a constant and c > 1rs-1, then with high probability, Hr(n,p) has a unique giant connected s-th-order component and its size is (z+o(1))n s, where z=1-Σj=0∞ (r sj -j+1 )j-1j!cje-c(r sj -j+1).