The completion numbers of Hamiltonicity and pancyclicity in random graphs

Abstract

Let μ(G) denote the minimum number of edges whose addition to G results in a Hamiltonian graph, and let μ(G) denote the minimum number of edges whose addition to G results in a pancyclic graph. We study the distributions of μ (G),μ(G) in the context of binomial random graphs. Letting d=d(n) := n· p, we prove that there exists a function f:R+ [0,1] of order f(d) = 12de-d+e-d+O(d6e-3d) such that, if G G(n,p) with 20 d(n) 0.4 n, then with high probability μ (G)= (1+o(1))· f(d)· n. Let ni(G) denote the number of degree i vertices in G. A trivial lower bound on μ(G) is given by the expression n0(G) + 12n1(G) . In the denser regime of random graphs, we show that if np-13 n - 2 n ∞ and G G(n,p) then, with high probability, μ (G) = n0(G) + 12n1(G) . For completion to pancyclicity, we show that if G G(n,p) and np 20 then, with high probability, μ (G)=μ (G). Finally, we present a polynomial time algorithm such that, if G G(n,p) and np 20, then, with high probability, the algorithm returns a set of edges of size μ (G) whose addition to G results in a pancyclic (and therefore also Hamiltonian) graph.