Hamilton cycles, minimum degree and bipartite holes

Abstract

We present a tight extremal threshold for the existence of Hamilton cycles in graphs with large minimum degree and without a large ``bipartite hole`` (two disjoint sets of vertices with no edges between them). This result extends Dirac's classical theorem, and is related to a theorem of Chv\'atal and Erdos. In detail, an (s, t)-bipartite-hole in a graph G consists of two disjoint sets of vertices S and T with |S|= s and |T|=t such that there are no edges between S and T; and α(G) is the maximum integer r such that G contains an (s, t)-bipartite-hole for every pair of non-negative integers s and t with s + t = r. Our central theorem is that a graph G with at least 3 vertices is Hamiltonian if its minimum degree is at least α(G). From the proof we obtain a polynomial time algorithm that either finds a Hamilton cycle or a large bipartite hole. The theorem also yields a condition for the existence of k edge-disjoint Hamilton cycles. We see that for dense random graphs G(n,p), the probability of failing to contain many edge-disjoint Hamilton cycles is (1 - p)(1 + o(1))n. Finally, we discuss the complexity of calculating and approximating α(G).