On graphs whose cycle space is spanned by their Hamilton cycles

Abstract

The cycle space of a graph G, denoted C(G), is a vector space over F2, spanned by all incidence vectors of edge-sets of cycles of G. If G has n vertices, then Cn(G) denotes the subspace of C(G), spanned by the incidence vectors of Hamilton cycles of G. We consider several known sufficient conditions for Hamiltonicity and show that an appropriate and fairly mild strengthening of each such condition in fact ensures the stronger property Cn(G) = C(G). In particular, we consider the classical Chvátal-Erdős criterion and prove that (under various additional restrictions) if n is odd and κ(G) ≥ c α(G), where c is a sufficiently large absolute constant, then Cn(G) = C(G). Moreover, considering the McDiarmid-Yolov criterion we prove that if n is odd and δ(G) ≥ \2 α(G) + 9, α(G) + 18 \, where α(G) is the so-called bipartite independence number of G, then Cn(G) = C(G). We also prove that if n is odd and G admits 16 α(G) + 12 pairwise disjoint connected dominating sets, Cn(G) = C(G). Finally, we consider an effective Chvátal-Erdős type criterion for bipartite graphs and prove that if G is a balanced bipartite graph on 2n vertices, satisfying αBIP(G) ≤ 2 δ(G) - 24, then C2n(G) = C(G).