On Domination Exponents for Pairs of Graphs

Abstract

Understanding graph density profiles is notoriously challenging. Even for pairs of graphs, complete characterizations are known only in very limited cases, such as edges versus cliques. This paper explores a relaxation of the graph density profile problem by examining the homomorphism density domination exponent C(H1, H2). This is the smallest real number c ≥ 0 such that t(H1, T) ≥ t(H2, T)c for all target graphs T (if such a c exists) where t(H,T) is the homomorphism density from H to T. We demonstrate that infinitely many families of graphs are required to realize C(H1, H2) for all connected graphs H1, H2. We derive the homomorphism density domination exponent for a variety of graph pairs, including paths and cycles. As a couple of typical examples, we obtain exact values when H1 is an even cycle and H2 contains a Hamiltonian cycle, and provide asymptotically sharp bounds when both H1 and H2 are odd cycles.