Balanced and 1-balanced graph constructions

There are several density functions for graphs which have found use in various applications. In this paper, we examine two of them, the first being given by b(G)=|E(G)|/|V(G)|b(G)=|E(G)|/|V(G)|, and the other being given by g(G)=|E(G)|/(|V(G)|−ω(G))g(G)=|E(G)|/(|V(G)|−ω(G)), where ω(G)ω(G) denotes the number of components of GG. Graphs for which b(H)≤b(G)b(H)≤b(G) for all subgraphs HH of GG are called balanced graphs  , and graphs for which g(H)≤g(G)g(H)≤g(G) for all subgraphs HH of GG are called 1-balanced graphs (also sometimes called strongly balanced or uniformly dense   in the literature). Although the functions bb and gg are very similar, they distinguish classes of graphs sufficiently differently that b(G)b(G) is useful in studying random graphs, g(G)g(G) has been useful in designing networks with reduced vulnerability to attack and in studying the World Wide Web, and a similar function is useful in the study of rigidity. First we give a new characterization of balanced graphs. Then we introduce a graph construction which generalizes the Cartesian product of graphs to produce what we call a generalized Cartesian product. We show that generalized Cartesian product derived from a tree and 1-balanced graphs are 1-balanced, and we use this to prove that the generalized Cartesian products derived from 1-balanced graphs are 1-balanced.