Hitting times and resistance distances of q-triangulation graphs: Accurate results and applications

Abstract

Graph operations or products, such as triangulation and Kronecker product have been extensively applied to model complex networks with striking properties observed in real-world complex systems. In this paper, we study hitting times and resistance distances of q-triangulation graphs. For a simple connected graph G, its q-triangulation graph Rq(G) is obtained from G by performing the q-triangulation operation on G. That is, for every edge uv in G, we add q disjoint paths of length 2, each having u and v as its ends. We first derive the eigenvalues and eigenvectors of normalized adjacency matrix of Rq(G), expressing them in terms of those associated with G. Based on these results, we further obtain some interesting quantities about random walks and resistance distances for Rq(G), including two-node hitting time, Kemeny's constant, two-node resistance distance, Kirchhoff index, additive degree-Kirchhoff index, and multiplicative degree-Kirchhoff index. Finally, we provide exact formulas for the aforementioned quantities of iterated q-triangulation graphs, using which we provide closed-form expressions for those quantities corresponding to a class of scale-free small-world graphs, which has been applied to mimic complex networks.