The asymptotic value of energy for matrices with degree-distance-based entries of random graphs

Abstract

For a graph G=(V, E) and i, j∈ V, denote the distance between i and j in G by D(i, j) and the degrees of i, j by di, dj, respectively. Let f(D(i, j), di, dj) be a function symmetric in i and j. Define a matrix Wf(G), called the weighted distance matrix, of G, with the ij-entry Wf(G)(i, j)=f(D(i, j), di, dj) if i≠ j and Wf(G)(i, j)=0 if i=j. In this paper, we prove that if the symmetric function f satisfies that f(D(i, j), (1+o(1))np, (1+o(1))np)=(1+o(1))f(D(i, j), np, np), then for almost all graphs Gp in the Erdos-Renyi random graph model Gn, p, the energy of Wf(Gp) is \(83πp(1-p)+o(1))·|f(1, np, np)-f(2, np, np)|+o(|f(2, np, np)|)\· n3/2. As a consequence, we give the asymptotic values of energies of a variety of weighted distance matrices with function f from distance-based only and mixed with degree-distance-based topological indices of chemical use. This generalizes our former result with only degree-based weights.