On Squared Distance Matrix of Complete Multipartite Graphs

Abstract

Let G = Kn1,n2,·s,nt be a complete t-partite graph on n=Σi=1t ni vertices. The distance between vertices i and j in G, denoted by dij is defined to be the length of the shortest path between i and j. The squared distance matrix (G) of G is the n× n matrix with (i,j)th entry equal to 0 if i = j and equal to dij2 if i ≠ j. We define the squared distance energy E(G) of G to be the sum of the absolute values of its eigenvalues. We determine the inertia of (G) and compute the squared distance energy E(G). More precisely, we prove that if ni ≥ 2 for 1≤ i ≤ t, then E(G)=8(n-t) and if h= |\i : ni=1\|≥ 1, then 8(n-t)+2(h-1) ≤ E(G) < 8(n-t)+2h. Furthermore, we show that for a fixed value of n and t, both the spectral radius of the squared distance matrix and the squared distance energy of complete t-partite graphs on n vertices are maximal for complete split graph Sn,t and minimal for Tur\'an graph Tn,t.