Stiffness matrices of graph blow-ups and the d-dimensional algebraic connectivity of complete bipartite graphs
Abstract
The d-dimensional algebraic connectivity ad(G) of a graph G=(V,E) is a quantitative measure of its d-dimensional rigidity, defined in terms of the eigenvalues of stiffness matrices associated with different embeddings of the graph into Rd. For a function a:V N, we denote by G(a) the a-blow-up of G, that is, the graph obtained from G by replacing every vertex v∈ V with an independent set of size a(v). We determine a relation between the stiffness matrix eigenvalues of G(a) and the eigenvalues of certain weighted stiffness matrices associated with the original graph G. This resolves, as a special case, a conjecture of Lew, Nevo, Peled and Raz on the stiffness eigenvalues of balanced blow-ups of the complete graph. As an application, we obtain a lower bound on the d-dimensional algebraic connectivity of complete bipartite graphs. More precisely, we prove the following: Let Kn,m be the complete bipartite graph with sides of size n and m respectively. Then, for every d 1 there exists cd>0 such that, for all n,m d+1 with n+m d+22, ad(Kn,m) cd· \n,m\. This bound is tight up to the multiplicative constant. In the special case d=2, n=m=3, we obtain the improved bound a2(K3,3) 2(1-λ), where λ≈ 0.6903845 is the unique positive real root of the polynomial 176 x4-200 x3+47 x2+18 x-9, which we conjecture to be tight.
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