Graph Eigenvalues and Projection Constants
Abstract
Let λ1(G) λ2(G) ·s λn(G) denote the adjacency eigenvalues of a graph G of order n. We prove that for every k≥ 2 and every graph G on n≥ k vertices, λk(G) λR(k-1)2(k-1)\,n-1, where λR(r)=N r1N Q∈ Pr(N)Σi,j=1N |qij| and Pr(N) denotes the set of rank-r orthogonal projections in RN× N. In Banach space theory, λR(r) is well known as the maximal absolute projection constant, which has been shown to equal the quasimaximal absolute projection constant μR(r). This yields a new conceptual connection: universal upper bounds on λk(G) are controlled by the real maximal absolute projection constant λR(k-1). In dimensions where λR(k-1) is known explicitly, this gives explicit coefficients. In particular, for k=3 this recovers Tang's recent sharp bound λ3(G) n/3-1. For k=4, using λR(3)=1+52 together with Linz's closed blowups of the icosahedral graph, we obtain the result λ4(G) ≤ 1+512n-1. The method allows us to transfer known upper bounds on λR(k-1) to match the best known upper bounds on λk(G) for other values of k, such as k=5.
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