A Geometric View of Combinatorial Fiedler Theory

Abstract

Recently, Andrade and Dahl introduced combinatorial Fiedler theory by studying a parameter b(G) defined as the 1-analog of the Rayleigh quotient minimization characterization of the algebraic connectivity of a graph G=(V,E). In this work, we study the corresponding maximization problem, which plays the role of the 1-analog of the largest Laplacian eigenvalue. We show that the new parameter B(G) associated with this maximization problem admits a simple exact description: it is the average of the two largest vertex degrees of G. A unified combinatorial treatment of the minimization and maximization problems is presented first. Later, both optimization problems are reinterpreted in a geometrical setting. The feasible set is identified with a (n-2)-dimensional cuboctahedron shell where n=|V|. Additional structure is presented for this polyhedron, including the fact that maximizing solutions arise at its vertices and minimizing solutions arise at the centers of its facets. Finally, we analyze the number of optimal vectors for b(G) and B(G) for several graph families. Although the value of B(G) is determined by the two largest degrees, we prove that counting the vectors that attain this value is actually \#P-complete.

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