On the l∞-analog of Algebraic Connectivity

Abstract

The algebraic connectivity a(G) of a graph G is defined as the second smallest eigenvalue of its Laplacian matrix L(G). It also admits a variational characterization as the minimum of a quadratic form associated with L(G), subject to l2-norm constraints. In 2024, Andrade and Dahl investigated an analogous parameter γ(G), defined using the l∞-norm instead of the l2-norm. They demonstrated that γ(G) can be computed in polynomial time using linear programming. In this article, we study the combinatorial significance of γ(G), revealing that it can be efficiently computed using a breadth-first search (BFS) algorithm. We show that γ (G) characterizes the connectedness of the graph G. We further establish new bounds on γ(G), and analyze the graphs that attain extremal values. Finally, we derive an elegant formula for γ(G) when G is the Cartesian product of finitely many graphs. Applying this formula, we explicitly compute γ(G) for various families of graphs, including hypercube graphs, Hamming graphs, and others.