Eigenvalue interlacing and weight parameters of graphs

TL;DR

This paper explores how eigenvalue interlacing can be used to analyze weight parameters and pseudo-regular partitions in graphs, leading to bounds on graph capacities and eigenvalue multiplicities.

Contribution

It introduces a method to apply eigenvalue interlacing to weight parameters and pseudo-regular partitions, generalizing existing results and deriving new bounds for graph capacities and eigenvalue multiplicities.

Findings

Bound on the weight Shannon capacity of graphs

Upper bounds for eigenvalue multiplicities in distance-regular graphs

Results involving Laplacian spectrum analysis

Abstract

Eigenvalue interlacing is a versatile technique for deriving results in algebraic combinatorics. In particular, it has been successfully used for proving a number of results about the relation between the (adjacency matrix or Laplacian) spectrum of a graph and some of its properties. For instance, some characterizations of regular partitions, and bounds for some parameters, such as the independence and chromatic numbers, the diameter, the bandwidth, etc., have been obtained. For each parameter of a graph involving the cardinality of some vertex sets, we can define its corresponding weight parameter by giving some "weights" (that is, the entries of the positive eigenvector) to the vertices and replacing cardinalities by square norms. The key point is that such weights "regularize" the graph, and hence allow us to define a kind of regular partition, called "pseudo-regular," intended for general graphs. Here we show how to use interlacing for proving results about some weight parameters and pseudo-regular partitions of a graph. For instance, generalizing a well-known result of Lov\'asz, it is shown that the weight Shannon capacity $\Theta^*$ of a connected graph $\G$, with $n$ vertices and (adjacency matrix) eigenvalues $\lambda_1>\lambda_2\ge\...\ge \lambda_n$, satisfies $$ \Theta\le \Theta^* \le \frac{\|\vecnu\|^2}{1-\frac{\lambda_1}{\lambda_n}} $$ where $\Theta$ is the (standard) Shannon capacity and $\vecnu$ is the positive eigenvector normalized to have smallest entry 1. In the special case of regular graphs, the results obtained have some interesting corollaries, such as an upper bound for some of the multiplicities of the eigenvalues of a distance-regular graph. Finally, some results involving the Laplacian spectrum are derived. spectrum are derived.