English

Constructing Laplacian matrices with Soules vectors: inverse eigenvalue problem and applications

Physics and Society 2019-09-26 v1 Combinatorics Spectral Theory

Abstract

The symmetric nonnegative inverse eigenvalue problem (SNIEP) asks which sets of numbers (counting multiplicities) can be the eigenvalues of a symmetric matrix with nonnegative entries. While examples of such matrices are abundant in linear algebra and various applications, this question is still open for matrices of dimension N5N\geq 5. One of the approaches to solve the SNIEP was proposed by George W. Soules, relying on a specific type of eigenvectors (Soules vectors) to derive sufficient conditions for this problem. Elsner et al. later showed a canonical way to construct all Soules vectors, based on binary rooted trees. While Soules vectors are typically treated as a totally ordered set of vectors, we propose in this article to consider a relaxed alternative: a partially ordered set of Soules vectors. We show that this perspective enables a more complete characterization of the sufficient conditions for the SNIEP. In particular, we show that the set of eigenvalues that satisfy these sufficient conditions is a convex cone, with symmetries corresponding to the automorphisms of the binary rooted tree from which the Soules vectors were constructed. As a second application, we show how Soules vectors can be used to construct graph Laplacian matrices with a given spectrum and describe a number of interesting connections with the concepts of hierarchical random graphs, equitable partitions and effective resistance.

Cite

@article{arxiv.1909.11282,
  title  = {Constructing Laplacian matrices with Soules vectors: inverse eigenvalue problem and applications},
  author = {Karel Devriendt and Renaud Lambiotte and Piet Van Mieghem},
  journal= {arXiv preprint arXiv:1909.11282},
  year   = {2019}
}
R2 v1 2026-06-23T11:25:03.585Z