English

A transfer principle and applications to eigenvalue estimates for graphs

Metric Geometry 2016-09-02 v3 Combinatorics Spectral Theory

Abstract

In this paper, we prove a variant of the Burger-Brooks transfer principle which, combined with recent eigenvalue bounds for surfaces, allows to obtain upper bounds on the eigenvalues of graphs as a function of their genus. More precisely, we show the existence of a universal constants CC such that the kk-th eigenvalue λknr\lambda_k^{nr} of the normalized Laplacian of a graph GG of (geometric) genus gg on nn vertices satisfies λknr(G)Cdmax(g+k)n,\lambda_k^{nr}(G) \leq C \frac{d_{\max}(g+k)}{n}, where dmaxd_{\max} denotes the maximum valence of vertices of the graph. This result is tight up to a change in the value of the constant CC, and improves recent results of Kelner, Lee, Price and Teng on bounded genus graphs. To show that the transfer theorem might be of independent interest, we relate eigenvalues of the Laplacian on a metric graph to the eigenvalues of its simple graph models, and discuss an application to the mesh partitioning problem, extending pioneering results of Miller-Teng-Thurston-Vavasis and Spielman-Tang to arbitrary meshes.

Keywords

Cite

@article{arxiv.1409.4228,
  title  = {A transfer principle and applications to eigenvalue estimates for graphs},
  author = {Omid Amini and David Cohen-Steiner},
  journal= {arXiv preprint arXiv:1409.4228},
  year   = {2016}
}

Comments

Major revision, 16 pages

R2 v1 2026-06-22T05:56:45.271Z