English

The least balanced graphs and trees

Combinatorics 2026-03-26 v3

Abstract

Given a connected graph, the principal eigenvector of the adjacency matrix (often called the Perron vector) can be used to assign positive weights to the vertices. A natural way to measure the homogeneousness of this vector is by considering the ratio of its 1\ell^1 and 2\ell^2 norms. It is easy to see that the most balanced graphs in this sense (i.e., the ones with the largest ratio) are the regular graphs. What can we say about the least balanced (or most centralized) graphs with the smallest ratio? It was conjectured by R\"ucker, R\"ucker and Gutman that, for any given n6n \geq 6, among nn-vertex connected graphs the smallest ratio is achieved by the complete graph K4K_4 with a single path Pn4P_{n-4} attached to one of its vertices. In this paper we confirm this conjecture. We also verify the analogous conjecture for trees: for any given n8n \geq 8, among nn-vertex trees the smallest ratio is achieved by the star graph S5S_5 with a path Pn5P_{n-5} attached to its central vertex.

Keywords

Cite

@article{arxiv.2502.13939,
  title  = {The least balanced graphs and trees},
  author = {Péter Csikvári and Viktor Harangi},
  journal= {arXiv preprint arXiv:2502.13939},
  year   = {2026}
}
R2 v1 2026-06-28T21:50:23.794Z