Total Conformal Rigidity in Graphs
Abstract
We introduce and study a generalization of conformal rigidity for graphs. A graph is -conformally rigid if the uniform edge weights simultaneously maximize the sum of the smallest nontrivial Laplacian eigenvalues and minimize the sum of the largest, over all normalized non-negative weight assignments. A graph that is -conformally rigid for every is called totally conformally rigid. Our main result is a complete characterization: a graph is totally conformally rigid if and only if it is edge-rigid, meaning every canonical spectral embedding onto a Laplacian eigenspace is edge-isometric. We further show this is equivalent to all edges of the graph being pairwise Laplacian-cospectral, that is, the removal of any single edge yields a graph with the same Laplacian characteristic polynomial. Using semidefinite programming duality, we establish this equivalence and derive a polynomial-time algorithm for deciding edge-rigidity using only integer arithmetic. We provide a combinatorial characterization of edge-rigidity in terms of Laplacian walks and connect it to the walk-regularity of signed line graphs. We show that a graph is edge-rigid if and only if it is either -walk-regular or -walk-biregular, and we finally show an equivalence based on monotone gauges and gauge duality. As an application, we derive two non-trivial combinatorial consequences of total conformal rigidity, relating it to the number of spanning trees and the Kirchhoff index of the graph.
Cite
@article{arxiv.2605.08508,
title = {Total Conformal Rigidity in Graphs},
author = {Henrique Assumpção and Gabriel Coutinho and Chris Godsil},
journal= {arXiv preprint arXiv:2605.08508},
year = {2026}
}
Comments
22 pages, 1 figure