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Main Author: Vermant, Joannes
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.05435
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author Vermant, Joannes
author_facet Vermant, Joannes
contents In recent work, Stokes and Vermant considered graph-of-groups realisations of hypergraphs as a new description of rigidity-theoretic problems. In this paper, we show that the infinitesimal aspects of graph-of-groups realisations can be analysed using cellular sheaves and their cohomology. Using these tools, we give an algebraic condition for Henneberg moves to preserve independence, and we prove that the infinitesimal rigidity and flexibility of certain graph-of-groups realisations are generic properties. We use these results to show that whenever a rigidity-theoretic problem is defined in a Lie group $G$ using a $1$-dimensional connected subgroup $H$ with $N_{G}(H)/H$ finite, then the so-called Maxwell-count leads to a necessary and sufficient condition for minimal rigidity, generalising various known results in the literature.
format Preprint
id arxiv_https___arxiv_org_abs_2603_05435
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Homological methods in rigidity theory using graphs of groups
Vermant, Joannes
Combinatorics
Algebraic Topology
52C25
In recent work, Stokes and Vermant considered graph-of-groups realisations of hypergraphs as a new description of rigidity-theoretic problems. In this paper, we show that the infinitesimal aspects of graph-of-groups realisations can be analysed using cellular sheaves and their cohomology. Using these tools, we give an algebraic condition for Henneberg moves to preserve independence, and we prove that the infinitesimal rigidity and flexibility of certain graph-of-groups realisations are generic properties. We use these results to show that whenever a rigidity-theoretic problem is defined in a Lie group $G$ using a $1$-dimensional connected subgroup $H$ with $N_{G}(H)/H$ finite, then the so-called Maxwell-count leads to a necessary and sufficient condition for minimal rigidity, generalising various known results in the literature.
title Homological methods in rigidity theory using graphs of groups
topic Combinatorics
Algebraic Topology
52C25
url https://arxiv.org/abs/2603.05435