English

Minimally rigid tensegrity frameworks

Combinatorics 2024-10-11 v1

Abstract

A dd-dimensional tensegrity framework (T,p)(T,p) is an edge-labeled geometric graph in Rd{\mathbb R}^d, which consists of a graph T=(V,BCS)T=(V,B\cup C\cup S) and a map p:VRdp:V\to {\mathbb R}^d. The labels determine whether an edge uvuv of TT corresponds to a fixed length bar in (T,p)(T,p), or a cable which cannot increase in length, or a strut which cannot decrease in length. We consider minimally infinitesimally rigid dd-dimensional tensegrity frameworks and provide tight upper bounds on the number of its edges, in terms of the number of vertices and the dimension dd. We obtain stronger upper bounds in the case when there are no bars and the framework is in generic position. The proofs use methods from convex geometry and matroid theory. A special case of our results confirms a conjecture of Whiteley from 1987. We also give an affirmative answer to a conjecture concerning the number of edges of a graph whose three-dimensional rigidity matroid is minimally connected.

Keywords

Cite

@article{arxiv.2410.07452,
  title  = {Minimally rigid tensegrity frameworks},
  author = {Adam D. W. Clay and Tibor Jordán and Sára Hanna Tóth},
  journal= {arXiv preprint arXiv:2410.07452},
  year   = {2024}
}
R2 v1 2026-06-28T19:15:22.101Z