English

Linking Rigid Bodies Symmetrically

Metric Geometry 2014-02-04 v1 Combinatorics

Abstract

The mathematical theory of rigidity of body-bar and body-hinge frameworks provides a useful tool for analyzing the rigidity and flexibility of many articulated structures appearing in engineering, robotics and biochemistry. In this paper we develop a symmetric extension of this theory which permits a rigidity analysis of body-bar and body-hinge structures with point group symmetries. The infinitesimal rigidity of body-bar frameworks can naturally be formulated in the language of the exterior (or Grassmann) algebra. Using this algebraic formulation, we derive symmetry-adapted rigidity matrices to analyze the infinitesimal rigidity of body-bar frameworks with Abelian point group symmetries in an arbitrary dimension. In particular, from the patterns of these new matrices, we derive combinatorial characterizations of infinitesimally rigid body-bar frameworks which are generic with respect to a point group of the form Z/2Z××Z/2Z\mathbb{Z}/2\mathbb{Z}\times \dots \times \mathbb{Z}/2\mathbb{Z}. Our characterizations are given in terms of packings of bases of signed-graphic matroids on quotient graphs. Finally, we also extend our methods and results to body-hinge frameworks with Abelian point group symmetries in an arbitrary dimension. As special cases of these results, we obtain combinatorial characterizations of infinitesimally rigid body-hinge frameworks with C2\mathcal{C}_2 or D2\mathcal{D}_2 symmetry - the most common symmetry groups found in proteins.

Keywords

Cite

@article{arxiv.1402.0039,
  title  = {Linking Rigid Bodies Symmetrically},
  author = {Bernd Schulze and Shin-ichi Tanigawa},
  journal= {arXiv preprint arXiv:1402.0039},
  year   = {2014}
}

Comments

arXiv:1308.6380 version 1 was split into two papers. The version 2 of arXiv:1308.6380 consists of Sections 1 - 6 of the version 1. This paper is based on the second part of the version 1 (Sections 7 and 8)

R2 v1 2026-06-22T02:58:59.472Z