Balancing polyhedra
Abstract
We define the mechanical complexity of a convex polyhedron interpreted as a homogeneous solid, as the difference between the total number of its faces, edges and vertices and the number of its static equilibria, and the mechanical complexity of primary equilibrium classes with stable and unstable equilibria as the infimum of the mechanical complexity of all polyhedra in that class. We prove that the mechanical complexity of a class with is the minimum of over all polyhedral pairs , where a pair of integers is called a polyhedral pair if there is a convex polyhedron with faces and vertices. In particular, we prove that the mechanical complexity of a class is zero if, and only if there exists a convex polyhedron with faces and vertices. We also give asymptotically sharp bounds for the mechanical complexity of the monostatic classes and , and offer a complexity-dependent prize for the complexity of the G\"omb\"oc-class .
Cite
@article{arxiv.1810.05382,
title = {Balancing polyhedra},
author = {Gábor Domokos and Flórián Kovács and Zsolt Lángi and Krisztina Regős and Péter T. Varga},
journal= {arXiv preprint arXiv:1810.05382},
year = {2021}
}
Comments
29 pages, 13 figures