Maxwell-Laman counts for bar-joint frameworks in normed spaces

TL;DR

This paper extends the rigidity matrix concept to bar-joint frameworks in arbitrary finite-dimensional normed spaces, deriving Maxwell-Laman-type counting conditions for infinitesimal rigidity and symmetry considerations.

Contribution

It introduces a generalized rigidity matrix for normed spaces and establishes new counting conditions for rigidity and symmetry-extended frameworks.

Findings

Derived necessary Maxwell-Laman-type counting conditions.

Established symmetry-extended counting conditions for isostatic frameworks.

Proposed conjectures on combinatorial characterizations of symmetric frameworks.

Abstract

The rigidity matrix is a fundamental tool for studying the infinitesimal rigidity properties of Euclidean bar-joint frameworks. In this paper we generalize this tool and introduce a rigidity matrix for bar-joint frameworks in arbitrary finite dimensional real normed vector spaces. Using this new matrix, we derive necessary Maxwell-Laman-type counting conditions for a well-positioned bar-joint framework in a real normed vector space to be infinitesimally rigid. Moreover, we derive symmetry-extended counting conditions for a bar-joint framework with a non-trivial symmetry group to be isostatic (i.e., minimally infinitesimally rigid). These conditions imply very simply stated restrictions on the number of those structural components that are fixed by the various symmetry operations of the framework. Finally, we offer some observations and conjectures regarding combinatorial characterisations of 2-dimensional symmetric, isostatic bar-joint frameworks where the unit ball is a quadrilateral.