English

Sliding vectors, line bivectors, and torque

Mathematical Physics 2021-03-30 v1 math.MP

Abstract

This paper is a modern exposition of old ideas. The setting is a Euclidian space EE of dimension nn with associated vector space VV of dimension nn. A (non-zero) sliding vector is a vector in VV that is free to move, but only within a line LL of EE. The set of sliding vectors has dimension 2n12n-1. This set is naturally embedded in a vector space of dimension (n+12){n +1 \choose 2}. An element of this vector space will be called a line bivector. Other terms used in applications are screw and wrench. There is a nice description of line bivectors in terms of Grassmann algebra in a projective representation. It is shown that this abstract description has a concrete realization in terms of moment functions from EE to bivectors over VV. The literature in physics and engineering mainly deals with the special case n=3n=3. The results of the paper apply in this case and to its most common application, where the vectors in VV represent force and the bivectors over VV represent torque. It concludes with a discussion of duality, such as that of force and velocity or of torque and angular velocity.

Keywords

Cite

@article{arxiv.2103.15015,
  title  = {Sliding vectors, line bivectors, and torque},
  author = {William G. Faris},
  journal= {arXiv preprint arXiv:2103.15015},
  year   = {2021}
}

Comments

16 pages

R2 v1 2026-06-24T00:37:02.109Z