Sliding vectors, line bivectors, and torque
Abstract
This paper is a modern exposition of old ideas. The setting is a Euclidian space of dimension with associated vector space of dimension . A (non-zero) sliding vector is a vector in that is free to move, but only within a line of . The set of sliding vectors has dimension . This set is naturally embedded in a vector space of dimension . 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 to bivectors over . The literature in physics and engineering mainly deals with the special case . The results of the paper apply in this case and to its most common application, where the vectors in represent force and the bivectors over represent torque. It concludes with a discussion of duality, such as that of force and velocity or of torque and angular velocity.
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