Ropelength Criticality
Abstract
The ropelength problem asks for the minimum-length configuration of a knotted diameter-one tube embedded in Euclidean three-space. The core curve of such a tube is called a tight knot, and its length is a knot invariant measuring complexity. In terms of the core curve, the thickness constraint has two parts: an upper bound on curvature and a self-contact condition. We give a set of necessary and sufficient conditions for criticality with respect to this constraint, based on a version of the Kuhn-Tucker theorem that we established in previous work. The key technical difficulty is to compute the derivative of thickness under a smooth perturbation. This is accomplished by writing thickness as the minimum of a -compact family of smooth functions in order to apply a theorem of Clarke. We give a number of applications, including a classification of the "supercoiled helices" formed by critical curves with no self-contacts (constrained by curvature alone) and an explicit but surprisingly complicated description of the "clasp" junctions formed when one rope is pulled tight over another.
Cite
@article{arxiv.1102.3234,
title = {Ropelength Criticality},
author = {Jason Cantarella and Joseph H. G. Fu and Robert Kusner and John M. Sullivan},
journal= {arXiv preprint arXiv:1102.3234},
year = {2016}
}
Comments
72 pages, 10 figures; v3: incorporate referee's comments: minor fixes; expository improvements; slight strengthening of some results