Determining Generic Point Configurations From Unlabeled Path or Loop Lengths
Abstract
Let be a configuration of points in for some and some . Each pair of points defines an edge, which has a Euclidean length in the configuration. A path is an ordered sequence of the points, and a loop is a path that has the same endpoints. A path or loop, as a sequence of edges, also has a Euclidean length. In this paper, we study the question of when will be uniquely determined (up to an unknowable Euclidean transform) from a given set of path or loop lengths. In particular, we consider the setting where the lengths are given simply as a set of real numbers, and are not labeled with the combinatorial data describing the paths or loops that gave rise to the lengths. Our main result is a condition on the set of paths or loops that is sufficient to guarantee such a unique determination. We also provide an algorithm, under a real computational model, for performing a reconstruction of from such unlabeled lengths. To obtain our results, we introduce a new family of algebraic varieties which we call the unsquared measurement varieties. The family is parameterized by the number of points and the dimension , and our results follow from a complete characterization of the linear automorphisms of these varieties for all and . The linear automorphisms for the special case of and correspond to the so-called Regge symmetries of the tetrahedron.
Cite
@article{arxiv.1709.03936,
title = {Determining Generic Point Configurations From Unlabeled Path or Loop Lengths},
author = {Ioannis Gkioulekas and Steven J. Gortler and Louis Theran and Todd Zickler},
journal= {arXiv preprint arXiv:1709.03936},
year = {2021}
}
Comments
Results subsumed by: arXiv:2007.12649 and arXiv:2012.14527