English

Determining Generic Point Configurations From Unlabeled Path or Loop Lengths

Metric Geometry 2021-01-05 v3 Combinatorics

Abstract

Let p\mathbf{p} be a configuration of nn points in Rd\mathbb{R}^d for some nn and some d2d \ge 2. 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 p\mathbf{p} 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 p\mathbf{p} 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 nn and the dimension dd, and our results follow from a complete characterization of the linear automorphisms of these varieties for all nn and dd. The linear automorphisms for the special case of n=4n = 4 and d=2d = 2 correspond to the so-called Regge symmetries of the tetrahedron.

Keywords

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

R2 v1 2026-06-22T21:40:39.946Z