Finding closed quasigeodesics on convex polyhedra

Author(s)

Demaine, Erik D; Hesterberg, Adam Classen; Ku, Jason S

Abstract

A closed quasigeodesic is a closed loop on the surface of a polyhedron with at most 180◦ of surface on both sides at all points; such loops can be locally unfolded straight. In 1949, Pogorelov proved that every convex polyhedron has at least three (non-self-intersecting) closed quasigeodesics, but the proof relies on a nonconstructive topological argument. We present the first finite algorithm to find a closed quasigeodesic on a given convex polyhedron, which is the first positive progress on a 1990 open problem by O'Rourke and Wyman. The algorithm's running time is pseudopolynomial, namely O ( nε22 L` b ) time, where ε is the minimum curvature of a vertex, L is the length of the longest edge, ` is the smallest distance within a face between a vertex and a nonincident edge (minimum feature size of any face), and b is the maximum number of bits of an integer in a constant-size radical expression of a real number representing the polyhedron. We take special care in the model of computation and needed precision, showing that we can achieve the stated running time on a pointer machine supporting constant-time w-bit arithmetic operations where w = Ω(lg b).

Date issued

2020-06

URI

https://hdl.handle.net/1721.1/129938

Department

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory
Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science

Journal

Leibniz International Proceedings in Informatics, LIPIcs

Publisher

Schloss Dagstuhl, Leibniz Center for Informatics

Citation

Demaine, Erik D. et al. “Finding closed quasigeodesics on convex polyhedra.” 36th International Symposium on Computational Geometry, June 2020, virtual, Schloss Dagstuhl and Leibniz Center for Informatics, June 2020. © 2020 The Author(s)

Version: Final published version

ISSN

1868-8969

9783959771436