SHORTEST PATH AMIDST DISC OBSTACLES IS COMPUTABLE-Reference-Cited by-同舟云学术

SHORTEST PATH AMIDST DISC OBSTACLES IS COMPUTABLE

Published:2006-12 Issue:05n06 Volume:16 Page:567-590
ISSN:0218-1959
Container-title:International Journal of Computational Geometry & Applications
language:en
Short-container-title:Int. J. Comput. Geom. Appl.

Author:

CHANG EE-CHIEN¹,CHOI SUNG WOO²,KWON DO YONG³,PARK HYUNGJU³,YAP CHEE K.⁴

Affiliation:

1. National University of Singapore, Singapore

2. Duksung Women's University, Seoul, Korea

3. Korea Institute for Advanced Study, Seoul, Korea

4. Courant Institute of Mathematical Sciences, New York University, New York, USA

Abstract

An open question in Exact Geometric Computation is whether there are transcendental computations that can be made "geometrically exact". Perhaps the simplest such problem in computational geometry is that of computing the shortest obstacle-avoiding path between two points p,q in the plane, where the obstacles are a collection of n discs. This problem can be solved in O(n2 log n) time in the Real RAM model, but nothing was known about its computability in the standard (Turing) model of computation. We first give a direct proof of the Turing-computability of this problem, provided the radii of the discs are rationally related. We make the usual assumption that the numerical input data are real algebraic numbers. By appealing to effective bounds from transcendental number theory, we further show a single-exponential time upper bound when the input numbers are rational. Our result appears to be the first example of a non-algebraic combinatorial problem which is shown computable. It is also a rare example of transcendental number theory yielding positive computational results.

Publisher

World Scientific Pub Co Pte Lt

Subject

Applied Mathematics,Computational Mathematics,Computational Theory and Mathematics,Geometry and Topology,Theoretical Computer Science

Link

https://www.worldscientific.com/doi/pdf/10.1142/S0218195906002191

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