Computing All Maps into a Sphere

Given topological spaces X , Y , a fundamental problem of algebraic topology is understanding the structure of all continuous maps X → Y . We consider a computational version, where X , Y are given as finite simplicial complexes, and the goal is to compute [ X , Y ], that is, all homotopy classes of...

Full description

Saved in:
Bibliographic Details
Published in:Journal of the ACM 2014-05, Vol.61 (3), p.1-44
Main Authors: CADEK, Martin, KRCAL, Marek, MATOUSEK, Jiří, SERGERAERT, Francis, VOKRINEK, Lukáš, WAGNER, Uli
Format: Article
Language:English
Subjects:
Algebra
Algorithmics. Computability. Computer arithmetics
Algorithms
Applied sciences
Computation
Computer science
control theory
systems
Convex and discrete geometry
Exact sciences and technology
Geometry
Mathematical analysis
Mathematics
Obstructions
Polynomials
Sciences and techniques of general use
Theoretical computing
Topology
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Given topological spaces X , Y , a fundamental problem of algebraic topology is understanding the structure of all continuous maps X → Y . We consider a computational version, where X , Y are given as finite simplicial complexes, and the goal is to compute [ X , Y ], that is, all homotopy classes of such maps. We solve this problem in the stable range , where for some d ≥ 2, we have dim X ≤ 2 d −2 and Y is ( d -1)- connected ; in particular, Y can be the d -dimensional sphere S d . The algorithm combines classical tools and ideas from homotopy theory (obstruction theory, Postnikov systems, and simplicial sets) with algorithmic tools from effective algebraic topology (locally effective simplicial sets and objects with effective homology). In contrast, [ X , Y ] is known to be uncomputable for general X , Y , since for X = S 1 it includes a well known undecidable problem: testing triviality of the fundamental group of Y . In follow-up papers, the algorithm is shown to run in polynomial time for d fixed, and extended to other problems, such as the extension problem , where we are given a subspace A ⊂ X and a map A → Y and ask whether it extends to a map X → Y , or computing the ℤ 2 - index —everything in the stable range. Outside the stable range, the extension problem is undecidable.
ISSN:0004-5411
1557-735X
DOI:10.1145/2597629