Topological complexity

In mathematics, topological complexity of a topological space X (also denoted by TC(X)) is a topological invariant closely connected to the motion planning problem^{[further explanation needed]}, introduced by Michael Farber in 2003.

Definition[edit]

Let X be a topological space and $PX=\{\gamma :[0,1]\,\to \,X\}$ be the space of all continuous paths in X. Define the projection $\pi :PX\to \,X\times X$ by $\pi (\gamma )=(\gamma (0),\gamma (1))$ . The topological complexity is the minimal number k such that

there exists an open cover $\{U_{i}\}_{i=1}^{k}$ of $X\times X$ ,
for each $i=1,\ldots ,k$ , there exists a local section $s_{i}:\,U_{i}\to \,PX.$

Examples[edit]

The topological complexity: TC(X) = 1 if and only if X is contractible.
The topological complexity of the sphere $S^{n}$ is 2 for n odd and 3 for n even. For example, in the case of the circle $S^{1}$ , we may define a path between two points to be the geodesic between the points, if it is unique. Any pair of antipodal points can be connected by a counter-clockwise path.
If $F(\mathbb {R} ^{m},n)$ is the configuration space of n distinct points in the Euclidean m-space, then

TC(F(\mathbb {R} ^{m},n))={\begin{cases}2n-1&\mathrm {for\,\,{\it {m}}\,\,odd} \\2n-2&\mathrm {for\,\,{\it {m}}\,\,even.} \end{cases}}

The topological complexity of the Klein bottle is 5.^[1]

References[edit]

^ Cohen, Daniel C.; Vandembroucq, Lucile (2016). "Topological Complexity of the Klein bottle". arXiv:1612.03133 [math.AT].

Farber, M. (2003). "Topological complexity of motion planning". Discrete & Computational Geometry. Vol. 29, no. 2. pp. 211–221.
Armindo Costa: Topological Complexity of Configuration Spaces, Ph.D. Thesis, Durham University (2010), online

External links[edit]

Topological complexity on nLab

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[1] Cohen, Daniel C.; Vandembroucq, Lucile (2016). "Topological Complexity of the Klein bottle". arXiv:1612.03133 [math.AT].

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