Configuration space (mathematics) explained
In mathematics, a configuration space is a construction closely related to state spaces or phase spaces in physics. In physics, these are used to describe the state of a whole system as a single point in a high-dimensional space. In mathematics, they are used to describe assignments of a collection of points to positions in a topological space. More specifically, configuration spaces in mathematics are particular examples of configuration spaces in physics in the particular case of several non-colliding particles.
Definition
For a topological space
and a positive integer
, let
be the
Cartesian product of
copies of
, equipped with the
product topology. The
nth (ordered) configuration space of
is the set of
n-
tuples of pairwise distinct points in
:
\operatorname{Conf}n(X):=Xn\smallsetminus\{(x1,x2,\ldots,xn)\inXn\midxi=xj forsomei ≠ j\}.
This space is generally endowed with the subspace topology from the inclusion of
into
. It is also sometimes denoted
,
, or
.
on the points in
given by
\begin{align}
Sn x \operatorname{Conf}n(X)&\longrightarrow\operatorname{Conf}n(X)\\
(\sigma,x)&\longmapsto\sigma(x)=(x\sigma(1),x\sigma(2),\ldots,x\sigma(n)).
\end{align}
This action gives rise to the th unordered configuration space of ,
\operatorname{UConf}n(X):=\operatorname{Conf}n(X)/Sn,
which is the orbit space of that action. The intuition is that this action "forgets the names of the points". The unordered configuration space is sometimes denoted
,
, or
. The collection of unordered configuration spaces over all
is the
Ran space, and comes with a natural topology.
Alternative formulations
For a topological space
and a finite set
, the
configuration space of with particles labeled by is
\operatorname{Conf}S(X):=\{f\midf\colonS\hookrightarrowXisinjective\}.
For
, define
. Then the
th configuration space of X is denoted simply
.
[2] Examples
- The space of ordered configuration of two points in
is
homeomorphic to the product of the Euclidean 3-space with a circle, i.e.
| 2)\cong |
| \operatorname{Conf} | |
| 2(R |
R3 x S1
.
- More generally, the configuration space of two points in
is
homotopy equivalent to the sphere
.
[3] - The configuration space of
points in
is the classifying space of the
th
braid group (see below).
Connection to braid groups
See main article: Braid group.
The -strand braid group on a connected topological space is
Bn(X):=\pi1(\operatorname{UConf}n(X)),
the
fundamental group of the
th unordered configuration space of . The
-strand pure braid group on is
[4] Pn(X):=\pi1(\operatorname{Conf}n(X)).
The first studied braid groups were the Artin braid groups
Bn\cong\pi1(\operatorname{UConf}
. While the above definition is not the one that
Emil Artin gave,
Adolf Hurwitz implicitly defined the Artin braid groups as fundamental groups of configuration spaces of the complex plane considerably before Artin's definition (in 1891).
[5] It follows from this definition and the fact that
and
| 2) |
| \operatorname{UConf} | |
| n(R |
are
Eilenberg–MacLane spaces of type
, that the unordered configuration space of the plane
| 2) |
| \operatorname{UConf} | |
| n(R |
is a
classifying space for the Artin braid group, and
is a classifying space for the pure Artin braid group, when both are considered as
discrete groups.
[6] Configuration spaces of manifolds
If the original space
is a
manifold, its ordered configuration spaces are open subspaces of the powers of
and are thus themselves manifolds. The configuration space of distinct unordered points is also a manifold, while the configuration space of
not necessarily distinct unordered points is instead an
orbifold.
A configuration space is a type of classifying space or (fine) moduli space. In particular, there is a universal bundle
which is a sub-bundle of the trivial bundle
, and which has the property that the fiber over each point
is the
n element subset of
classified by
p.
Homotopy invariance
The homotopy type of configuration spaces is not homotopy invariant. For example, the spaces
are not homotopy equivalent for any two distinct values of
:
is empty for
,
is not connected for
,
is an
Eilenberg–MacLane space of type
, and
is
simply connected for
.
It used to be an open question whether there were examples of compact manifolds which were homotopy equivalent but had non-homotopy equivalent configuration spaces: such an example was found only in 2005 by Riccardo Longoni and Paolo Salvatore. Their example are two three-dimensional lens spaces, and the configuration spaces of at least two points in them. That these configuration spaces are not homotopy equivalent was detected by Massey products in their respective universal covers. Homotopy invariance for configuration spaces of simply connected closed manifolds remains open in general, and has been proved to hold over the base field
.
[7] [8] Real homotopy invariance of simply connected compact manifolds with simply connected boundary of dimension at least 4 was also proved.
[9] Configuration spaces of graphs
Some results are particular to configuration spaces of graphs. This problem can be related to robotics and motion planning: one can imagine placing several robots on tracks and trying to navigate them to different positions without collision. The tracks correspond to (the edges of) a graph, the robots correspond to particles, and successful navigation corresponds to a path in the configuration space of that graph.
For any graph
,
\operatorname{Conf}n(\Gamma)
is an Eilenberg–MacLane space of type
and
strong deformation retracts to a
CW complex of dimension
, where
is the number of vertices of
degree at least 3.
[10] Moreover,
\operatorname{UConf}n(\Gamma)
and
\operatorname{Conf}n(\Gamma)
deformation retract to
non-positively curved cubical complexes of dimension at most
.
[11] [12] Configuration spaces of mechanical linkages
One also defines the configuration space of a mechanical linkage with the graph
its underlying geometry. Such a graph is commonly assumed to be constructed as concatenation of rigid rods and hinges. The configuration space of such a linkage is defined as the totality of all its admissible positions in the Euclidean space equipped with a proper metric. The configuration space of a generic linkage is a smooth manifold, for example, for the trivial planar linkage made of
rigid rods connected with revolute joints, the configuration space is the n-torus
.
[13] [14] The simplest singularity point in such configuration spaces is a product of a cone on a homogeneous quadratic hypersurface by a Euclidean space. Such a singularity point emerges for linkages which can be divided into two sub-linkages such that their respective endpoints trace-paths intersect in a non-transverse manner, for example linkage which can be aligned (i.e. completely be folded into a line).
[15] Compactification
The configuration space
of distinct points is non-compact, having ends where the points tend to approach each other (become confluent). Many geometric applications require compact spaces, so one would like to
compactify
, i.e., embed it as an open subset of a compact space with suitable properties. Approaches to this problem have been given by
Raoul Bott and
Clifford Taubes,
[16] as well as
William Fulton and
Robert MacPherson.
[17] See also
Notes and References
- 0806.4111. Farber. Michael. Topological complexity of configuration spaces. Grant. Mark. 2009. Proceedings of the American Mathematical Society. 137. 5. 1841–1847. 2470845. 10.1090/S0002-9939-08-09808-0. 16188638.
- 1612.08290. Chettih. Safia. The Homology of Configuration Spaces of Trees with Loops. . 18. 4. 2443–2469. Lütgehetmann. Daniel. 2018. 10.2140/agt.2018.18.2443. 119168700.
- Sinha. Dev. 2010-02-20. The homology of the little disks operad . 2 . math/0610236.
- Book: Ghrist, Robert. Braids. 2009-12-01. World Scientific. 9789814291408. Berrick. A. Jon. Lecture Notes Series, Institute for Mathematical Sciences, National University of Singapore. 19. 263–304. Configuration Spaces, Braids, and Robotics. 10.1142/9789814291415_0004. Cohen. Frederick R.. Hanbury. Elizabeth. Wong. Yan-Loi. Wu. Jie.
- Book: Magnus, Wilhelm . . 372 . Wilhelm Magnus . Braid groups: A survey . https://doi.org/10.1007%2FBFb0065203 . Proceedings of the Second International Conference on the Theory of Groups . Springer . 1974 . 978-3-540-06845-7 . 465. 10.1007/BFb0065203 .
- Book: Arnold, Vladimir. Vladimir Arnold. Translated by Victor Vassiliev. Vladimir I. Arnold - Collected Works . The cohomology ring of the colored braid group . ru. 5. 227–231. 10.1007/978-3-642-31031-7_18. 0025-567X. 0242196. 1969. 978-3-642-31030-0. 122699084 .
- Campos. Ricardo. Willwacher. Thomas. Thomas Willwacher. 2023. A model for configuration spaces of points. Algebraic & Geometric Topology . 23 . 5 . 2029–2106 . 10.2140/agt.2023.23.2029 . 1604.02043 .
- Idrissi. Najib. 2016-08-29. The Lambrechts–Stanley Model of Configuration Spaces. Inventiones Mathematicae. 216. 1–68. 1608.08054 . 10.1007/s00222-018-0842-9. 2016arXiv160808054I. 102354039.
- Campos. Ricardo. Idrissi. Najib. Lambrechts. Pascal. Willwacher. Thomas. Thomas Willwacher. 2018-02-02. Configuration Spaces of Manifolds with Boundary. 1802.00716. math.AT.
- Farley. Daniel. Sabalka. Lucas. 2005. Discrete Morse theory and graph braid groups. Algebraic & Geometric Topology. 5. 3. 1075–1109. 10.2140/agt.2005.5.1075. math/0410539. 2171804. 119715655.
- Świątkowski. Jacek. 2001. Estimates for homological dimension of configuration spaces of graphs. Colloquium Mathematicum. pl. 89. 1. 69–79. 10.4064/cm89-1-5. 1853416 . free.
- Daniel. Lütgehetmann. Configuration spaces of graphs. Master’s. Free University of Berlin. Berlin. 2014.
- Shvalb. Nir. Shoham. Moshe. Blanc. David. 2005. The configuration space of arachnoid mechanisms. Forum Mathematicum. en. 17. 6. 1033–1042. 10.1515/form.2005.17.6.1033. 121995780.
- Book: Farber, Michael. 2007. Invitation to Topological Robotics. american Mathematical Society.
- Shvalb. Nir. Blanc. David. 2012. Generic singular configurations of linkages. Topology and Its Applications. en. 159. 3. 877–890. 10.1016/j.topol.2011.12.003. free. 1112.2334.
- Bott . Raoul . Raoul Bott. Taubes . Clifford . Clifford Taubes. 1994-10-01 . On the self-linking of knots . . 35 . 10 . 5247–5287 . 10.1063/1.530750 . 0022-2488.
- Fulton . William . William Fulton (mathematician). MacPherson . Robert . Robert MacPherson (mathematician). January 1994 . A Compactification of Configuration Spaces . . 139 . 1 . 183 . 10.2307/2946631 . 2946631 . 0003-486X.
