Fixed-point property: Difference between revisions
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==Definition== | ==Definition== | ||
A [[topological space]] is said to have the '''fixed-point property''' if every [[continuous map]] from the topological space to itself | A [[topological space]] is said to have the '''fixed-point property''' if every [[continuous map]] (''not necessarily a self-homeomorphism'') from the topological space to itself has a fixed point. | ||
==Relation with other properties== | ==Relation with other properties== | ||
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* [[Acyclic space|acyclic]] [[compact space|compact]] [[polyhedron]] (nonempty) | * [[Acyclic space|acyclic]] [[compact space|compact]] [[polyhedron]] (nonempty) | ||
* [[Rationally acyclic space|rationally acyclic]] [[compact space|compact]] [[polyhedron]] (nonempty) | * [[Rationally acyclic space|rationally acyclic]] [[compact space|compact]] [[polyhedron]] (nonempty) | ||
==Examples== | |||
===Manifolds without boundary=== | |||
{| class="sortable" border="1" | |||
! Manifold or family of manifolds !! Dimension in terms of parameter !! Does it satisfy the fixed-point property? !! Proof/explanation | |||
|- | |||
| [[sphere]] <math>S^n,n \ge 1</math> || <math>n</math> || No || The antipodal map is a fixed-point-free self-map (in fact, it's a self-homeomorphism without fixed points). | |||
|- | |||
| [[real projective space]] <math>\mathbb{P}^n(\R), n \ge 1</math> || <math>n</math> || Yes if <math>n</math> is even, No if <math>n = 1,3</math>, what happens for other odd <math>n</math>? || For <math>n</math> even, follows from [[rationally acyclic compact polyhedron has fixed-point property]]. For <math>n = 1,3</math>, follows from the fact that it is a [[Lie group]] and thus multiplication by a non-identity element is a continuous self-map without fixed points. | |||
|- | |||
| [[complex projective space]] <math>\mathbb{P}^n(\mathbb{C}), n \ge 1</math> || <math>2n</math> || Yes if <math>n</math> is even, what happens for odd <math>n</math>? || {{fillin}} | |||
|- | |||
| [[compact orientable surface]] of genus <math>g \ge 0</math> || 2 || No if <math>g = 0,1</math>, what happens for higher <math>g</math>? || | |||
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===Manifolds with boundary=== | |||
==Facts== | ==Facts== | ||
Revision as of 17:45, 27 July 2011
This article defines a property of topological spaces: a property that can be evaluated to true/false for any topological space|View a complete list of properties of topological spaces
Definition
A topological space is said to have the fixed-point property if every continuous map (not necessarily a self-homeomorphism) from the topological space to itself has a fixed point.
Relation with other properties
Stronger properties
- acyclic compact polyhedron (nonempty)
- rationally acyclic compact polyhedron (nonempty)
Examples
Manifolds without boundary
| Manifold or family of manifolds | Dimension in terms of parameter | Does it satisfy the fixed-point property? | Proof/explanation |
|---|---|---|---|
| sphere | No | The antipodal map is a fixed-point-free self-map (in fact, it's a self-homeomorphism without fixed points). | |
| real projective space | Yes if is even, No if , what happens for other odd ? | For even, follows from rationally acyclic compact polyhedron has fixed-point property. For , follows from the fact that it is a Lie group and thus multiplication by a non-identity element is a continuous self-map without fixed points. | |
| complex projective space | Yes if is even, what happens for odd ? | Fill this in later | |
| compact orientable surface of genus | 2 | No if , what happens for higher ? |
|}
Manifolds with boundary
Facts
In general, we combine the Lefschetz fixed-point theorem with the structure of the cohomology ring of the space to determine whether or not it has the fixed-point property. For instance, we can show that complex projective space in even dimensions has the fixed-point property, by combining the Lefschetz fixed-point theorem with the fact that the trace on the homology is where is the trace on the second homology.
Metaproperties
Retract-hereditariness
This property of topological spaces is hereditary on retracts, viz if a space has the property, so does any retract of it
View all retract-hereditary properties of topological spaces
Every retract of a space with the fixed-point property also has the fixed-point property. Further information: fixed-point property is retract-hereditary