Fixed-point property is retract-hereditary: Difference between revisions

Latest revision as of 11:22, 8 August 2008

This article gives the statement, and possibly proof, of a topological space property (i.e., fixed-point property) satisfying a topological space metaproperty (i.e., retract-hereditary property of topological spaces)
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Statement

Property-theoretic statement

The property of topological spaces called the fixed-point property is a retract-hereditary property of topological spaces.

Verbal statement

Any retract of a topological space having the fixed-point property, also has the fixed-point property.

Definitions used

Fixed-point property

Retract

Subspace topology

Proof

Proof outline

Consider a self-map of the retract
Compose with the retraction to get a self-map of the whole space
Find a fixed point, and observe that it must be a fixed point of the original self-map

Proof details

Given: A topological space $X$ satisfying the fixed-point property, a retraction $r : X \to A$ where $A \subset X$ and $r (a) = a$ for all $a \in A$

To prove: $A$ satisfies the fixed-point property

Proof: Let $i$ denote the inclusion of $A$ in $X$ .

Consider any continuous map $f : A \to A$ . We need to show that $f$ has a fixed point in $A$ . Consider the composition $g = i \circ f \circ r$ . This is a map from $X$ to $X$ that first retracts to $A$ , then applies $f$ , and then views the resulting point of $A$ as a point in $X$ . $g$ is a composite of continuous maps, so $g$ is continuous. Since $X$ has the fixed-point property, there exists $x \in X$ such that $g (x) = x$ .

But by construction, $g (x)$ is actually inside $A$ , so in fact $x \in A$ . But if $x \in A$ , $r (x) = x$ , so we conclude that $x = g (x) = f (r (x)) = f (x)$ . Thus, $x \in A$ is a fixed point of $f$ , completing the proof.

@@ Line 1: / Line 1: @@
-{{topospace metaproperty satisfaction}}
+{{topospace metaproperty satisfaction|
+property = fixed-point property|
+metaproperty = retract-hereditary property of topological spaces}}
 ==Statement==
@@ Line 26: / Line 28: @@
 * Compose with the retraction to get a self-map of the whole space
 * Find a fixed point, and observe that it must be a fixed point of the original self-map
+===Proof details===
+'''Given''': A topological space <math>X</math> satisfying the fixed-point property, a retraction <math>r:X \to A</math> where <math>A \subset X</math> and <math>r(a) = a</math> for all <math>a \in A</math>
+'''To prove''': <math>A</math> satisfies the fixed-point property
+'''Proof''': Let <math>i</math> denote the inclusion of <math>A</math> in <math>X</math>.
+Consider any continuous map <math>f:A \to A</math>. We need to show that <math>f</math> has a fixed point in <math>A</math>. Consider the composition <math>g = i \circ f \circ r</math>. This is a map from <math>X</math> to <math>X</math> that first retracts to <math>A</math>, then applies <math>f</math>, and then views the resulting point of <math>A</math> as a point in <math>X</math>. <math>g</math> is a composite of continuous maps, so <math>g</math> is continuous. Since <math>X</math> has the fixed-point property, there exists <math>x \in X</math> such that <math>g(x) = x</math>.
+But by construction, <math>g(x)</math> is actually inside <math>A</math>, so in fact <math>x \in A</math>. But if <math>x \in A</math>, <math>r(x) = x</math>, so we conclude that <math>x = g(x) = f(r(x)) = f(x)</math>. Thus, <math>x \in A</math> is a fixed point of <math>f</math>, completing the proof.