Contractibility is product-closed: Difference between revisions

Latest revision as of 11:21, 8 August 2008

This article gives the statement, and possibly proof, of a topological space property (i.e., contractible space) satisfying a topological space metaproperty (i.e., product-closed property of topological spaces)
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Statement

Property-theoretic statement

The property of topological spaces of being a contractible space, satisfies the metaproperty of topological spaces of being product-closed.

Statement with symbols

Let $X_{i}$ , $i \in I$ , be an indexed family of topological spaces. Then the product space, endowed with the product topology, is contractible.

Proof

Key idea (for two spaces)

Suppose $F : X \times I \to X$ and $G : Y \times I \to Y$ are contracting homotopies for $X$ and $Y$ . Then the map $F \times G$ defined as:

$(F \times G) (x, y, t) = (F (x, t), G (y, t))$

is a contracting homotopy for $X \times Y$ .

Thus $X \times Y$ is contractible.

Generic proof (for an arbitrary family)

Given: An indexing set $I$ , a collection ${X_{i}}_{i \in I}$ of contractible spaces. $X$ is the product of the $X_{i}$ s, endowed with the product topology

To prove: $X$ is a contractible space

Proof: Since each $X_{i}$ is contractible, we can choose, for each $X_{i}$ , a point $p_{i} \in X_{i}$ , and a contracting homotopy $F_{i} : X_{i} \times [0, 1] \to X_{i}$ , with the property that:

$F_{i} (a, 0) = a \forall a \in X_{i}, F_{i} (a, 1) = p_{i} \forall a \in X_{i}$

Now consider the point $p \in X$ whose $i^{t h}$ coordinate is $p_{i}$ for each $i \in I$ . We denote:

$x = (x_{i})_{i \in I}$

to be a point whose $i^{t h}$ coordinate is $x_{i}$ . Then, define a homotopy:

$F : X \times [0, 1] \to X$

given by:

$F (x, t) = (F_{i} (x_{i}, t))_{i \in I}$

In other words, the homotopy acts as $F_{i}$ in each coordinate. We observe that:

Since $F_{i} (x_{i}, 0) = x_{i}$ for each $i$ , $F (x, 0) = x$
Since $F_{i} (x_{i}, 1) = p_{i}$ for each $i$ , $F (x, 1) = p$
$F$ is a continuous map: Fill this in later

Thus, $F$ is a contracting homotopy on $X$ , so $X$ is contractible.

@@ Line 1: / Line 1: @@
+{{topospace metaproperty satisfaction|
+property = contractible space|
+metaproperty = product-closed property of topological spaces}}
 ==Statement==
-Let <math>X</math> and <math>Y</math> be [[contractible space]]s. Then the product space <math>X \times Y</math> is contractible.
+===Property-theoretic statement===
+The [[property of topological spaces]] of being a [[contractible space]], satisfies the [[metaproperty of topological spaces]] of being [[product-closed property of topological spaces|product-closed]].
+===Statement with symbols===
+Let <math>X_i</math>, <math>i \in I</math>, be an indexed family of topological spaces. Then the product space, endowed with the [[product topology]], is contractible.
 ==Proof==
-===Key idea===
+===Key idea (for two spaces)===
 Suppose <math>F: X \times I \to X</math> and <math>G:Y \times I \to Y</math> are contracting homotopies for <math>X</math> and <math>Y</math>. Then the map <math>F \times G</math> defined as:
@@ Line 14: / Line 24: @@
 Thus <math>X \times Y</math> is contractible.
+===Generic proof (for an arbitrary family)===
+'''Given''': An indexing set <math>I</math>, a collection <math>\{ X_i \}_{i \in I}</math> of [[contractible space]]s. <math>X</math> is the product of the <math>X_i</math>s, endowed with the [[product topology]]
+'''To prove''': <math>X</math> is a contractible space
+'''Proof''': Since each <math>X_i</math> is contractible, we can choose, for each <math>X_i</math>, a point <math>p_i \in X_i</math>, and a contracting homotopy <math>F_i: X_i \times [0,1] \to X_i</math>, with the property that:
+<math>F_i(a,0) = a \ \forall \ a \in X_i, F_i(a,1) = p_i \ \forall \ a \in X_i</math>
+Now consider the point <math>p \in X</math> whose <math>i^{th}</math> coordinate is <math>p_i</math> for each <math>i \in I</math>. We denote:
+<math>x = (x_i)_{i \in I}</math>
+to be a point whose <math>i^{th}</math> coordinate is <math>x_i</math>. Then, define a homotopy:
+<math>F: X \times [0,1] \to X</math>
+given by:
+<math>F(x,t) = (F_i(x_i,t))_{i \in I}</math>
+In other words, the homotopy acts as <math>F_i</math> in each coordinate. We observe that:
+* Since <math>F_i(x_i,0) = x_i</math> for each <math>i</math>, <math>F(x,0) = x</math>
+* Since <math>F_i(x_i,1) = p_i</math> for each <math>i</math>, <math>F(x,1) = p</math>
+* <math>F</math> is a continuous map: {{fillin}}
+Thus, <math>F</math> is a contracting homotopy on <math>X</math>, so <math>X</math> is contractible.