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In [[mathematics]], particularly [[topology]], the '''tube lemma''' is a useful tool in order to prove that the finite product of [[compact space]]s is compact. It is in general, a concept of [[point-set topology]].
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==Tube lemma==
 
Before giving the lemma, one notes the following terminology:
 
* If ''X'' and ''Y'' are [[topological spaces]] and ''X''&nbsp;&times;&nbsp;''Y'' is the product space, a slice in ''X''&nbsp;&times;&nbsp;''Y'' is a set of the form {''x''}&nbsp;&times;&nbsp;''Y'' for ''x''&nbsp;∈&nbsp;''X''
 
* A tube in ''X''&nbsp;&times;&nbsp;''Y'' is just a [[Base (topology)|basis element]], ''K''&nbsp;&times;&nbsp;''Y'', in ''X''&nbsp;&times;&nbsp;''Y'' containing a slice in ''X''&nbsp;&times;&nbsp;''Y''
 
'''Tube Lemma:''' Let ''X'' and ''Y'' be topological spaces with ''Y'' compact, and consider the [[Product topology|product space]] ''X''&nbsp;&times;&nbsp;''Y''. If ''N'' is an open set containing a slice in ''X''&nbsp;&times;&nbsp;''Y'', then there exists a tube in ''X''&nbsp;&times;&nbsp;''Y'' containing this slice and contained in ''N''.
 
Using the concept of [[closed map]]s, this can be rephrased concisely as follows: if ''X'' is any topological space and ''Y'' a compact space, then the projection map ''X''&nbsp;&times;&nbsp;''Y''&nbsp;→&nbsp;''X'' is closed.
 
'''Generalized Tube Lemma:''' Let ''X'' and ''Y'' be topological spaces and consider the product space ''X''&nbsp;&times;&nbsp;''Y''. Let ''A'' be a compact subset of ''X'' and ''B'' be a compact subset of ''Y''. If ''N'' is an open set containing ''A''&nbsp;&times;&nbsp;''B'', then there exists ''U'' open in ''X'' and ''V'' open in ''Y'' such that <math>A\times B\subset U\times V\subset N</math>.
 
==Examples and properties==
 
1. Consider ''R'' × ''R'' in the product topology, that is the [[Euclidean plane]], and the open set ''N'' = { (''x'', ''y'') : |''x''·''y''| &lt; 1 }.  The open set ''N'' contains {0} × ''R'', but contains no tube, so in this case the tube lemma fails.  Indeed, if ''W'' × ''R'' is a tube containing {0} × ''R'' and contained in ''N'', ''W'' must be a subset of (−1/''x'', +1/''x'') for all positive integers ''x'' which means ''W'' = {0} contradicting the fact that ''W'' is open in ''R'' (because ''W'' × ''R'' is a tube). This shows that the compactness assumption is essential.
 
2. The tube lemma can be used to prove that if ''X'' and ''Y'' are compact topological spaces, then ''X''&nbsp;&times;&nbsp;''Y'' is compact as follows:
 
Let {''G''<sub>''a''</sub>} be an open cover of ''X''&nbsp;&times;&nbsp;''Y''; for each ''x'' belonging to ''X'', cover the slice {''x''}&nbsp;&times;&nbsp;''Y'' by finitely many elements of {''G''<sub>''a''</sub>} (this is possible since {''x''}&nbsp;&times;&nbsp;''Y'' is compact being [[homeomorphism|homeomorphic]] to ''Y''). Call the union of these finitely many elements ''N''<sub>''x''</sub>. By the tube lemma, there is an open set of the form ''W''<sub>x</sub>&nbsp;&times;&nbsp;''Y'' containing {''x''}&nbsp;&times;&nbsp;''Y'' and contained in ''N''<sub>''x''</sub>. The collection of all ''W''<sub>''x''</sub> for ''x'' belonging to ''X'' is an open cover of ''X'' and hence has a finite subcover ''W''<sub>''x''<sub>1</sub></sub> &nbsp;∪&nbsp;...&nbsp;∪&nbsp;''W''<sub>''x''<sub>''n''</sub></sub>. Then for each ''x''<sub>''i''</sub>, ''W''<sub>''x''<sub>''i''</sub></sub>&nbsp;&times;&nbsp;''Y'' is contained in ''N''<sub>''x''<sub>''i''</sub></sub>. Using the fact that each ''N''<sub>''x''<sub>''i''</sub></sub> is the finite union of elements of ''G''<sub>''a''</sub> and that the finite collection (''W''<sub>''x''<sub>1</sub></sub>&nbsp;&times;&nbsp;''Y'')&nbsp;∪&nbsp;...&nbsp;∪&nbsp;(''W''<sub>''x''<sub>''n''</sub></sub>&nbsp;&times;&nbsp;''Y'') covers ''X''&nbsp;&times;&nbsp;''Y'', the collection ''N''<sub>''x''<sub>1</sub></sub>&nbsp;∪&nbsp;...&nbsp;∪&nbsp;''N''<sub>''x''<sub>''n''</sub></sub> is a finite subcover of ''X''&nbsp;&times;&nbsp;''Y''.
 
3. By example 2 and induction, one can show that the finite product of compact spaces is compact.
 
4. The tube lemma cannot be used to prove the [[Tychonoff theorem]], which generalizes the above to infinite products.
 
==Proof==
The tube lemma follows from the generalized tube lemma by taking <math>A=\{x\}</math> and <math>B=Y</math>. It therefore suffices to prove the generalized tube lemma. By the definition of the product topology, for each <math>(a,b)\in A\times B</math> there are open sets <math>U_{a,b}\subset X</math> and <math>V_{a,b}\subset Y</math> such that <math>(a,b)\in U_{a,b}\times V_{a,b}\subset N</math>. Fix some <math>a\in A</math>. Then <math>(V_{a,b}:b\in B)</math> is an open cover of <math>B</math>. Since <math>B</math> is compact, this cover has a finite subcover; namely, there is a finite <math>B_0(a)\subset B</math> such that <math>V'_{a}:=\bigcup_{b\in B_0(a)} V_{a,b}\supset B</math>. Set <math>U'_a:=\bigcap_{b\in B_0(a)} U_{a,b}</math>. Since <math>B_0(a)</math> is finite, <math>U'_a</math> is open. Also <math>V'_{a}</math> is open. Moreover, the construction of <math>U'_a</math> and <math>V'_a</math> implies that <math>\{a\}\times B\subset U'_a\times V'_a\subset N</math>. We now essentially repeat the argument to drop the dependence on <math>a</math>. Let <math>A_0\subset A</math> be a finite subset such that <math>U'':=\bigcup_{a\in A_0}U'_a\supset A</math> and set <math>V'':=\bigcap_{a\in A_0}V'_a</math>. It then follows by the above reasoning that <math>A\times B\subset U''\times V''\subset N</math> and <math>U''\subset X</math> and <math>V''\subset Y</math> are open, which completes the proof.
 
==See also==
 
*[[Tychonoff theorem]]
*[[Compact space]]
*[[Product topology]]
 
==References==
 
* {{cite book
| author = [[James Munkres]]
| year = 1999
| title = Topology
| edition = 2nd edition
| publisher = [[Prentice Hall]]
| isbn = 0-13-181629-2
}}
 
[[Category:Topology]]
[[Category:Lemmas]]
[[Category:Articles containing proofs]]

Latest revision as of 19:41, 12 March 2014

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