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In [[mathematics]], a set <math>A \subset X</math>, where <math>(X,O)</math> is some [[topological space]], is said to be closed if <math>X-A=\{x \in X \mid x \notin A\}</math>, the complement of <math>A</math> in <math>X</math>, is an [[open set]]
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In [[mathematics]], a set <math>A \subset X</math>, where <math>(X,O)</math> is some [[topological space]], is said to be closed if <math>X-A=\{x \in X \mid x \notin A\}</math>, the [[complement (set theory)|complement]] of <math>A</math> in <math>X</math>, is an [[open set]].  The [[empty set]] and the set ''X'' itself are always closed sets.  The finite [[union]] and arbitrary [[intersection]] of closed sets are again closed.


== Examples ==
== Examples ==
1. Let <math>X=(0,1)</math> with the usual topology induced by the Euclidean distance. Open sets are then of the form <math>\cup_{\gamma \in \Gamma} (a_{\gamma},b_{\gamma})</math> where <math>0\leq a_{\gamma}\leq b_{\gamma} \leq 1</math> and <math>\Gamma</math> is an arbitrary index set (if <math>a=b</math> then define <math>(a,b)=\emptyset</math>). Then closed sets by definition are of the form <math>\cap_{\gamma \in \Gamma} (0,a_{\gamma}]\cup [b_{\gamma},1)</math>.
2. As a more interesting example, consider the function space <math>C[a,b]</math>  consisting of all real valued [[continuous function|continuous functions]] on the interval [a,b] (a<b) endowed with a topology induced by the distance <math>d(f,g)=\mathop{\max}_{x \in [a,b]}|f(x)-g(x)|</math>. In this topology, the sets
<center><math>A=\{ g \in C[a,b] \mid  \mathop{\min}_{x \in [a,b]}g(x) > 0 \}</math></center>


<ol>
<li>
Let ''X'' be the open interval (0, 1) with the usual topology induced by the Euclidean distance. Open sets are then of the form
:<math>\bigcup_{\gamma \in \Gamma} (a_{\gamma},b_{\gamma})</math>
where <math>0\leq a_{\gamma}\leq b_{\gamma} \leq 1</math> and <math>\Gamma</math> is an arbitrary index set (if <math>a=b</math> then the open interval (''a'', ''b'') is defined to be the empty set). The definition now implies that closed sets are of the form
:<math>\bigcap_{\gamma \in \Gamma} (0,a_{\gamma}]\cup [b_{\gamma},1). </math>.
</li>
<li>
As a more interesting example, consider the function space <math>C[a,b]</math> (with ''a'' < ''b''). This space consists of all real-valued [[continuous function]]s on the closed interval [''a'', ''b''] and is endowed with the topology induced by the [[norm (mathematics)|norm]]
:<math>\|f\| = \max_{x \in [a,b]} |f(x)|. </math>
In this topology, the sets
:<math> A = \big\{ f \in C[a,b] \mid \min_{x \in [a,b]} f(x) > 0 \} </math>
and  
and  
 
:<math> B = \big\{ f \in C[a,b] \mid \min_{x \in [a,b]} f(x) < 0 \} </math>
<center><math>B=\{ g \in C[a,b] \mid \mathop{\min}_{x \in [a,b]}g(x) < 0\}</math></center>
 
are open sets while the sets  
are open sets while the sets  
 
:<math> C = \big\{ f \in C[a,b] \mid \min_{x \in [a,b]} f(x) \ge 0 \} </math>
<center><math>C=\{ g \in C[a,b] \mid \mathop{\min}_{x \in [a,b]}g(x) \geq  0\}=C[a,b]-B</math></center>
 
and  
and  
 
:<math> D = \big\{ f \in C[a,b] \mid \min_{x \in [a,b]} f(x) \le 0 \} </math>
<center><math>D=\{ g \in C[a,b] \mid \mathop{\min}_{x \in [a,b]}g(x) \leq 0\}=C[a,b]-A</math></center>
are closed (the sets <math>C</math> and <math>D</math> are the [[closure (topology)|closure]] of the sets <math>A</math> and <math>B</math> respectively).
 
</li>
are closed (the sets <math>C</math> and <math>D</math> are, respectively, the [[Closure_mathematical|closures]] of the sets <math>A</math> and <math>B</math>).
</ol>[[Category:Suggestion Bot Tag]]
 
== See also ==
[[Topology]]
 
[[Analysis]]
 
[[Open set]]
 
[[Category:Mathematics Workgroup]]
[[Category:CZ Live]]

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In mathematics, a set , where is some topological space, is said to be closed if , the complement of in , is an open set. The empty set and the set X itself are always closed sets. The finite union and arbitrary intersection of closed sets are again closed.

Examples

  1. Let X be the open interval (0, 1) with the usual topology induced by the Euclidean distance. Open sets are then of the form
    where and is an arbitrary index set (if then the open interval (a, b) is defined to be the empty set). The definition now implies that closed sets are of the form
    .
  2. As a more interesting example, consider the function space (with a < b). This space consists of all real-valued continuous functions on the closed interval [a, b] and is endowed with the topology induced by the norm
    In this topology, the sets
    and
    are open sets while the sets
    and
    are closed (the sets and are the closure of the sets and respectively).