Closed set: Difference between revisions

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In mathematics, a set $A\subset X$ , where $(X,O)$ is some topological space, is said to be closed if $X-A=\{x\in X\mid x\notin A\}$ , the complement of $A$ in $X$ , 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

Let X be the open interval (0, 1) with the usual topology induced by the Euclidean distance. Open sets are then of the form
$\bigcup _{\gamma \in \Gamma }(a_{\gamma },b_{\gamma })$
where $0\leq a_{\gamma }\leq b_{\gamma }\leq 1$ and $\Gamma$ is an arbitrary index set (if $a=b$ then the open interval (a, b) is defined to be the empty set). The definition now implies that closed sets are of the form
$\bigcap _{\gamma \in \Gamma }(0,a_{\gamma }]\cup [b_{\gamma },1).$ .
As a more interesting example, consider the function space $C[a,b]$ (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
$\|f\|=\max _{x\in [a,b]}|f(x)|.$
In this topology, the sets
$A={\big \{}f\in C[a,b]\mid \min _{x\in [a,b]}f(x)>0\}$
and
$B={\big \{}f\in C[a,b]\mid \min _{x\in [a,b]}f(x)<0\}$
are open sets while the sets
$C={\big \{}f\in C[a,b]\mid \min _{x\in [a,b]}f(x)\geq 0\}$
and
$D={\big \{}f\in C[a,b]\mid \min _{x\in [a,b]}f(x)\leq 0\}$
are closed (the sets $C$ and $D$ are the closure of the sets $A$ and $B$ respectively).

@@ Line 1: / Line 1: @@
 {{subpages}}
-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]]
+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 ==
-. 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>.
-. 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
+:<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
+:<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
+:<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>
-== See also ==
-[[Topology]]
-[[Analysis]]
-[[Open set]]
-[[Compact set]]

Closed set: Difference between revisions

Latest revision as of 15:26, 6 January 2009

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