Second-countable implies Lindelof: Difference between revisions

Latest revision as of 21:43, 20 July 2008

This article gives the statement and possibly, proof, of an implication relation between two topological space properties. That is, it states that every topological space satisfying the first topological space property must also satisfy the second topological space property
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Statement

Property-theoretic statement

The property of topological spaces of being a second-countable space implies, or is stronger than, the property of being a Lindelof space.

Verbal statement

Any second-countable space is Lindelof.

Definitions used

Second-countable space

Further information: Second-countable space

A topological space is termed second-countable if it admits a countable basis.

Lindelof space

Further information: Lindelof space

A topological space is termed Lindelof if every open cover of the space has a countable subcover.

Proof

Given: A second-countable space $X$ with countable basis $\{B_{n}\}$

To prove: If $\{U_{i}\}_{i\in I}$ form an open cover of $X$ , there exists a countable subcover of $X$ among the $\{U_{i}\}$ s

Proof: For each basis element $B_{n}$ , let $V_{n}$ be any $U_{i}$ containing $B_{n}$ , if such a $U_{i}$ exists, otherwise, pick nothing. This gives a (at most) countable subcollection $\{V_{n}\}$ of the collection $\{U_{i}\}$ . We want to show that this subcollection covers $X$ .

Suppose there exists $x\in X$ , that does not belong to any $V_{n}$ . Then, since the entire collection of $U_{j}$ cover $X$ , we can find some $j\in I$ such that $x\in U_{j}$ . Further, there exists some $n$ such that $x\in B_{n}\subset U_{j}$ . Now, since $B_{n}$ is contained in at least one of the $U_{i}$ s, there should exist an element $V_{n}$ . But such an element would also contain $x$ , contradicting the claim that $x$ does not belong to any $V_{n}$ .

References

Textbook references

Topology (2nd edition) by James R. Munkres, ^{More info}, Page 191, Theorem 30.3(a), Chapter 4, Section 30

@@ Line 9: / Line 9: @@
 ===Verbal statement===
-Any [[second-countable basis]] is [[Lindelof space|Lindelof]].
+Any [[second-countable space]] is [[Lindelof space|Lindelof]].
 ==Definitions used==
@@ Line 29: / Line 29: @@
 '''To prove''': If <math>\{ U_i \}_{i \in I}</math> form an open cover of <math>X</math>, there exists a countable subcover of <math>X</math> among the <math>\{ U_i \}</math>s
-'''Proof''': For each basis element <math>B_n</math>, pick a <math>U_i</math> containing <math>B_n</math>, if such a <math>U_i</math> exists, otherwise, pick nothing. This gives a (at most) countable subcollection of the collection <math>\{ U_i \}</math>. We want to show that this subcollection covers <math>X</math>.
+'''Proof''': For each basis element <math>B_n</math>, let <math>V_n</math> be any <math>U_i</math> containing <math>B_n</math>, if such a <math>U_i</math> exists, otherwise, pick nothing. This gives a (at most) countable subcollection <math>\{ V_n \}</math> of the collection <math>\{ U_i \}</math>. We want to show that this subcollection covers <math>X</math>.
-Suppose there exists <math>x \in X</math>, that does not belong to any <math>U_i</math> in the subcollection. Then, since the entire collection of <math>U_j</math> cover <math>X</math>, we can find some <math>j \in I</math> such that <math>x \in U_j</math>. Further, there exists some <math>n</math> such that <math>x \in B_n \subset U_j</math>. Now, since <math>B_n</math> is contained in at least one of the <math>U_i</math>s, there should have been an element in the collection <math>\{ U_i \}</math> associated to <math>B_n</math>. But such an element would also contain <math>x</math>, contradicting the claim that <math>x</math> does not belong to any <math>U_i</math> in the subcollection.
+Suppose there exists <math>x \in X</math>, that does not belong to any <math>V_n</math>. Then, since the entire collection of <math>U_j</math> cover <math>X</math>, we can find some <math>j \in I</math> such that <math>x \in U_j</math>. Further, there exists some <math>n</math> such that <math>x \in B_n \subset U_j</math>. Now, since <math>B_n</math> is contained in at least one of the <math>U_i</math>s, there should exist an element <math>V_n</math>. But such an element would also contain <math>x</math>, contradicting the claim that <math>x</math> does not belong to any <math>V_n</math>.
+==References==
+===Textbook references===
+* {{booklink-proved|Munkres}}, Page 191, Theorem 30.3(a), Chapter 4, Section 30