Compactness axioms: Difference between revisions

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In general topology, the important property of compactness has a number of related properties.

The definitions require some preliminary terminology. A cover of a set X is a family ${\mathcal {U}}=\{U_{\alpha }:\alpha \in A\}$ such that the union $\bigcup _{\alpha \in A}U_{\alpha }$ is equal to X. A subcover is a subfamily which is again a cover ${\mathcal {S}}=\{U_{\alpha }:\alpha \in B\}$ where B is a subset of A. A refinement is a cover ${\mathcal {R}}=\{V_{\beta }:\beta \in B\}$ such that for each β in B there is an α in A such that $V_{\beta }\subseteq U_{\alpha }$ . A cover is finite or countable if the index set is finite or countable. A cover is point finite if each element of X belongs to a finite numbers of sets in the cover. The phrase "open cover" is often used to denote "cover by open sets".

Definitions

We say that a topological space X is

Compact if every cover by open sets has a finite subcover.
A compactum if it is a compact metric space.
Countably compact if every countable cover by open sets has a finite subcover.
Lindelöf if every cover by open sets has a countable subcover.
Sequentially compact if every convergent sequence has a convergent subsequence.
Paracompact if every cover by open sets has an open locally finite refinement.
Metacompact if every cover by open sets has a point finite open refinement.
Orthocompact if every cover by open sets has an interior preserving open refinement.
σ-compact if it is the union of countably many compact subspaces.
Locally compact if every point has a compact neighbourhood.
Strongly locally compact if every point has a neighbourhood with compact closure.
σ-locally compact if it is both σ-compact and locally compact.
Pseudocompact if every continuous real-valued function is bounded.

@@ Line 2: / Line 2: @@
 In [[general topology]], the important property of '''[[compact set|compactness]]''' has a number of related properties.
-The definitions require some preliminary terminology.  A ''cover'' of a set ''X'' is a family <math>\mathcal{U} = \{ U_\alpha : \alpha \in A \}</math> such that the union <math>\bigcup_{\alpha \in A} U_\alpha</math> is equal to ''X''.  A ''subcover'' is a subfamily which is again a cover <math>\mathcal{S} = \{ U_\alpha : \alpha \in B \}</math> where ''B'' is a subset of ''A''.  A ''refinement'' is a cover <math>\mathcal{R} = \{ V_\beta : \beta \in B \}</math> such that for each β in ''B'' there is an α in ''A'' such that <math>V_\beta \subseteq U_\alpha</math>.  A cover is finite or countable if the index set is finite or countable.  The phrase "open cover"is often used to denote "cover by open sets".
+The definitions require some preliminary terminology.  A ''cover'' of a set ''X'' is a family <math>\mathcal{U} = \{ U_\alpha : \alpha \in A \}</math> such that the union <math>\bigcup_{\alpha \in A} U_\alpha</math> is equal to ''X''.  A ''subcover'' is a subfamily which is again a cover <math>\mathcal{S} = \{ U_\alpha : \alpha \in B \}</math> where ''B'' is a subset of ''A''.  A ''refinement'' is a cover <math>\mathcal{R} = \{ V_\beta : \beta \in B \}</math> such that for each β in ''B'' there is an α in ''A'' such that <math>V_\beta \subseteq U_\alpha</math>.  A cover is finite or countable if the index set is finite or countable.  A cover is ''point finite'' if each element of ''X'' belongs to a finite numbers of sets in the cover.  The phrase "open cover" is often used to denote "cover by open sets".
 ==Definitions==

Compactness axioms: Difference between revisions

Revision as of 06:47, 30 December 2008

Definitions

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