Topological Space: Difference between revisions
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imported>Giovanni Antonio DiMatteo (New page: The ==The Open and Closed Set Axioms== Let <math>X</math> be a set, and <math>\tau</math> a collection of subsets of <math>X</math> (which will be called the ''open subsets'' of <math>...) |
imported>Giovanni Antonio DiMatteo No edit summary |
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Revision as of 14:25, 2 December 2007
Topological spaces are
The Open and Closed Set Axioms
Let be a set, and a collection of subsets of (which will be called the open subsets of with respect to the topology ) verifying the following axioms:
- Any finite intersection of sets in is again in ; i.e., if , then .
- Any union of a family of sets is in ; i.e., .
When these axioms are satisfied, we say that is a topological space of open sets .
The Neighborhood Axioms
One can phrase a set of axioms for the definition of a topological space by defining the neighborhoods of points in that space. This is particularly useful when one considers topologies on topological abelian groups and topological rings by subgroups or ideals, respectively, because knowing the neighborhoods of any point is equivalent to knowing the neighborhoods of .
Examples
- Metric Spaces