- K-topology
In
mathematics , particularlytopology , the K-topology is a topology that one can impose on the set of all real numbers which has some interesting properties. Relative to the set of all real numbers carrying thestandard topology , the set "K" = {"1/n" | "n is anatural number "} is not closed since it doesn’t contain its (only) limit point 0. Relative to the K-topology however, the set K is automatically decreed to be closed by adding ‘more’ basis elements to the standard topology on R. Basically, the K-topology on R is strictly finer than the standard topology on R. It is mostly useful for counterexamples in basic topology.Formal definition
Let R be the set of all real numbers and let "K" = {"1/n" | "n is a natural number"}. Generate a topology on R by taking as
basis all open intervals ("a", "b") and all sets of the form ("a", "b") – "K" (the set of all elements in ("a", "b") that are not in "K"). The topology generated is known as the K-topology on R.Note that: The sets described in the definition do form a basis (they satisfy the conditions to be a basis).
Properties and examples
Throughout this section, "T" will denote the K-topology and ("R", "T") will denote the set of all real numbers with the K-topology as a
topological space .1. The topology "T" on R is strictly finer than the standard topology on R but not comparable with the
lower limit topology on R2. From the previous example, it follows that ("R", "T") is not compact
3. ("R", "T") is Hausdorff but not regular. The fact that it is Hausdorff follows from the first property. It is not regular since the closed set K and the point {0} have no disjoint neighbourhoods about them
4. Suprisingly enough, ("R", "T") is a connected topological space. However, ("R", "T") is not path connected; it has precisely two path components: (−∞, 0] and (0, +∞)
5. Note also that ("R", "T") is not locally path connected (since its path components are not equal to its components). It is also not locally connected at {0} but it is locally connected everywhere else
6. The closed interval [0,1] is not compact as a subspace of ("R", "T") since it is not even
limit point compact ("K" is an infinite subspace of [0,1] that has no limit point in [0,1] )7. In fact, no subspace of "(R, T)" containing "K" can be compact. If "A" were a subspace of "(R, T)" containing "K", "K" would have no limit point in "A" so that "A" can not be limit point compact. Therefore, "A" cannot be compact
8. The
quotient space of ("R", "T") obtained by collapsing "K" to a point is not Hausdorff; see example 3.ee also
*
Lower limit topology
*Natural topology
*Sequence
*Locally connected space
*Connected space References
* cite book
author =James Munkres
year = 1999
title = Topology
edition = 2nd edition
publisher =Prentice Hall
id = ISBN 0-13-181629-2
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