Perfect set

{{Short description|Subset that is closed and has no isolated points}}

In general topology, a subset of a topological space is perfect if it is closed and has no isolated points. Equivalently: the set $S$ is perfect if $S=S'$ , where $S'$ denotes the set of all limit points of $S$ , also known as the derived set of $S$ . (Some authors do not consider the empty set to be perfect.{{cite book|last=Jech|first=Thomas|title=Set Theory (The Third Millenium Edition, revised and expanded)|series=Springer Monographs in Mathematics |date=2003|publisher=Springer|isbn=978-3-540-44085-7|page=40|doi=10.1007/3-540-44761-X}})

In a perfect set, every point can be approximated arbitrarily well by other points from the set: given any point of $S$ and any neighborhood of the point, there is another point of $S$ that lies within the neighborhood. Furthermore, any point of the space that can be so approximated by points of $S$ belongs to $S$ .

Note that the term perfect space is also used, incompatibly, to refer to other properties of a topological space, such as being a G_δ space. As another possible source of confusion, also note that having the perfect set property is not the same as being a perfect set.

Examples

Examples of perfect subsets of the real line $\mathbb{R}$ are the empty set, all closed intervals, the real line itself, and the Cantor set. The latter is noteworthy in that it is totally disconnected.

Whether a set is perfect or not (and whether it is closed or not) depends on the surrounding space. For instance, the set $S=[0,1]\cap \Q$ is perfect as a subset of the space $\Q$ but not perfect as a subset of the space $\mathbb{R}$ , since it fails to be closed in the latter.

Connection with other topological properties

Every topological space can be written in a unique way as the disjoint union of a perfect set and a scattered set.Engelking, problem 1.7.10, p. 59{{cite web |url=https://math.stackexchange.com/questions/3856152 |title = Uniqueness of decomposition into perfect set and scattered set - Mathematics Stack Exchange}}

Cantor proved that every closed subset of the real line can be uniquely written as the disjoint union of a perfect set and a countable set. This is also true more generally for all closed subsets of Polish spaces, in which case the theorem is known as the Cantor–Bendixson theorem.

Cantor also showed that every non-empty perfect subset of the real line has cardinality $2^{\aleph_0}$ , the cardinality of the continuum. These results are extended in descriptive set theory as follows:

If X is a complete metric space with no isolated points, then the Cantor space 2^ω can be continuously embedded into X. Thus X has cardinality at least $2^{\aleph_0}$ . If X is a separable, complete metric space with no isolated points, the cardinality of X is exactly $2^{\aleph_0}$ .
If X is a locally compact Hausdorff space with no isolated points, there is an injective function (not necessarily continuous) from Cantor space to X, and so X has cardinality at least $2^{\aleph_0}$ .

Notes

References

{{Cite book

| last1=Engelking

| first1=Ryszard

| author1-link=Ryszard Engelking

| title=General Topology

| publisher=Heldermann Verlag

| location=Berlin

| isbn=3-88538-006-4

| year=1989

}}

{{Citation

| last1=Kechris

| first1=A. S.

| author1-link=Alexander S. Kechris

| title=Classical Descriptive Set Theory

| publisher=Springer-Verlag

| location=Berlin, New York

| isbn=3540943749

| year=1995

}}

{{Citation

| last1=Levy

| first1=A.

| author1-link=Azriel Levy

| title=Basic Set Theory

| publisher=Springer-Verlag

| location=Berlin, New York

| year=1979

}}

{{Citation

| editor1-last=Pearl

| editor1-first=Elliott

| title=Open problems in topology. II

| publisher=Elsevier

| isbn=978-0-444-52208-5|mr=2367385

| year=2007

}}

Category:Topology

Category:Properties of topological spaces

Perfect set

Examples

Connection with other topological properties

See also

Notes

References