Difference between revisions of "Baire space"
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| − | Any space in which the intersection of any countable family of dense open subsets is dense. An open set of a Baire space is itself a Baire space. By the [[Baire theorem|Baire category theorem]], any complete metric space | + | Any space in which the intersection of any countable family of dense open subsets is dense. An open set of a Baire space is itself a Baire space. By the [[Baire theorem|Baire category theorem]], any [[Complete metric space|complete metric space]] is a Baire space. Another class of Baire spaces are [[Locally compact space|locally compact]] [[Hausdorff space|Hausdorff spaces]]. |
| − | is a Baire space. Another class of Baire spaces are locally compact Hausdorff spaces. | ||
The name is also used for the metric space consisting of infinite sequences $\{n_i\}=\{n_1,n_2,\dotsc\}$ of natural numbers, with the distance given by the following formula: | The name is also used for the metric space consisting of infinite sequences $\{n_i\}=\{n_1,n_2,\dotsc\}$ of natural numbers, with the distance given by the following formula: | ||
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\rho(\{n_i\},\{m_i\}) = \frac1{k_0}\, . | \rho(\{n_i\},\{m_i\}) = \frac1{k_0}\, . | ||
\] | \] | ||
| − | where $k_0$ is the first natural number $k$ for which $n_k\neq m_k$. Such metric is complete and the space is separable and zero-dimensional, | + | where $k_0$ is the first natural number $k$ for which $n_k\neq m_k$. Such metric is complete and the space is [[Separable space|separable]] and [[Dimension|zero-dimensional]], [[Totally-disconnected space|totally disconnected]] and with no isolated points. Observe that the Baire space is the [[Topological product|topological product]] of countably many copies of the natural numbers $\mathbb N$ endowed with the [[Discrete topology|discrete topology]]. Moreover it is homeomorphic to the irrational numbers endowed with the topology of subset of $\mathbb R$. Any zero-dimensional separable metric space of dimension zero can be embedded in the Baire space. |
| − | totally disconnected and with no isolated points. | ||
| − | Observe that the Baire space is the topological product of countably many | ||
| − | copies of the natural numbers $\mathbb N$ endowed with the discrete topology. Moreover it is homeomorphic to the irrational numbers endowed with the topology of subset of $\mathbb R$. Any zero-dimensional separable metric space of dimension zero can be embedded in the Baire space. | ||
====Comments==== | ====Comments==== | ||
Revision as of 15:43, 8 August 2012
2020 Mathematics Subject Classification: Primary: 54A05 [MSN][ZBL]
Any space in which the intersection of any countable family of dense open subsets is dense. An open set of a Baire space is itself a Baire space. By the Baire category theorem, any complete metric space is a Baire space. Another class of Baire spaces are locally compact Hausdorff spaces.
The name is also used for the metric space consisting of infinite sequences $\{n_i\}=\{n_1,n_2,\dotsc\}$ of natural numbers, with the distance given by the following formula: \[ \rho(\{n_i\},\{m_i\}) = \frac1{k_0}\, . \] where $k_0$ is the first natural number $k$ for which $n_k\neq m_k$. Such metric is complete and the space is separable and zero-dimensional, totally disconnected and with no isolated points. Observe that the Baire space is the topological product of countably many copies of the natural numbers $\mathbb N$ endowed with the discrete topology. Moreover it is homeomorphic to the irrational numbers endowed with the topology of subset of $\mathbb R$. Any zero-dimensional separable metric space of dimension zero can be embedded in the Baire space.
Comments
By the Baire category theorem the latter space is a Baire space in the sense of the first definition.
References
| [Kec] | A. S. Kechris, "Classical Descriptive Set Theory", Springer (1994) |
| [Kel] | J.L. Kelley, "General topology" , v. Nostrand (1955) |
| [Ox] | J.C. Oxtoby, "Measure and category" , Springer (1971) |
Baire space. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Baire_space&oldid=27436