Difference between revisions of "Paracompactness criteria"
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| − | + | The following statements are equivalent for an arbitrary completely-regular Hausdorff space $ X $( | |
| + | cf. [[Completely-regular space|Completely-regular space]]; [[Hausdorff space|Hausdorff space]]). | ||
| − | + | 1) $ X $ | |
| + | is paracompact. | ||
| − | + | 2) Each open covering of $ X $ | |
| + | can be refined to a locally finite open covering. | ||
| − | + | 3) Each open covering of $ X $ | |
| + | can be refined to a $ \sigma $- | ||
| + | locally finite open covering, i.e. an open covering decomposing into a countable collection of locally finite families of sets in $ X $. | ||
| − | + | 4) Each open covering of $ X $ | |
| + | can be refined to a locally finite covering (about the structure of the elements of which nothing is assumed). | ||
| − | + | 5) For any open covering $ \gamma $ | |
| + | of $ X $ | ||
| + | there exists an open covering which is a star refinement of $ \gamma $. | ||
| − | + | 6) Each open covering of $ X $ | |
| + | can be refined to a conservative covering. | ||
| − | + | 7) For any open covering $ \gamma $ | |
| + | of $ X $ | ||
| + | there exists a countable collection $ \lambda _ {1} , \lambda _ {2} \dots $ | ||
| + | of open coverings of this space such that for each point $ x \in X $ | ||
| + | and for each of its neighbourhoods $ O _ {x} $ | ||
| + | there exist a $ U \in \gamma $ | ||
| + | and an integer $ i $ | ||
| + | satisfying the condition: Each element of $ \lambda _ {i} $ | ||
| + | intersecting $ O _ {x} $ | ||
| + | is contained in $ U $( | ||
| + | i.e. each star of the set $ O _ {x} $ | ||
| + | relative to $ \lambda _ {i} $ | ||
| + | lies in $ U $). | ||
| + | 8) For any open covering $ \omega $ | ||
| + | of $ X $ | ||
| + | there exists a continuous mapping of the space $ X $ | ||
| + | into some metric space $ Y $ | ||
| + | subject to the condition: At each point of $ Y $ | ||
| + | there exists a neighbourhood whose inverse image is contained in an element of $ \omega $. | ||
| + | 9) The space $ X $ | ||
| + | is collectionwise normal and weakly paracompact. | ||
====Comments==== | ====Comments==== | ||
Additional equivalent statements are: | Additional equivalent statements are: | ||
| − | 10) The product of | + | 10) The product of $ X $ |
| + | and any compact Hausdorff space is normal (cf. [[Normal space|Normal space]]). | ||
| − | 11) | + | 11) $ X \times \beta X $ |
| + | is normal. | ||
| − | 12) Every lower semi-continuous [[Multi-valued mapping|multi-valued mapping]] from | + | 12) Every lower semi-continuous [[Multi-valued mapping|multi-valued mapping]] from $ X $ |
| + | to a Banach space contains a continuous single-valued mapping. | ||
| − | 13) | + | 13) $ X $ |
| + | admits a uniformity for which the [[Hyperspace|hyperspace]] of closed sets is complete. | ||
| − | Such a mapping as is posited in 8) is said to realize the covering | + | Such a mapping as is posited in 8) is said to realize the covering $ \omega $. |
Weakly paracompact spaces are also called metacompact. They are the spaces every open covering of which has a point-finite open refinement. | Weakly paracompact spaces are also called metacompact. They are the spaces every open covering of which has a point-finite open refinement. | ||
| − | A family of sets | + | A family of sets $ \gamma $, |
| + | in particular a covering, is called a conservative family of sets if for every subfamily $ \gamma ^ \prime $ | ||
| + | of $ \gamma $, | ||
| + | $ [ \cup _ {P \in \gamma ^ \prime } P] = \cup _ {P \in \gamma ^ \prime } [ P] $. | ||
| + | Here $ [ A] $ | ||
| + | denotes the closure of $ A \subset X $. | ||
See also [[Paracompact space|Paracompact space]]. | See also [[Paracompact space|Paracompact space]]. | ||
Latest revision as of 08:05, 6 June 2020
The following statements are equivalent for an arbitrary completely-regular Hausdorff space $ X $(
cf. Completely-regular space; Hausdorff space).
1) $ X $ is paracompact.
2) Each open covering of $ X $ can be refined to a locally finite open covering.
3) Each open covering of $ X $ can be refined to a $ \sigma $- locally finite open covering, i.e. an open covering decomposing into a countable collection of locally finite families of sets in $ X $.
4) Each open covering of $ X $ can be refined to a locally finite covering (about the structure of the elements of which nothing is assumed).
5) For any open covering $ \gamma $ of $ X $ there exists an open covering which is a star refinement of $ \gamma $.
6) Each open covering of $ X $ can be refined to a conservative covering.
7) For any open covering $ \gamma $ of $ X $ there exists a countable collection $ \lambda _ {1} , \lambda _ {2} \dots $ of open coverings of this space such that for each point $ x \in X $ and for each of its neighbourhoods $ O _ {x} $ there exist a $ U \in \gamma $ and an integer $ i $ satisfying the condition: Each element of $ \lambda _ {i} $ intersecting $ O _ {x} $ is contained in $ U $( i.e. each star of the set $ O _ {x} $ relative to $ \lambda _ {i} $ lies in $ U $).
8) For any open covering $ \omega $ of $ X $ there exists a continuous mapping of the space $ X $ into some metric space $ Y $ subject to the condition: At each point of $ Y $ there exists a neighbourhood whose inverse image is contained in an element of $ \omega $.
9) The space $ X $ is collectionwise normal and weakly paracompact.
Comments
Additional equivalent statements are:
10) The product of $ X $ and any compact Hausdorff space is normal (cf. Normal space).
11) $ X \times \beta X $ is normal.
12) Every lower semi-continuous multi-valued mapping from $ X $ to a Banach space contains a continuous single-valued mapping.
13) $ X $ admits a uniformity for which the hyperspace of closed sets is complete.
Such a mapping as is posited in 8) is said to realize the covering $ \omega $.
Weakly paracompact spaces are also called metacompact. They are the spaces every open covering of which has a point-finite open refinement.
A family of sets $ \gamma $, in particular a covering, is called a conservative family of sets if for every subfamily $ \gamma ^ \prime $ of $ \gamma $, $ [ \cup _ {P \in \gamma ^ \prime } P] = \cup _ {P \in \gamma ^ \prime } [ P] $. Here $ [ A] $ denotes the closure of $ A \subset X $.
See also Paracompact space.
References
| [a1] | D.K. Burke, "Covering properties" K. Kunen (ed.) J.E. Vaughan (ed.) , Handbook of Set-Theoretic Topology , North-Holland (1984) pp. Chapt. 9; pp. 347–422 |
| [a2] | E.A. Michael, "A note on paracompact spaces" Proc. Amer. Math. Soc. , 4 (1953) pp. 831–838 |
| [a3] | E.A. Michael, "Another note on paracompact spaces" Proc. Amer. Math. Soc. , 8 (1958) pp. 822–828 |
| [a4] | E.A. Michael, "Yet another note on paracompact spaces" Proc. Amer. Math. Soc. , 10 (1959) pp. 309–314 |
| [a5] | A.H. Stone, "Paracompactness and product spaces" Bull. Amer. Math. Soc. , 54 (1948) pp. 977–982 |
| [a6] | J. Isbell, "Supercomplete spaces" Pacific J. Math. , 12 (1962) pp. 287–290 |
| [a7] | E. Michael, "Continuous selections I" Ann. of Math. (2) , 63 (1956) pp. 361–382 |
| [a8] | H. Tamano, "On paracompactness" Pacific J. Math. , 10 (1960) pp. 1043–1047 |
How to Cite This Entry:
Paracompactness criteria. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Paracompactness_criteria&oldid=12705
Paracompactness criteria. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Paracompactness_criteria&oldid=12705
This article was adapted from an original article by A.V. Arkhangel'skii (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article