Some cardinal properties of stratifiable spaces mamadaliev N. K., Nurmatova M. Ya
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- Bu səhifədəki naviqasiya:
- Theorem 1[3].
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Definition 1[3] We say that -topological space is stratifiable provided that to each open set one can assign a sequence of open subsets of such that
a) , b) , c) whenever . The construction in the definition is called the stratification. It is obvious that every metrizable space is stratifiable. J.Ceder [3] proved the following statement. Theorem 1[3]. For a stratifiable space following conditions are equivalent: 1) is finally compact; 2) is separable; 3) has the Souslin property; 4) has countable network. Proposition 1[5]. For any -space we have In the work R.A.Stoltenberg proved the following theorem: Theorem 2[6]. Let be an infinite cardinal. Then for any stratifiable space following conditions are equivalent: 1) The space has dense subset of cardinality ; 2) Every open cover of the space has a subcover of cardinality 3) Every family of pairwise disjoint non-empty open subsets of the space has cardinality ; 4) The space has a network of cardinality . Beshimov and Mamadaliyev generalize that theorem 2 as following: Theorem 3. Let be an infinite cardinal. Then for any stratifiable space following conditions are equivalent: 1) The space has dense subset of cardinality ; 2) The weakly density of the space is ; 3) Every open cover of the space has a subcover of cardinality 4) Every family of pairwise disjoint non-empty open subsets of the space has cardinality ; 5) The space has a network of cardinality ; 6) The space has a -network of cardinality . Proof. The implication 5) 6) is obvious. We show the implication 1) 6). Let be a dense subset of cardinality in . We must prove that the family is a -network of the space . Let be any non-empty open subset of . There exists a point such that from density of the subset Then . Hence, the family is a -network of the space . Now we show the implication 6) 1). Let be a -network of the space . We choose a point from each set . It is obvious that the set has cardinality . We show that is dense in . Let be an arbitrary non-empty open subset of . Since is a -network of there exists such that . Thence, we have , so that is dense in . Theorem 1.5 is proved. Yüklə 186,9 Kb. Dostları ilə paylaş:
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