Presentation is loading. Please wait.

Presentation is loading. Please wait.

M onotone C ountable P aracompactness Lylah Haynes Joint work with Chris Good.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "M onotone C ountable P aracompactness Lylah Haynes Joint work with Chris Good."— Presentation transcript:

1 M onotone C ountable P aracompactness Lylah Haynes HaynesL@maths.bham.ac.uk Joint work with Chris Good

2 A space is countably paracompact if every countable open cover has a locally finite open refinement [Dowker, Katětov]. X x [0,1] is normal iff X is countably paracompact and normal [Dowker]. A space is  -normal if every pair of disjoint closed sets, one of which is a regular G  -set, can be separated by disjoint closed sets [Mack]. X x [0,1] is  -normal iff X is countably paracompact [Mack]. Countable paracompactness and  -normality

3 1) For every decreasing sequence (D n ) n of closed sets with empty intersection, there exists a sequence (U n ) n of open sets such that D n U n for each n and [Ishikawa]. 2) For every decreasing sequence (D n ) n of closed nowhere dense sets with empty intersection, there exists a sequence (U n ) n of open sets such that D n U n for each n and Ø [Hardy & Juhász]. 3) If C is a closed subset of X x [0,1] and D is a closed subset of [0,1] such that C (X x D) = Ø, then there are disjoint open sets separating C and X x D [Tamano]. 4) X x [0,1] is  -normal [Mack]. Characterizing countable paracompactness Ø

4 0 1 [ [ X D X x D C Tamano’s characterization of cp C closed in X x [0,1] D closed in [0,1]

5 For example, monotone normality represented pictorially: What is monotonization? C H(C,U)H(C,U) U C’ H(C’,U’ ) U’

6 A space X is monotonically countably metacompact (MCM) iff there is an operator U assigning to each n and each closed set D, an open set U(n,D) such that 1) D U(n,D), 2) if D E then U(n,D) U(n,E) and 3) if (D i ) i is a decreasing sequence of closed sets with empty intersection, then X is monotonically countably paracompact (MCP) if also 4) if (D i ) i is a decreasing sequence of closed sets with empty intersection, then [Good, Ying] MCP Ø.Ø. MCM/MCP introduced by Good, Knight and Stares Ø.Ø. Monotone condition Monotone condition

7 MNSet theoretic assumptions can often be abandoned, for example 1) the Normal Moore Space Conjecture is true under PMEA. 2) every monotonically normal Moore space is metrizable. MCPSet theoretic assumptions can often be abandoned, for example 1) every countably paracompact Moore space is metrizable under PMEA. 2) every MCP Moore space is metrizable. Motivation for monotonization

8 A space X is MCP iff there is an operator U assigning to each pair (C,D), where C is closed in X x [0,1] and D is closed in [0,1] such that C (X x [0,1]) = Ø, an open set U(C,D) such that 1) C U(C,D) X x ([0,1] \ D) 2) if C C’ and D’ D, then U(C,D) U(C’,D’). Monotonizing Tamano’s characterization 0 1 [ [ X X x D C D U(C,D)U(C,D) Monotone condition Monotone condition

9 Suppose U is an MCP operator. Define Sketch proof 0 1 [ [ X x D C D r CrCr X ( ( U(n rD,C r )

10 Suppose the monotonization of Tamano’s characterization holds Then D n U(n,(D i )) for each n, if D i E i for each i, then U(n,(D i )) U(n,(E i )) for each n, Ø. Hence MCP. Sketch proof X D 1 x {1} 0 1 D 2 x {1/2} D 3 x {1/3} D n x {1/n} () U(n,(D i )) U(D,{0}) 1/2 X x {0} 1/3

11 A space X is monotonically  -normal (M  N) if there is an operator H assigning to each pair of disjoint closed sets (C,D) in X, at least one of which is a regular G  -set, an open set H(C,D) such that 1) C H(C,D) X \ D 2) if C C’ and D’ D, then H(C,D) H(C’,D’). MNMN X x [0,1] M  N X MCP X x [0,1] MCP X M  N

12 X x [0,1] M  N X MCP Since [0,1] is metrizable, every closed set in [0,1] is a regular G  -set. Therefore X x D is a regular G  -set. Hence any M  N operator H satisfies the ‘monotonized Tamano’ characterization of MCP. Proof 0 1 [ [ X X x D C D H(C,D)H(C,D)

13 MCP M  N F  1 point compactification of Mrówka’s  -space F is an infinite mad family of infinite subsets of  (i.e. for every F 1,F 2 F, F 1 F 2 is finite, and if S  is an infinite set not in F, there exists F’ F such that S F’ is infinite).  * is MCP since it is compact. 1) If C and D are disjoint closed sets in  *, then one must contain at most a finite subset of F. 2) Any closed subset of  * containing at most finitely many points of F is a regular G  -set. Hence if  * is M  N, it is MN and so  is MN. Contradiction.  = F   *=  N( )= (  \K), K compact in 

14 The Sorgenfrey line S S is MN, so it is both M  N and collectionwise normal. Suppose S is MCP. Then S is MCM ≡ . Since S is a regular  -space, it is a Moore space (  +  implies developable). Since collectionwise normal Moore implies metrizable [Bing], S is metrizable. Contradiction. M  N MCP [ ) ab R

15 A space X is nowhere dense MCM (nMCM) iff there is an operator U assigning to each n and each closed nowhere dense set D, an open set U(n,D) such that 1) D U(n,D), 2) if D E then U(n,D) U(n,E) and 3) if (D i ) i is a decreasing sequence of closed nowhere dense sets with empty intersection, then Ø. X is nowhere dense MCP (nMCP) if also 4) if (D i ) i is a decreasing sequence of closed nowhere dense sets with empty intersection, then Ø. Nowhere dense MCM and MCP

16 1)nMCM ≡ MCM 2)wN ↔ nMCP + q [wN ↔ MCP + q] 3)nMCP + Moore → Metrizable [MCP + Moore → Metrizable] nMCP vs MCP nMCP ≡ MCP?

17 For more information, see the above article, Topology and its Applications 154 (2007) 734—740

Download ppt "M onotone C ountable P aracompactness Lylah Haynes Joint work with Chris Good."

Similar presentations

Completeness and Expressiveness

Completeness and Expressiveness
Some important properties Lectures of Prof. Doron Peled, Bar Ilan University.

Some important properties Lectures of Prof. Doron Peled, Bar Ilan University.
The proof is quite similar to that of a previous result: a compact subspace of a Hausdorff is closed. Theorem: If topological X  space is compact and.

The proof is quite similar to that of a previous result: a compact subspace of a Hausdorff is closed. Theorem: If topological X  space is compact and.
Lecture 3 Universal TM. Code of a DTM Consider a one-tape DTM M = (Q, Σ, Γ, δ, s). It can be encoded as follows: First, encode each state, each direction,

Lecture 3 Universal TM. Code of a DTM Consider a one-tape DTM M = (Q, Σ, Γ, δ, s). It can be encoded as follows: First, encode each state, each direction,
2.1 Sets ‒Sets ‒Common Universal Sets ‒Subsets 2.2 Set Operations 2.3 Functions 2.4 Sequences and Summations 1.

2.1 Sets ‒Sets ‒Common Universal Sets ‒Subsets 2.2 Set Operations 2.3 Functions 2.4 Sequences and Summations 1.
Week 21 Basic Set Theory A set is a collection of elements. Use capital letters, A, B, C to denotes sets and small letters a 1, a 2, … to denote the elements.

Week 21 Basic Set Theory A set is a collection of elements. Use capital letters, A, B, C to denotes sets and small letters a 1, a 2, … to denote the elements.
1 Diagonalization Fact: Many books exist. Fact: Some books contain the titles of other books within them. Fact: Some books contain their own titles within.

1 Diagonalization Fact: Many books exist. Fact: Some books contain the titles of other books within them. Fact: Some books contain their own titles within.
Basic properties of the integers

Basic properties of the integers
15-251 Great Theoretical Ideas in Computer Science.

Great Theoretical Ideas in Computer Science.
Selective screenability, products and topological groups Liljana Babinkostova Boise State University III Workshop on Coverings, Selections and Games in.

Selective screenability, products and topological groups Liljana Babinkostova Boise State University III Workshop on Coverings, Selections and Games in.
1 More Applications of the Pumping Lemma. 2 The Pumping Lemma: Given a infinite regular language there exists an integer for any string with length we.

1 More Applications of the Pumping Lemma. 2 The Pumping Lemma: Given a infinite regular language there exists an integer for any string with length we.
Introduction 0-dimensional space X is 0-dimensional iff for each open cover U of X there is a disjoint refinement that is still an open cover of X.

Introduction 0-dimensional space X is 0-dimensional iff for each open cover U of X there is a disjoint refinement that is still an open cover of X.
Homework 4 Solutions.

Homework 4 Solutions.
Selection Principles and Basis Properties Liljana Babinkostova Boise State University.

Selection Principles and Basis Properties Liljana Babinkostova Boise State University.
Equivalence Relations: Selected Exercises

Equivalence Relations: Selected Exercises
Mathematical Induction Assume that we are given an infinite supply of stamps of two different denominations, 3 cents and and 5 cents. Prove using mathematical.

Mathematical Induction Assume that we are given an infinite supply of stamps of two different denominations, 3 cents and and 5 cents. Prove using mathematical.
Topological Nets and Filters Mark Hunnell. Outline 1.Motivations for Nets and Filters 2.Basic Definitions 3.Construction of Equivalence 4.Comparison and.

Topological Nets and Filters Mark Hunnell. Outline 1.Motivations for Nets and Filters 2.Basic Definitions 3.Construction of Equivalence 4.Comparison and.
MA4266 Topology Wayne Lawton Department of Mathematics S17-08-17, 65162749

MA4266 Topology Wayne Lawton Department of Mathematics S ,
Department of Mathematics

Department of Mathematics
Methods of Proof. This Lecture Now we have learnt the basics in logic. We are going to apply the logical rules in proving mathematical theorems. Direct.

Methods of Proof. This Lecture Now we have learnt the basics in logic. We are going to apply the logical rules in proving mathematical theorems. Direct.

Similar presentations

Ads by Google