Difference between revisions of "Dense"

Latest revision as of 04:15, 1 January 2017

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Revise page, add some links to propositions or theorems using the dense property. Also more references, then demote.

DENSE IS SPRAWLED OVER LIKE 4 PAGES

I've distilled some of it Equivalent statements to a set being dense there, but I need to .... fix this page up, it's a mess. I should probably move the equivalent definitions to here, as they're like... "easy equivalent" and may well be definitions, not like ... a proposition of equivalence.
- That's a woolly distinction

Anyway, there is work required to fix this up.

SEE: List of topological properties for a smaller and neater list

Temporary summary

Let $(X,\mathcal{ J })$ be a topological space, and $(X,d)$ be a metric space. Then for an arbitrary subset of $X$ , say $A\in\mathcal{P}(X)$ , we say $A$ is dense in $X$ if:

Topological: ∀U∈J[U∩A≠∅]^[1]
- There are some equivalent conditions^{[Note 1]}
  1. $\text{Closure}(A)$ $\eq X$ (sometimes written: $\overline{A}\eq X$ )
  2. X−A contains no (non-empty) open subsets of X
    - Symbolically: $\forall U\in\mathcal{J}[U\nsubseteq X-A]$ - which is easily seen to be equivalent to: $\forall U\in\mathcal{J}\exists p\in U[p\notin X-A]$
  3. X-A has no interior points^{[Note 2]}
    - Symbolically we may write this as: $\forall p\in X-A\left[\neg\left(\exists U\in\mathcal{J}[p\in U\wedge U\subseteq A\right)\right]$
      $\iff\forall p\in X-A\forall U\in\mathcal{J}[\neg(p\in U\wedge U\subseteq A)]$
      
      $\iff\forall p\in X-A\forall U\in\mathcal{J}[(\neg(p\in U))\vee(\neg(U\subseteq A))]$ - by the negation of logical and
      
      $\iff\forall p\in X-A\forall U\in\mathcal{J}[p\notin U\vee U\nsubseteq A]$ - of course by the implies-subset relation we see $(A\subseteq B)\iff(\forall a\in A[a\in B])$ , thus:
      
      $\iff\forall p\in X-A\forall U\in\mathcal{J}\big[p\notin U\vee(\exists q\in U[q\notin A])\big]$
Metric: \forall x\in X\forall\epsilon>0[B_\epsilon(x)\cap A\neq\emptyset
- There are no equivalent statements at this time.

[Expand]Notes to editors: (Alec (talk) 04:15, 1 January 2017 (UTC))

The rest of the page continues below. It will be refactored soon.

Definition

Let $(X,\mathcal{ J })$ be a topological space and let $A\in\mathcal{P}(X)$ be an arbitrary subset of $X$ . We say " $A$ is dense in $X$ if^[2]:

$\overline{A}=X$ - that is to say that the closure of $A$ is the entirety of $X$ itself.

Some authors give the following equivalent definition to $A$ being dense^[1]:

$\forall U\in\mathcal{J}\exists a\in A[U\ne\emptyset\implies y\in U]$ , which is obviously equivalent to: \forall U\in\mathcal{J}[U\ne\emptyset \implies A\cap U\ne\emptyset] (see Claim 1 below)
- In words:
  - A set is dense if and only if every non-empty open subset contains a point of it
  - Which can be found in "equivalent statements to a set being dense".

Metric spaces definition

Let $(X,d)$ me a metric space, we say that $E\in\mathcal{P}(X)$ (so $E$ is an arbitrary subset of $X$ ) if^[1]:

\forall x\in X\forall\epsilon>0[B_\epsilon(x)\cap E\ne\emptyset] - where B_r(x) denotes the open ball of radius r, centred at x
- In words: Every open ball at every point overlaps with $E$ . (i.e: every open ball at every point contains at least 1 point in common with $E$ )
- This is equivalent to $\forall x\in X\forall\epsilon>0\exists y\in E[y\in B_\epsilon(x)]$ ^{Found in:}^[3] (see Claim 1)^{[Note 3]}

Claim 2: for a metric space $(X,d)$ a subset, $E\in\mathcal{P}(X)$ is dense in the metric sense if and only if it is dense in $(X,\mathcal{ J })$ where $J$ is the topology induced by the metric $d$ .

Proof of claims

Claim 1

This is used for both cases, and it should really be factored out into its own page. Eg:

The intersection of two sets is non-empty if and only if there exists a point in one set that is in the other set

Grade: C

This page requires one or more proofs to be filled in, it is on a to-do list for being expanded with them.

Please note that this does not mean the content is unreliable. Unless there are any caveats mentioned below the statement comes from a reliable source. As always, Warnings and limitations will be clearly shown and possibly highlighted if very important (see template:Caution et al).
The message provided is:

It is obvious that

$(B_\epsilon(x)\cap E\ne\emptyset)\iff(\exists y\in E[y\in B_\epsilon(x)])$

This proof has been marked as an page requiring an easy proof

Claim 2

Grade: C

This page requires one or more proofs to be filled in, it is on a to-do list for being expanded with them.

Please note that this does not mean the content is unreliable. Unless there are any caveats mentioned below the statement comes from a reliable source. As always, Warnings and limitations will be clearly shown and possibly highlighted if very important (see template:Caution et al).
The message provided is:

Easy for someone informed of what a metric space and topology is. The claim means showing that if

$(X,\mathcal{ J })$ is the topological space induced by a metric space for a metric space

$(X,d)$ then

$E$ is dense in

$(X,\mathcal{ J })$ if and only if

$E$ is dense in

$(X,d)$

This proof has been marked as an page requiring an easy proof

Notes

Jump up ↑ These are not just logically equivalent to density, they could be definitions for density, and may well be in some books.
Jump up ↑
a\in A is an interior point of A if:
- $\exists U\in\mathcal{J}[a\in U\wedge U\subseteq A]$ (by Functional Analysis - V1 - Dzung M. Ha - can't use references in reference tag!)
Jump up ↑ This is a trivial restatement of the claim and not worth going on its own page, unless it can be generalised (eg detached from dense-ness)

References

[2] Jump up ↑ These are not just logically equivalent to density, they could be definitions for density, and may well be in some books.

[3] Jump up ↑ $a\in A$ is an interior point of $A$ if:
$\exists U\in\mathcal{J}[a\in U\wedge U\subseteq A]$ (by Functional Analysis - V1 - Dzung M. Ha - can't use references in reference tag!)

[3] $\exists U\in\mathcal{J}[a\in U\wedge U\subseteq A]$ (by Functional Analysis - V1 - Dzung M. Ha - can't use references in reference tag!)

[6] Jump up ↑ This is a trivial restatement of the claim and not worth going on its own page, unless it can be generalised (eg detached from dense-ness)

[FAVIDMH-1] {Jump up to: 1.0} ^1.1 ^1.2 Functional Analysis - Volume 1: A gentle introduction - Dzung Minh Ha

[ITTMJML-4] Jump up ↑ Introduction to Topological Manifolds - John M. Lee

[W2014LNFARS-5] Jump up ↑ Warwick 2014 Lecture Notes - Functional Analysis - Richard Sharp

[1]

[Note 1]

[Note 2]

[2]

[3]

[Note 3]

@@ Line 1: / Line 1: @@
-{{Stub page|grade=B|msg=Revise page, add some links to propositions or theorems using the dense property. Also more references, then demote}}
+{{Stub page|grade=B|msg=Revise page, add some links to propositions or theorems using the dense property. Also more references, then demote.<br/>
+'''DENSE IS SPRAWLED OVER LIKE 4 PAGES'''
+* I've distilled some of it [[Equivalent statements to a set being dense]] there, but I need to .... fix this page up, it's a mess. I should probably move the equivalent definitions to here, as they're like... "easy equivalent" and may well be definitions, not like ... a proposition of equivalence.
+** That's a woolly distinction
+Anyway, there is work required to fix this up.
+'''SEE: [[List of topological properties]] for a smaller and neater list'''}}
+__TOC__
+==Temporary summary==
+Let {{Top.|X|J}} be a [[topological space]], and {{M|(X,d)}} be a [[metric space]]. Then for an arbitrary [[subset of]] {{M|X}}, say {{M|A\in\mathcal{P}(X)}}, we say {{M|A}} is ''dense'' in {{M|X}} if:
+# '''Topological: ''' {{M|\forall U\in\mathcal{J}[U\cap A\neq\emptyset]}}{{rFAVIDMH}}
+#* There are some equivalent conditions<ref group="Note">These are not just logically equivalent to density, they could be definitions for density, and may well be in some books.</ref>
+#*# [[Closure (topology)|{{M|\text{Closure}(A)}}]]{{M|\eq X}} (sometimes written: {{M|\overline{A}\eq X}})
+#*# {{M|X-A}} contains no (non-empty) [[open set|open subsets]] of {{M|X}}
+#*#* Symbolically: {{M|\forall U\in\mathcal{J}[U\nsubseteq X-A]}} - which is easily seen to be equivalent to: {{M|\forall U\in\mathcal{J}\exists p\in U[p\notin X-A]}}
+#*# {{M|X-A}} has no [[interior point (topology)|interior points]]<ref group="Note">{{M|a\in A}} is an ''interior point'' of {{M|A}} if:
+* {{M|\exists U\in\mathcal{J}[a\in U\wedge U\subseteq A]}} (by [[Books:Functional Analysis - Volume 1: A gentle introduction - Dzung Minh Ha|Functional Analysis - V1 - Dzung M. Ha]] - can't use references in reference tag!)</ref>
+#*#* Symbolically we may write this as: {{M|\forall p\in X-A\left[\neg\left(\exists U\in\mathcal{J}[p\in U\wedge U\subseteq A\right)\right]}}
+#*#*: {{M|\iff\forall p\in X-A\forall U\in\mathcal{J}[\neg(p\in U\wedge U\subseteq A)]}}
+#*#*: {{M|\iff\forall p\in X-A\forall U\in\mathcal{J}[(\neg(p\in U))\vee(\neg(U\subseteq A))]}} - by the [[negation of logical and]]
+#*#*: {{M|\iff\forall p\in X-A\forall U\in\mathcal{J}[p\notin U\vee U\nsubseteq A]}} - of course by the [[implies-subset relation]] we see {{M|(A\subseteq B)\iff(\forall a\in A[a\in B])}}, thus:
+#*#*: {{M|\iff\forall p\in X-A\forall U\in\mathcal{J}\big[p\notin U\vee(\exists q\in U[q\notin A])\big]}}
+# '''Metric: ''' {{M|\forall x\in X\forall\epsilon>0[B_\epsilon(x)\cap A\neq\emptyset}}
+#* There are no equivalent statements at this time.
+{{Begin Notebox}}Notes to editors: ([[User:Alec|Alec]] ([[User talk:Alec|talk]]) 04:15, 1 January 2017 (UTC))
+{{Begin Notebox Content}}
+Written by: [[User:Alec|Alec]] ([[User talk:Alec|talk]]) 04:15, 1 January 2017 (UTC)
+I have used the data at [[List of topological properties]] to create this, whilst doing so I added a symbolic form for the interior point statement of topological density.
+That symbolic form was added to the list.
+{{End Notebox Content}}
+{{End Notebox}}
+The rest of the page continues below. It will be refactored soon.
 ==Definition==
 Let {{Top.|X|J}} be a [[topological space]] and let {{M|A\in\mathcal{P}(X)}} be an arbitrary [[subset]] of {{M|X}}. We say "''{{M|A}} is dense in {{M|X}}'' if{{rITTMJML}}:
-* {{M|1=\overline{A}=X}} - that is to say that the {{link|closure|topology}} of {{M|A}} is the entirety of {{M|X}} itself.
+* {{M|1=\overline{A}=X}} - that is to say that the {{link|closure|set, topology}} of {{M|A}} is the entirety of {{M|X}} itself.
+Some authors give the following equivalent definition to {{M|A}} being dense{{rFAVIDMH}}:
+* [[A set is dense if and only if every non-empty open subset contains a point of it|{{M|1=\forall U\in\mathcal{J}\exists a\in A[U\ne\emptyset\implies y\in U]}}]], which is obviously equivalent to: {{M|1=\forall U\in\mathcal{J}[U\ne\emptyset \implies A\cap U\ne\emptyset]}} (see '''''Claim 1''''' below)
+** In words:
+*** [[A set is dense if and only if every non-empty open subset contains a point of it]]
+*** Which can be found in "''[[equivalent statements to a set being dense]]''".
+===[[Metric spaces]] definition===
+Let {{M|(X,d)}} me a [[metric space]], we say that {{M|E\in\mathcal{P}(X)}} (so {{M|E}} is an arbitrary [[subset of]] {{M|X}}) if{{rFAVIDMH}}:
+* {{M|1=\forall x\in X\forall\epsilon>0[B_\epsilon(x)\cap E\ne\emptyset]}} - where {{M|B_r(x)}} denotes the [[open ball]] of [[radius]] {{M|r}}, centred at {{M|x}}
+** In words: Every [[open ball]] at every point overlaps with {{M|E}}. (i.e: every open ball at every point contains at least 1 point in common with {{M|E}})
+** This is equivalent to {{M|1=\forall x\in X\forall\epsilon>0\exists y\in E[y\in B_\epsilon(x)]}}<sup>Found in:</sup>{{rW2014LNFARS}} (see '''''Claim 1''''')<ref group="Note">This is a trivial restatement of the claim and not worth going on its own page, unless it can be generalised (eg detached from dense-ness)</ref>
+'''''Claim 2: ''''' for a [[metric space]] {{M|(X,d)}} a subset, {{M|E\in\mathcal{P}(X)}} is dense in the metric sense {{iff}} it is dense in {{Top.|X|J}} where {{M|J}} is the [[topology induced by the metric]] {{M|d}}.
+==Proof of claims==
+===Claim 1===
+This is used for both cases, and it should really be factored out into its own page. Eg:
+* [[The intersection of two sets is non-empty if and only if there exists a point in one set that is in the other set]]
+{{Requires proof|easy=true|grade=C|msg=It is obvious that {{M|1=(B_\epsilon(x)\cap E\ne\emptyset)\iff(\exists y\in E[y\in B_\epsilon(x)])}}}}
+===Claim 2===
+{{Requires proof|easy=true|grade=C|msg=Easy for someone informed of what a metric space and topology is. The claim means showing that if {{Top.|X|J}} is the [[topological space induced by a metric space]] for a [[metric space]] {{M|(X,d)}} then {{M|E}} is dense in {{Top.|X|J}} {{iff}} {{M|E}} is dense in {{M|(X,d)}}}}
 ==See also==
 * [[Equivalent statements to a set being dense]]
 ** [[A set is dense if and only if every non-empty open subset contains a point of it]]
+==Notes==
+<references group="Note"/>
 ==References==
 <references/>
-{{Definition|Topology|Metric Space}}
+{{Definition|Topology|Metric Space|Functional Analysis}}

Difference between revisions of "Dense"

Latest revision as of 04:15, 1 January 2017

Contents

Temporary summary

Definition

Metric spaces definition

Proof of claims

Claim 1

Claim 2

See also

Notes

References

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