Difference between revisions of "Borel sigma-algebra of the real line"
m (Added to theorems category. Added provisional notice pertaining to the Borel sigma-algebra page) |
(Claim 8 has reasoning now, warnings removed, it's probably true. Proof still pending) |
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# {{M|\{(a,b)\ \vert\ a,b\in\mathbb{M}\} }}{{rMIAMRLS}} | # {{M|\{(a,b)\ \vert\ a,b\in\mathbb{M}\} }}{{rMIAMRLS}} | ||
# {{M|\{[c,d)\ \vert\ c,d\in\mathbb{M}\} }}{{rMIAMRLS}} | # {{M|\{[c,d)\ \vert\ c,d\in\mathbb{M}\} }}{{rMIAMRLS}} | ||
− | # {{M|\{(p,q]\ \vert\ p,q\in\mathbb{M}\} }}<sup>Suspected:</sup><ref group="Note">I have proved form {{M|6}} before, the order didn't matter there</ref | + | # {{M|\{(p,q]\ \vert\ p,q\in\mathbb{M}\} }}<sup>Suspected:</sup><ref group="Note">I have proved form {{M|6}} before, the order didn't matter there</ref> |
− | # | + | # {{M|\{[u,v]\ \vert\ u,v\in\mathbb{M}\} }}<sup>Suspected:</sup><ref group="Note" name="Claim8">Take: {{MM|\bigcup_{n\in\mathbb{N} }[a+\frac{\epsilon}{n},b-\tfrac{\epsilon}{n}]}}, with a little effort one can see this {{M|\eq(a,b)}} - for carefully chosen {{M|\epsilon}}</ref> |
# {{M|\mathcal{C} }}{{rMIAMRLS}} - the [[closed sets]] of {{M|\mathbb{R} }} | # {{M|\mathcal{C} }}{{rMIAMRLS}} - the [[closed sets]] of {{M|\mathbb{R} }} | ||
# {{M|\mathcal{K} }}{{rMIAMRLS}} - the {{link|compact|topology}} sets of {{M|\mathbb{R} }} | # {{M|\mathcal{K} }}{{rMIAMRLS}} - the {{link|compact|topology}} sets of {{M|\mathbb{R} }} | ||
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* '''6: ''' - ''[[the closed-open rectangles with either rational or real points generate the same sigma-algebra as the Borel sigma-algebra on R^n]]'' | * '''6: ''' - ''[[the closed-open rectangles with either rational or real points generate the same sigma-algebra as the Borel sigma-algebra on R^n]]'' | ||
* '''7: ''' - {{Warning|Suspected from proof on paper of {{M|6}}}} | * '''7: ''' - {{Warning|Suspected from proof on paper of {{M|6}}}} | ||
− | * '''8: ''' - {{Warning| | + | * '''8: ''' - {{Warning|Suspected by<ref group="Note" name="Claim8"/>}} |
* '''9: ''' - ''[[the sigma-algebra generated by the closed sets of R^n is the same as the Borel sigma-algebra of R^n]]'' | * '''9: ''' - ''[[the sigma-algebra generated by the closed sets of R^n is the same as the Borel sigma-algebra of R^n]]'' | ||
* '''10: ''' - ''[[the sigma-algebra generated by the compact sets of R^n is the same as the Borel sigma-algebra of R^n]]'' | * '''10: ''' - ''[[the sigma-algebra generated by the compact sets of R^n is the same as the Borel sigma-algebra of R^n]]'' |
Latest revision as of 15:48, 27 February 2017
- This page is a provisional page - see the notice at the bottom for more information
Definition
Let [ilmath](\mathbb{R},\mathcal{O})[/ilmath][Note 1] denote the real line considered as a topological space. Recall that the Borel [ilmath]\sigma[/ilmath]-algebra is defined to be the [ilmath]\sigma[/ilmath]-algebra generated by the open sets of the topology, recall that [ilmath]\mathcal{J} [/ilmath] is the collection of all open sets of the space. Thus:
- [ilmath]\mathcal{B}(\mathbb{R}):\eq\sigma(\mathcal{O})[/ilmath]
- where [ilmath]\sigma(\mathcal{G})[/ilmath] denotes the [ilmath]\sigma[/ilmath]-algebra generated by [ilmath]\mathcal{G} [/ilmath], a collection of sets.
This is often written just as [ilmath]\mathcal{B} [/ilmath], provided this doesn't lead to ambiguities - this is inline with: [ilmath]\mathcal{B}^n[/ilmath], which we use for the Borel [ilmath]\sigma[/ilmath]-algebra on [ilmath]\mathbb{R}^n[/ilmath]
Other generators
Let [ilmath]\mathbb{M} [/ilmath] denote either the real numbers, [ilmath]\mathbb{R} [/ilmath], or the quotient numbers, [ilmath]\mathbb{Q} [/ilmath] (to save us writing the same thing for both [ilmath]\mathbb{R} [/ilmath] and [ilmath]\mathbb{Q} [/ilmath], then the following all generate[Note 2] [ilmath]\mathcal{B}(\mathbb{R})[/ilmath]:
- [ilmath]\{(-\infty,a)\ \vert\ a\in\mathbb{M}\} [/ilmath][1]
- [ilmath]\{(-\infty,b]\ \vert\ b\in\mathbb{M}\} [/ilmath][1]
- [ilmath]\{(c,+\infty)\ \vert\ c\in\mathbb{M}\} [/ilmath][1]
- [ilmath]\{[d,+\infty)\ \vert\ d\in\mathbb{M}\} [/ilmath][1]
- [ilmath]\{(a,b)\ \vert\ a,b\in\mathbb{M}\} [/ilmath][1]
- [ilmath]\{[c,d)\ \vert\ c,d\in\mathbb{M}\} [/ilmath][1]
- [ilmath]\{(p,q]\ \vert\ p,q\in\mathbb{M}\} [/ilmath]Suspected:[Note 3]
- [ilmath]\{[u,v]\ \vert\ u,v\in\mathbb{M}\} [/ilmath]Suspected:[Note 4]
- [ilmath]\mathcal{C} [/ilmath][1] - the closed sets of [ilmath]\mathbb{R} [/ilmath]
- [ilmath]\mathcal{K} [/ilmath][1] - the compact sets of [ilmath]\mathbb{R} [/ilmath]
Proofs
- 1, 2, 3 and 4: - the collection of all open and closed rays based at either rational or real points generate the Borel sigma-algebra on R
- 5: - the open rectangles with either rational or real points generate the same sigma-algebra as the Borel sigma-algebra on R^n
- 6: - the closed-open rectangles with either rational or real points generate the same sigma-algebra as the Borel sigma-algebra on R^n
- 7: - Warning:Suspected from proof on paper of [ilmath]6[/ilmath]
- 8: - Warning:Suspected by[Note 4]
- 9: - the sigma-algebra generated by the closed sets of R^n is the same as the Borel sigma-algebra of R^n
- 10: - the sigma-algebra generated by the compact sets of R^n is the same as the Borel sigma-algebra of R^n
The message provided is:
See next
See also
Notes
- ↑ Traditionally we use [ilmath]\mathcal{J} [/ilmath] for the topology part of a topological space, however later in the article we will introduce [ilmath]\mathscr{J} [/ilmath] in several forms, so we avoid [ilmath]\mathcal{J} [/ilmath] to avoid confusion.
- ↑ This means that if [ilmath]A[/ilmath] is any of the families of sets from the list, then:
- [ilmath]\mathcal{B}(\mathbb{R})\eq\sigma(A)[/ilmath].
- ↑ I have proved form [ilmath]6[/ilmath] before, the order didn't matter there
- ↑ 4.0 4.1 Take: [math]\bigcup_{n\in\mathbb{N} }[a+\frac{\epsilon}{n},b-\tfrac{\epsilon}{n}][/math], with a little effort one can see this [ilmath]\eq(a,b)[/ilmath] - for carefully chosen [ilmath]\epsilon[/ilmath]
References
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