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m I changed the link associated to the word "closed" at the very beggining, from the "Closed" Wikipedia disambiguation page to the "Closure (Mathematics)" Wikipedia article, since it's that concept the one relevant to Monotone Classes. |
Patar knight (talk | contribs) Adding local short description: "Measure theory and probability theorem", overriding Wikidata description "theorem" |
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{{Short description|Measure theory and probability theorem}}
In [[Measure (mathematics)|measure theory]] and [[Probability theory|probability]], the '''monotone class theorem''' connects monotone classes and [[Sigma-algebra|{{sigma}}-algebra]]s. The theorem says that the smallest [[#Definition of a monotone class|monotone class]] containing an [[Field of sets|algebra of sets]] <math>G</math> is precisely the smallest [[Sigma-algebra|{{sigma}}-algebra]] containing <math>G.</math> It is used as a type of [[transfinite induction]] to prove many other theorems, such as [[Fubini's theorem]].
==Definition of a monotone class==
A '''{{em|{{visible anchor|monotone class}}}}''' is a [[Family of sets|family]] (i.e. class) <math>M</math> of sets that is [[Closure (mathematics)|closed]] under countable monotone unions and also under countable monotone intersections. Explicitly, this means <math>M</math> has the following properties:
As a corollary, if <math>\mathcal{G}</math> is a [[Ring of sets|ring]] of sets, then the smallest monotone class containing it coincides with the sigma-ring of <math>\mathcal{G}</math>.▼
# if <math>A_1, A_2, \ldots \in M</math> and <math>A_1 \subseteq A_2 \subseteq \cdots</math> then <math display="inline">{\textstyle\bigcup\limits_{i = 1}^\infty} A_i \in M,</math> and
# if <math>B_1, B_2, \ldots \in M</math> and <math>B_1 \supseteq B_2 \supseteq \cdots</math> then <math display="inline">{\textstyle\bigcap\limits_{i = 1}^\infty} B_i \in M.</math>
==Monotone class theorem for sets==
{{math theorem|name=Monotone class theorem for sets|note=|style=|math_statement=
Let <math>G</math> be an [[Field of sets|algebra of sets]] and define <math>M(G)</math> to be the smallest monotone class containing <math>G.</math> Then <math>M(G)</math> is precisely the [[Sigma-algebra|{{sigma}}-algebra]] generated by <math>G</math>; that is <math>\sigma(G) = M(G).</math>
}}
==Monotone class theorem for functions==
[[Category:Set families]]▼
{{math theorem|name=Monotone class theorem for functions|note=|style=|math_statement=
Let <math>\mathcal{A}</math> be a [[Pi system|{{pi}}-system]] that contains <math>\Omega\,</math> and let <math>\mathcal{H}</math> be a collection of functions from <math>\Omega</math> to <math>\R</math> with the following properties:
# If <math>A \in \mathcal{A}</math> then <math>\mathbf{1}_A \in \mathcal{H}</math> where <math>\mathbf{1}_A</math> denotes the [[indicator function]] of <math>A.</math>
# If <math>f, g \in \mathcal{H}</math> and <math>c \in \Reals</math> then <math>f + g</math> and <math>c f \in \mathcal{H}.</math>
# If <math>f_n \in \mathcal{H}</math> is a sequence of non-negative functions that increase to a bounded function <math>f</math> then <math>f \in \mathcal{H}.</math>
Then <math>\mathcal{H}</math> contains all bounded functions that are measurable with respect to <math>\sigma(\mathcal{A}),</math> which is the {{sigma}}-algebra generated by <math>\mathcal{A}.</math>
}}
===Proof===
The following argument originates in [[Rick Durrett]]'s Probability: Theory and Examples.<ref name="Durrett">{{cite book|last=Durrett|first=Rick|year=2010|title=Probability: Theory and Examples|url=https://archive.org/details/probabilitytheor00rdur|url-access=limited|edition=4th|publisher=Cambridge University Press|page=[https://archive.org/details/probabilitytheor00rdur/page/n287 276]|isbn=978-0521765398}}</ref>
{{math proof|drop=hidden|proof=
The assumption <math>\Omega\, \in \mathcal{A},</math> (2), and (3) imply that <math>\mathcal{G} = \left\{A : \mathbf{1}_{A} \in \mathcal{H}\right\}</math> is a {{lambda}}-system.
By (1) and the [[Dynkin system|{{pi}}−{{lambda}} theorem]], <math>\sigma(\mathcal{A}) \subseteq \mathcal{G}.</math>
Statement (2) implies that <math>\mathcal{H}</math> contains all simple functions, and then (3) implies that <math>\mathcal{H}</math> contains all bounded functions measurable with respect to <math>\sigma(\mathcal{A}).</math>
}}
==Results and applications==
▲As a corollary, if <math>
By invoking this theorem, one can use monotone classes to help verify that a certain collection of subsets is a [[Sigma-algebra|{{sigma}}-algebra]].
The monotone class theorem for functions can be a powerful tool that allows statements about particularly simple classes of functions to be generalized to arbitrary bounded and measurable functions.
==See also==
* {{annotated link|Dynkin system}}
* {{annotated link|π-λ theorem|{{pi}}-{{lambda}} theorem}}
* {{annotated link|Pi-system|{{pi}}-system}}
* {{annotated link|σ-algebra}}
==Citations==
{{reflist|group=note}}
{{reflist}}
==References==
* {{Durrett Probability Theory and Examples 5th Edition}} <!-- {{sfn|Durrett|2019|p=}} -->
[[Category:Theorems in measure theory]]
[[fr:Lemme de classe monotone]]
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