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Line 1: {{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~~Field of sets\|algebra of sets]] ''<math>G''</math> is precisely the smallest [[Sigma-algebra\|~~''σ''~~{{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~~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: # 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\~~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\~~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 ~~{{mvar\|~~<math>G}}</math> be an [[~~field~~Field of sets\|algebra of sets]] and define {{<math~~\|''~~>M''(''G'')}}</math> to be the smallest monotone class containing~~ {{mvar\|~~ <math>G}}.</math> Then {{<math~~\|''~~>M''(''G'')}}</math> is precisely the [[Sigma-algebra\|~~''σ''~~{{sigma}}-algebra]] generated by ~~{{mvar\|~~<math>G~~}},~~</math>; ~~i.e.~~that is {{<math~~\|1=''σ''~~>\sigma(''G'') = ''M''(''G'')}}.</math> }} == Monotone class theorem for functions == {{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 \RReals</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 ~~''λ''~~{{lambda}}-system. By (1) and the [[Dynkin system\|{{pi}}−~~''λ''~~{{lambda}} theorem]], <math>\sigma(\mathcal{A}) \~~subset~~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 {{mvar\|G}} is a [[Ring of sets\|ring]] of sets, then the smallest monotone class containing it coincides with the sigma-ring of {{mvar\|G}}.▼ ▲As a corollary, if ~~{{mvar\|~~<math>G}}</math> is a [[~~Ring~~ring of sets~~\|ring~~]] ~~of sets~~, then the smallest monotone class containing it coincides with the [[Sigma-ring\|{{sigma}}-ring]] of~~ {{mvar\|~~ <math>G}}.</math> By invoking this theorem, one can use monotone classes to help verify that a certain collection of subsets is a sigma-algebra.▼ ▲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\|π-λ theorem}}▼ * {{annotated link\|Pi-system\|{{pi}}-system}}▼ * {{annotated link\|Dynkin system}} * {{annotated link\|π-λ theorem\|{{pi}}-{{lambda}} theorem}} ▲* {{annotated link\|Pi-system\|{{pi}}-system}} ▲* {{annotated link\|πσ-~~λ theorem~~algebra}} == Citations ==▼ {{reflist\|group=note}} ▲== Citations == {{reflist}} == References == * {{Durrett Probability Theory and Examples 5th Edition}} <!-- {{sfn\|Durrett\|2019\|p=}} --> [[Category:~~Set~~Families ~~families~~of sets]] [[Category:Theorems in measure theory]]