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Line 1: {{Short description\|Probability theorem}} {{Distinguish\|text=the [[contraction mapping theorem]]}} In [[probability theory]], the '''continuous mapping theorem''' states that continuous functions [[Continuous function#Heine definition of continuity\|preserve limits]] even if their arguments are sequences of random variables. A continuous function, in [[Continuous function#Heine definition of continuity\|~~Heine’s~~Heine's definition]], is such a function that maps convergent sequences into convergent sequences: if ''x<sub>n</sub>'' → ''x'' then ''g''(''x<sub>n</sub>'') → ''g''(''x''). The ''continuous mapping theorem'' states that this will also be true if we replace the deterministic sequence {''x<sub>n</sub>''} with a sequence of random variables {''X<sub>n</sub>''}, and replace the standard notion of convergence of real numbers “→” with one of the types of [[convergence of random variables]]. This theorem was first proved by [[Henry Mann]] and [[Abraham Wald]] in 1943,<ref>{{cite journal \| doi = 10.1214/aoms/1177731415 \| ~~last~~last1 = Mann \|~~first~~first1=H. B. \| last2=Wald \|first2=A. \| year = 1943 \| title = On Stochastic Limit and Order Relationships \| journal = [[Annals of Mathematical Statistics]] \| volume = 14 \| issue = 3 \| pages = 217–226 \| jstor = 2235800 ~~\| ref = CITEREFMannWald1943~~ \| doi-access = free }}</ref> and it is therefore sometimes called the '''Mann–Wald theorem'''.<ref>{{cite book \| last = Amemiya \| first = Takeshi \| ~~authorlink~~author-link = Takeshi Amemiya \| year = 1985 \| title = Advanced Econometrics \| publisher = Harvard University Press \| ___location = Cambridge, MA \| isbn = 0-674-00560-0 \| url = https://books.google.com/books?id=0bzGQE14CwEC&pg=pA88 ~~\| ref = harv~~ \|page=88 }}</ref> Meanwhile, [[Denis Sargan]] refers to it as the '''general transformation theorem'''.<ref>{{cite book \|first=Denis \|last=Sargan \|title=Lectures on Advanced Econometric Theory \|___location=Oxford \|publisher=Basil Blackwell \|year=1988 \|isbn=0-631-14956-2 \|pages=4–8 }}</ref> ==Statement== Let {''X<sub>n</sub>''}, ''X'' be [[random element]]s defined on a [[metric space]] ''S''. Suppose a function {{nowrap\|''g'': ''S''→''S′''}} (where ''S′'' is another metric space) has the set of [[Discontinuity (mathematics)\|discontinuity points]] ''D<sub>g</sub>'' such that {{nowrap\|1=Pr[''X'' ∈ ''D<sub>g</sub>''] = 0}}. Then<ref>{{cite book \| last = Billingsley \| first = Patrick \| ~~authorlink~~author-link = Patrick Billingsley \| title = Convergence of Probability Measures \| year = 1969 \| publisher = John Wiley & Sons \| isbn = 0-471-07242-7~~\| ref = harv~~ \|page=31 (Corollary 1) }}</ref><ref>{{cite book \| last = ~~Van~~van der Vaart \| first = A. W. \| title = Asymptotic Statistics \| year = 1998 \| publisher = Cambridge University Press \| ___location = New York \| isbn = 0-521-49603-9 \| url =https://books.google.com/books?id=UEuQEM5RjWgC&pg=PA7 ~~\| ref = CITEREFVan_der_Vaart1998~~ \|page=7 (Theorem 2.3) }}</ref> : <math> Line 25 ⟶ 26: : <math> \mathbb E f(X_n) \to \mathbb E f(X)</math> for every bounded continuous functional ''f''. So it suffices to prove that <math> \mathbb E f(g(X_n)) \to \mathbb E f(g(X))</math> for every bounded continuous functional ''f''. For simplicity we assume ''g'' continuous. Note that <math> F = f \circ g</math> is itself a bounded continuous functional. And so the claim follows from the statement above. The general case is slightly more technical. ===Convergence in probability=== Line 62 ⟶ 63: ==See also== * [[~~Slutsky’s~~Slutsky's theorem]] * [[Portmanteau theorem]] * [[Pushforward measure]] ==References== {{reflist}} [[Category:~~Probability~~Theorems ~~theorems~~in probability theory]] [[Category:~~Statistical~~Theorems ~~theorems~~in statistics]] [[Category:Articles containing proofs]]