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Line 1: In [[probability theory]], the '''continuous mapping theorem''' states that continuous functions are [[~~Continuous_function~~Continuous function#~~Heine_definition_of_continuity~~Heine definition of continuity\|limit-preserving]] even if their arguments are sequences of random variables. A continuous function, in [[~~Continuous_function~~Continuous function#~~Heine_definition_of_continuity~~Heine definition of continuity\|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 {{harv\|Mann\|Wald\|1943}}, and it is therefore sometimes called the '''Mann–Wald theorem'''.<ref>{{harvnb\|Amemiya\|1985\|page=88}}</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>{{harvnb\|Van der Vaart\|1998\|loc=Theorem 2.3, page 7}}</ref><ref>{{harvnb\|Billingsley\|1969\|page=31, Corollary 1}}</ref><ref>{{harvnb\|Billingsley\|1999\|page=21, Theorem 2.7}}</ref> # <math>X_n \ \xrightarrow{d}\ X \quad\Rightarrow\quad g(X_n)\ \xrightarrow{d}\ g(X);</math> # <math>X_n \ \xrightarrow{p}\ X \quad\Rightarrow\quad g(X_n)\ \xrightarrow{p}\ g(X);</math> Line 49: B_\delta = \big\{x\in S\ \big\|\ x\notin D_g:\ \exists y\in S:\ \|x-y\|<\delta,\, \|g(x)-g(y)\|>\varepsilon\big\}. </math> This is the set of continuity points ''x'' of the function ''g''(·) for which it is possible to find, within the ''δ''-neighborhood of ''x'', a point which maps outside the ''ε''-neighborhood of ''g''(''x''). By definition of continuity, this set shrinks as ''δ'' goes to zero, so that lim<sub>''δ''→0</sub>''B<sub>δ</sub>'' = ∅. Now suppose that \|''g''(''X'') − ''g''(''X<sub>n</sub>'')\| > ''ε''. This implies that at least one of the following is true: either \|''X''−''X<sub>n</sub>''\|≥''δ'', or ''X''∈''D<sub>g</sub>'', or ''X''∈''B<sub>δ</sub>''. In terms of probabilities this can be written as : <math> \operatorname{Pr}\big(\big\|g(X_n)-g(X)\big\|>\varepsilon\big) \leq Line 57: </math> On the right-hand side, the first term converges to zero as ''n'' → ∞ for any fixed ''δ'', by the definition of convergence in probability of the sequence {''X<sub>n</sub>''}. The second term converges to zero as ''δ'' → 0, since the set ''B<sub>δ</sub>'' shrinks to an empty set. And the last term is identically equal to zero by assumption of the theorem. Therefore the conclusion is that : <math> \lim_{n\to\infty}\operatorname{Pr}\big(\big\|g(X_n)-g(X)\big\|>\varepsilon\big) = 0, Line 83: ==References== ===Literature=== {{refbegin}}

Continuous mapping theorem: Difference between revisions