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→Convergence in probability: some math notation improvements |
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In [[probability theory]], the '''continuous mapping theorem''' states that continuous functions are [[Continuous function#Heine definition of continuity|limit-preserving]] even if their arguments are sequences of random variables. A continuous function, in [[Continuous function#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 {{
==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''
# <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>
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and by the portmanteau theorem the [[limsup]] of the last expression is less than or equal to Pr(''X'' ∈ <span style="text-decoration:overline">''g''<sup>−1</sup>(''F'')</span>). Using the formula we derived in the previous paragraph, this can be written as
: <math>\begin{align}
& \operatorname{Pr}\big(X\in \overline{g^{-1}(F)}\big) \leq
\operatorname{Pr}\big(X\in g^{-1}(F)\cup D_g\big) \leq \\
& \operatorname{Pr}\big(X \in g^{-1}(F)\big) + \operatorname{Pr}(X\in D_g) =
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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>
\Pr\big(\big|g(X_n)-g(X)\big|>\varepsilon\big) \leq
\Pr\big(|X_n-X|\geq\delta\big) + \Pr(X\in B_\delta) + \Pr(X\in D_g).
</math>
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===Convergence almost surely===
By definition of the continuity of the function ''g''(·),
: <math>
\lim_{n\to\infty}X_n(\omega) = X(\omega) \quad\Rightarrow\quad \lim_{n\to\infty}g(X_n(\omega)) = g(X(\omega))
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at each point ''X''(''ω'') where ''g''(·) is continuous. Therefore
: <math>\begin{align}
\operatorname{Pr}\Big(\lim_{n\to\infty}g(X_n) = g(X)\Big)
&\geq \operatorname{Pr}\Big(\lim_{n\to\infty}g(X_n) = g(X),\ X\notin D_g\Big) \\
&\geq \operatorname{Pr}\Big(\lim_{n\to\infty}X_n = X,\ X\notin D_g\Big) \\
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==References==
{{reflist}}▼
==
* {{cite book
| last = Amemiya
| first = Takeshi
| authorlink = Takeshi Amemiya
| year = 1985
| title = Advanced Econometrics
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| ___location = Cambridge, MA
| isbn = 0-674-00560-0
| url = https://books.google.com/books?id=0bzGQE14CwEC
| ref = harv
}}
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| last = Billingsley
| first = Patrick
| authorlink = Patrick Billingsley
| title = Convergence of Probability Measures
| year = 1969
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| publisher = John Wiley & Sons
| edition = 2nd
| isbn = 0-471-19745-9
| url = https://books.google.com/books?id=QY06uAAACAAJ
| ref = harv
}}
* {{cite journal
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| publisher = Cambridge University Press
| ___location = New York
| isbn =
| url = https://books.google.com/books?id=UEuQEM5RjWgC
| ref = CITEREFVan_der_Vaart1998
}}
▲{{reflist}}
[[Category:Probability theorems]]
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