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'''Almost sure convergence''' is one of the 4 main modes of [[stochastic convergence]].
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'''Almost sure convergence''' is one of the four main modes of [[stochastic convergence]]. It may be viewed as a notion of convergence for random variables that is similar to, but not the same as, the notion of [[pointwise convergence]] for real functions.
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==Definition==
In this section, a formal definition of almost sure convergence will be given for complex vector-valued random variables, but it should be noted that a more general definition can also be given for random variables that take on values on more abstract [[topological space|topological spaces]]. To this end, let <math>(\Omega,\mathcal{F},P)</math> be a [[measure space|probability space]] (in particular, <math>(\Omega,\mathcal{F}</math>) is a [[measurable space]]). A (<math>\mathbb{C}^n</math>-valued) '''random variable''' is defined to be any [[measurable function]] <math>X:(\Omega,\mathcal{F})\rightarrow (\mathbb{C}^n,\mathcal{B}(\mathbb{C}^n))</math>, where <math>\mathcal{B}(\mathbb{C}^n)</math> is the [[sigma algebra]] of [[Borel set|Borel sets]] of <math>\mathbb{C}^n</math>. A formal definition of almost sure convergence can be stated as follows:


==Examples==
A sequence <math>X_1,X_2,\ldots,X_n,\ldots</math> of random variables is said to '''converge almost surely''' to a random variable <math>Y</math> if <math>\mathop{\lim}_{k \rightarrow \infty}X_k(\omega)=Y(\omega)</math> for all <math>\omega \in \Lambda</math>, where <math>\Lambda \subset \Omega</math> is some measurable set satisfying <math>P(\Lambda)=1</math>. An equivalent definition is that the sequence <math>X_1,X_2,\ldots,X_n,\ldots</math>  converges almost surely to <math>Y</math> if <math>\mathop{\lim}_{k \rightarrow \infty}X_k(\omega)=Y(\omega)</math> for all <math>\omega \in \Omega \backslash \Lambda'</math>, where <math>\Lambda'</math> is some measurable set with <math>P(\Lambda')=0</math>. This convergence is often expressed as:
 
===Basic example===
 
===Intermediate example===


<math>\mathop{\lim}_{k \rightarrow \infty} X_k = Y \,\,P{\rm -a.s},</math>


==Definition==
or


<math>\mathop{\lim}_{k \rightarrow \infty} X_k = Y\,\,{\rm a.s}</math>.


==Important cases of almost sure convergence==
==Important cases of almost sure convergence==
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</math>.
</math>.


This is an example of the [[strong law of large numbers]].
This is an example of the [[strong law of large numbers]].[[Category:Suggestion Bot Tag]]
 
 
==References==
 
==See also==
*[[Stochastic convergence]]
*[[Convergence in distribution]]
*[[Convergence in probability]]
*[[Convergence in rth order mean]]
 
 
==Related topics==
*[[Stochastic variables]]
*[[Stochastic process|Stochastic processes]]
*[[Stochastic diffential equations]]
 
 
==External links==
 
 
 
[[Category:Mathematics Workgroup]]

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Almost sure convergence is one of the four main modes of stochastic convergence. It may be viewed as a notion of convergence for random variables that is similar to, but not the same as, the notion of pointwise convergence for real functions.

Definition

In this section, a formal definition of almost sure convergence will be given for complex vector-valued random variables, but it should be noted that a more general definition can also be given for random variables that take on values on more abstract topological spaces. To this end, let be a probability space (in particular, ) is a measurable space). A (-valued) random variable is defined to be any measurable function , where is the sigma algebra of Borel sets of . A formal definition of almost sure convergence can be stated as follows:

A sequence of random variables is said to converge almost surely to a random variable if for all , where is some measurable set satisfying . An equivalent definition is that the sequence converges almost surely to if for all , where is some measurable set with . This convergence is often expressed as:

or

.

Important cases of almost sure convergence

If we flip a coin n times and record the percentage of times it comes up heads, the result will almost surely approach 50% as .

This is an example of the strong law of large numbers.