Stochastic convergence: Difference between revisions
imported>Ragnar Schroder |
imported>Ragnar Schroder (This and previous edit: Fixed the tex error in the Formal definition subsection to the Almost sure convergence section.) |
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Let <math>X_0, X_1, ... </math> be a sequence of [[stochastic variable|stochastic variables]]. | Let <math>X_0, X_1, ... </math> be a sequence of [[stochastic variable|stochastic variables]]. | ||
If <math>P(\ | If <math>P(\lim_{i \to \infty} X_i = a) = 1 </math> for some a, then the sequence has almost sure convergence to a. | ||
==Convergence in probability== | ==Convergence in probability== | ||
Revision as of 15:18, 28 June 2007
Stochastic convergence is a mathematical concept intended to formalize the idea that a sequence of essentially random or unpredictable events sometimes tends to settle into a pattern.
Four different varieties of stochastic convergence are noted:
- Almost sure convergence
- Convergence in probability
- Convergence in distribution
- Convergence in nth order mean
Almost sure convergence
Example
Consider a short lived animal of some species. We may note the exact amount of food the animal consumes day by day. This sequence of numbers will be unpredictable in advance, but we may be quite certain that one day the number will be zero, and stay zero forever after.
Formal definition
Let be a sequence of stochastic variables.
If for some a, then the sequence has almost sure convergence to a.
Convergence in probability
Example
We may keep tossing a die an infinite number of times and at every toss note the average outcome so far. The exact number thus obtained after each toss will be unpredictable, but for a fair die, it will tend to get closer and closer to the arithmetic average of 1,2,3,4,5 and 6, i.e. 3.5.
Formal definition
Convergence in distribution
Example
Formal definition
Convergence in nth order mean
Example
Formal definition
Relations between the different modes of convergence
- If a stochastic sequence has almost sure convergence, then it also has convergence in probability.
- If a stochastic sequence has convergence in probability, then it also has convergence in distribution.
- If a stochastic sequence has convergence in (n+1)th order mean, then it also has convergence in nth order mean (n>0).
- If a stochastic sequence has convergence in nth order mean, then it also has convergence in probability.