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In [[mathematics]], a '''sample-continuous process''' is a [[stochastic process]] whose sample paths are [[almost surely]] [[continuous function]]s. | |||
==Definition== | |||
Let (Ω, Σ, '''P''') be a [[probability space]]. Let ''X'' : ''I'' × Ω → ''S'' be a stochastic process, where the [[index set]] ''I'' and state space ''S'' are both [[topological space]]s. Then the process ''X'' is called '''sample-continuous''' (or '''almost surely continuous''', or simply '''continuous''') if the map ''X''(''ω'') : ''I'' → ''S'' is [[Continuous function (topology)|continuous as a function of topological spaces]] for '''P'''-[[almost all]] ''ω'' in ''Ω''. | |||
In many examples, the index set ''I'' is an interval of time, [0, ''T''] or [0, +∞), and the state space ''S'' is the [[real line]] or ''n''-[[dimension]]al [[Euclidean space]] '''R'''<sup>''n''</sup>. | |||
==Examples== | |||
* [[Brownian motion]] (the [[Wiener process]]) on Euclidean space is sample-continuous. | |||
* For "nice" parameters of the equations, solutions to [[stochastic differential equation]]s are sample-continuous. See the existence and uniqueness theorem in the stochastic differential equations article for some sufficient conditions to ensure sample continuity. | |||
* The process ''X'' : [0, +∞) × Ω → '''R''' that makes equiprobable jumps up or down every unit time according to | |||
::<math>\begin{cases} X_{t} \sim \mathrm{Unif} (\{X_{t-1} - 1, X_{t-1} + 1\}), & t \mbox{ an integer;} \\ X_{t} = X_{\lfloor t \rfloor}, & t \mbox{ not an integer;} \end{cases}</math> | |||
: is ''not'' sample-continuous. In fact, it is surely discontinuous. | |||
==Properties== | |||
* For sample-continuous processes, the [[finite-dimensional distribution]]s determine the [[Law (stochastic processes)|law]], and vice versa. | |||
==See also== | |||
* [[Continuous stochastic process]] | |||
==References== | |||
* {{cite book | |||
| author = Kloeden, Peter E. | |||
|coauthors = Platen, Eckhard | |||
| title = Numerical solution of stochastic differential equations | |||
| series = Applications of Mathematics (New York) 23 | |||
|publisher = Springer-Verlag | |||
| location = Berlin | |||
| year = 1992 | |||
| pages = 38–39; | |||
| isbn = 3-540-54062-8 | |||
}} | |||
[[Category:Stochastic processes]] | |||
Revision as of 08:56, 19 November 2013
In mathematics, a sample-continuous process is a stochastic process whose sample paths are almost surely continuous functions.
Definition
Let (Ω, Σ, P) be a probability space. Let X : I × Ω → S be a stochastic process, where the index set I and state space S are both topological spaces. Then the process X is called sample-continuous (or almost surely continuous, or simply continuous) if the map X(ω) : I → S is continuous as a function of topological spaces for P-almost all ω in Ω.
In many examples, the index set I is an interval of time, [0, T] or [0, +∞), and the state space S is the real line or n-dimensional Euclidean space Rn.
Examples
- Brownian motion (the Wiener process) on Euclidean space is sample-continuous.
- For "nice" parameters of the equations, solutions to stochastic differential equations are sample-continuous. See the existence and uniqueness theorem in the stochastic differential equations article for some sufficient conditions to ensure sample continuity.
- The process X : [0, +∞) × Ω → R that makes equiprobable jumps up or down every unit time according to
- is not sample-continuous. In fact, it is surely discontinuous.
Properties
- For sample-continuous processes, the finite-dimensional distributions determine the law, and vice versa.
See also
References
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