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In mathematics, a continuous-time random walk (CTRW) is a generalization of a random walk where the wandering particle waits for a random time between jumps. It is a stochastic jump process with arbitrary distributions of jump lengths and waiting times.^[1]^[2]^[3] More generally it can be seen to be a special case of a Markov renewal process.

Motivation[edit]

CTRW was introduced by Montroll and Weiss^[4] as a generalization of physical diffusion processes to effectively describe anomalous diffusion, i.e., the super- and sub-diffusive cases. An equivalent formulation of the CTRW is given by generalized master equations.^[5] A connection between CTRWs and diffusion equations with fractional time derivatives has been established.^[6] Similarly, time-space fractional diffusion equations can be considered as CTRWs with continuously distributed jumps or continuum approximations of CTRWs on lattices.^[7]

Formulation[edit]

A simple formulation of a CTRW is to consider the stochastic process $X(t)$ defined by

X(t)=X_{0}+\sum _{i=1}^{N(t)}\Delta X_{i},

whose increments $\Delta X_{i}$ are iid random variables taking values in a domain $\Omega$ and $N(t)$ is the number of jumps in the interval $(0,t)$ . The probability for the process taking the value $X$ at time $t$ is then given by

P(X,t)=\sum _{n=0}^{\infty }P(n,t)P_{n}(X).

Here $P_{n}(X)$ is the probability for the process taking the value $X$ after $n$ jumps, and $P(n,t)$ is the probability of having $n$ jumps after time $t$ .

Montroll–Weiss formula[edit]

We denote by $\tau$ the waiting time in between two jumps of $N(t)$ and by $\psi (\tau )$ its distribution. The Laplace transform of $\psi (\tau )$ is defined by

{\tilde {\psi }}(s)=\int _{0}^{\infty }d\tau \,e^{-\tau s}\psi (\tau ).

Similarly, the characteristic function of the jump distribution $f(\Delta X)$ is given by its Fourier transform:

{\hat {f}}(k)=\int _{\Omega }d(\Delta X)\,e^{ik\Delta X}f(\Delta X).

One can show that the Laplace–Fourier transform of the probability $P(X,t)$ is given by

{\hat {\tilde {P}}}(k,s)={\frac {1-{\tilde {\psi }}(s)}{s}}{\frac {1}{1-{\tilde {\psi }}(s){\hat {f}}(k)}}.

The above is called the Montroll–Weiss formula.

Examples[edit]

References[edit]

^ Klages, Rainer; Radons, Guenther; Sokolov, Igor M. (2008-09-08). Anomalous Transport: Foundations and Applications. ISBN 9783527622986.
^ Paul, Wolfgang; Baschnagel, Jörg (2013-07-11). Stochastic Processes: From Physics to Finance. Springer Science & Business Media. pp. 72–. ISBN 9783319003276. Retrieved 25 July 2014.
^ Slanina, Frantisek (2013-12-05). Essentials of Econophysics Modelling. OUP Oxford. pp. 89–. ISBN 9780191009075. Retrieved 25 July 2014.
^ Elliott W. Montroll; George H. Weiss (1965). "Random Walks on Lattices. II". J. Math. Phys. 6 (2): 167. Bibcode:1965JMP.....6..167M. doi:10.1063/1.1704269.
^ . M. Kenkre; E. W. Montroll; M. F. Shlesinger (1973). "Generalized master equations for continuous-time random walks". Journal of Statistical Physics. 9 (1): 45–50. Bibcode:1973JSP.....9...45K. doi:10.1007/BF01016796.
^ Hilfer, R.; Anton, L. (1995). "Fractional master equations and fractal time random walks". Phys. Rev. E. 51 (2): R848–R851. Bibcode:1995PhRvE..51..848H. doi:10.1103/PhysRevE.51.R848.
^ Gorenflo, Rudolf; Mainardi, Francesco; Vivoli, Alessandro (2005). "Continuous-time random walk and parametric subordination in fractional diffusion". Chaos, Solitons & Fractals. 34 (1): 87–103. arXiv:cond-mat/0701126. Bibcode:2007CSF....34...87G. doi:10.1016/j.chaos.2007.01.052.

[klages-1] Klages, Rainer; Radons, Guenther; Sokolov, Igor M. (2008-09-08). Anomalous Transport: Foundations and Applications. ISBN 9783527622986.

[PaulBaschnagel2013-2] Paul, Wolfgang; Baschnagel, Jörg (2013-07-11). Stochastic Processes: From Physics to Finance. Springer Science & Business Media. pp. 72–. ISBN 9783319003276. Retrieved 25 July 2014.

[Slanina2013-3] Slanina, Frantisek (2013-12-05). Essentials of Econophysics Modelling. OUP Oxford. pp. 89–. ISBN 9780191009075. Retrieved 25 July 2014.

[4] Elliott W. Montroll; George H. Weiss (1965). "Random Walks on Lattices. II". J. Math. Phys. 6 (2): 167. Bibcode:1965JMP.....6..167M. doi:10.1063/1.1704269.

[5] . M. Kenkre; E. W. Montroll; M. F. Shlesinger (1973). "Generalized master equations for continuous-time random walks". Journal of Statistical Physics. 9 (1): 45–50. Bibcode:1973JSP.....9...45K. doi:10.1007/BF01016796.

[6] Hilfer, R.; Anton, L. (1995). "Fractional master equations and fractal time random walks". Phys. Rev. E. 51 (2): R848–R851. Bibcode:1995PhRvE..51..848H. doi:10.1103/PhysRevE.51.R848.

[7] Gorenflo, Rudolf; Mainardi, Francesco; Vivoli, Alessandro (2005). "Continuous-time random walk and parametric subordination in fractional diffusion". Chaos, Solitons & Fractals. 34 (1): 87–103. arXiv:cond-mat/0701126. Bibcode:2007CSF....34...87G. doi:10.1016/j.chaos.2007.01.052.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

@@ Line 1: / Line 1: @@
+{{Short description|Random walk with random time between jumps}}
-In mathematics, a '''continuous-time random walk''' ('''CTRW''') is a generalization of a [[stochastic]] [[jump process]] with arbitrary distributions of jump lengths and waiting times.<ref name="klages">{{cite book|last1=Klages|first1=Rainer|last2=Radons|first2=Guenther|first3=Igor M.|last3=Sokolov|title=Anomalous Transport: Foundations and Applications|url=http://books.google.co.uk/books?id=N1xD7ay06Z4C}}</ref><ref name="PaulBaschnagel2013">{{cite book|last1=Paul|first1=Wolfgang|last2=Baschnagel|first2=Jörg|title=Stochastic Processes: From Physics to Finance|url=http://books.google.com/books?id=OWANAAAAQBAJ&pg=PA72|accessdate=25 July 2014|date=2013-07-11|publisher=Springer Science & Business Media|isbn=9783319003276|pages=72–}}</ref><ref name="Slanina2013">{{cite book|last=Slanina|first=Frantisek|title=Essentials of Econophysics Modelling|url=http://books.google.com/books?id=3CJoAgAAQBAJ&pg=PA89|accessdate=25 July 2014|date=2013-12-05|publisher=OUP Oxford|isbn=9780191009075|pages=89–}}</ref>
+In mathematics, a '''continuous-time random walk''' ('''CTRW''') is a generalization of a [[random walk]] where the wandering particle waits for a random time between jumps. It is a [[stochastic]] [[jump process]] with arbitrary distributions of jump lengths and waiting times.<ref name="klages">{{cite book|last1=Klages|first1=Rainer|last2=Radons|first2=Guenther|first3=Igor M.|last3=Sokolov|title=Anomalous Transport: Foundations and Applications|url=https://books.google.com/books?id=N1xD7ay06Z4C|isbn=9783527622986|date=2008-09-08}}</ref><ref name="PaulBaschnagel2013">{{cite book|last1=Paul|first1=Wolfgang|last2=Baschnagel|first2=Jörg|title=Stochastic Processes: From Physics to Finance|url=https://books.google.com/books?id=OWANAAAAQBAJ&pg=PA72|accessdate=25 July 2014|date=2013-07-11|publisher=Springer Science & Business Media|isbn=9783319003276|pages=72–}}</ref><ref name="Slanina2013">{{cite book|last=Slanina|first=Frantisek|title=Essentials of Econophysics Modelling|url=https://books.google.com/books?id=3CJoAgAAQBAJ&pg=PA89|accessdate=25 July 2014|date=2013-12-05|publisher=OUP Oxford|isbn=9780191009075|pages=89–}}</ref> More generally it can be seen to be a special case of a [[Markov renewal process]].
 == Motivation ==
-CTRW was introduced by [[Elliott Waters Montroll|Montroll]] and [[George Herbert Weiss|Weiss]] <ref>{{cite journal
+CTRW was introduced by [[Elliott Waters Montroll|Montroll]] and [[George Herbert Weiss|Weiss]]<ref>{{cite journal
- | last = Elliott W. Montroll and George H. Weiss
+ |author1=Elliott W. Montroll |author2=George H. Weiss | title = Random Walks on Lattices. II
- | first =
- | authorlink =
- | title = Random Walks on Lattices. II
  | journal = J. Math. Phys.
  | volume = 6
- | issue =
+ | issue =2
  | pages = 167
- | publisher =
- | location =
  | date = 1965
- | language =
- | url = http://dx.doi.org/10.1063/1.1704269
- | jstor =
- | issn =
  | doi = 10.1063/1.1704269
+ | bibcode =1965JMP.....6..167M}}</ref> as a generalization of physical diffusion processes to effectively describe [[anomalous diffusion]], i.e., the super- and sub-diffusive cases. An equivalent formulation of the CTRW is given by generalized [[master equation]]s.<ref>{{cite journal
- | id =
+ |author1=. M. Kenkre |author2=E. W. Montroll |author3=M. F. Shlesinger | title = Generalized master equations for continuous-time random walks
- | mr =
- | zbl =
- | jfm =
- | accessdate = }}</ref> as a generalization of physical diffusion process to effectively describe [[anomalous diffusion]], i.e., the super- and sub-diffusive cases. An equivalent formulation of the CTRW is given by [[generalized master equation]]s. <ref>{{cite journal
- | last = . M. Kenkre, E. W. Montroll, M. F. Shlesinger
- | first =
- | authorlink =
- | title = Generalized master equations for continuous-time random walks
  | journal = Journal of Statistical Physics
  | volume = 9
  | issue = 1
- | pages =  45-50
+ | pages =  45–50
- | publisher =
- | location =
  | date =  1973
- | language =
- | url = http://link.springer.com/article/10.1007/BF01016796
- | jstor =
- | issn =
  | doi = 10.1007/BF01016796
+ | bibcode =1973JSP.....9...45K}}</ref> A connection between CTRWs and diffusion equations with [[fractional derivative|fractional time derivatives]] has been established.<ref>{{cite journal
- | id =
+ |author1=Hilfer, R.  |author2=Anton, L.
- | mr =
+ | title = Fractional master equations and fractal time random walks
- | zbl =
+ | journal = Phys. Rev. E
- | jfm =
- | accessdate = }}</ref>
+ | volume = 51
+ | issue = 2
-A connection between CTRWs and diffusion equations with [[fractional derivative|fractional time derivatives]] has been established. <ref>{{cite journal
- | last = Hilfer, R.
+ | pages = R848–R851
- | first =
+ | date = 1995
- | authorlink =
- | title = On fractional diffusion and continuous time random walks
- | journal = Physica A
- | volume = 329
- | issue = 1
- | pages = 35-40
- | publisher =
- | location =
- | date = 2003
- | language =
- | url = http://link.aps.org/doi/10.1103/PhysRevE.51.R848
- | jstor =
- | issn =
  | doi = 10.1103/PhysRevE.51.R848
+ | bibcode =1995PhRvE..51..848H}}</ref> Similarly, [[Fractional calculus#Time-space fractional diffusion equation models|time-space fractional diffusion equations]] can be considered as CTRWs with continuously distributed jumps or continuum approximations of CTRWs on lattices.<ref>{{cite journal
- | id =
+ | last1 = Gorenflo | first1 = Rudolf | author1-link = Rudolf Gorenflo
- | mr =
+ | last2 =Mainardi | first2 = Francesco
- | zbl =
+ | last3 = Vivoli | first3 = Alessandro
- | jfm =
- | accessdate = }}</ref>
-Similarly, [[Fractional_calculus#Time-space_fractional_diffusion_equation_models|time-space fractional diffusion equations]] can be considered as CTRWs with continuously distributed jumps or continuum approximations of CTRWs on lattices.
-<ref>{{cite journal
- | last = Gorenflo, Rudolf and Mainardi, Francesco and Vivoli, Alessandro
- | first =
- | authorlink =
  | title = Continuous-time random walk and parametric subordination in fractional diffusion
- | journal = Chaos, Solitons \& Fractals
+ | journal = Chaos, Solitons & Fractals
  | volume = 34
  | issue = 1
- | pages = 87-103
+ | pages = 87–103
- | publisher = Elsevier
- | location =
  | date = 2005
- | language =
- | url =
- | jstor =
- | issn =
  | doi = 10.1016/j.chaos.2007.01.052
+ | arxiv =cond-mat/0701126| bibcode =2007CSF....34...87G}}</ref>
- | id =
- | mr =
- | zbl =
- | jfm =
- | accessdate = }}</ref>
 == Formulation ==
@@ Line 108: / Line 58: @@
 Here <math>P_n(X)</math> is the probability for the process taking the value <math>X</math> after <math>n</math> jumps, and <math>P(n,t)</math> is the probability of having <math>n</math> jumps after time <math>t</math>.
-== Montroll-Weiss formula ==
+== Montroll–Weiss formula ==
-Denoting the waiting time distribution in between two jumps of <math>N(t)</math> by <math>\psi(\tau)</math>, its [[Laplace transform]] is defined by
+We denote by <math>\tau</math> the waiting time in between two jumps of <math>N(t)</math> and by <math>\psi(\tau)</math> its distribution. The [[Laplace transform]] of <math>\psi(\tau)</math> is defined by
 :<math>
-{\psi}(s)=\int_0^{\infty} d\tau e^{-\tau s} \psi(\tau).
+\tilde{\psi}(s)=\int_0^{\infty} d\tau \, e^{-\tau s} \psi(\tau).
 </math>
-Similarly, for the jump distribution <math> f(\Delta X) </math> of the increments, the [[Fourier transform]] is given by
+Similarly, the [[Characteristic function (probability theory)|characteristic function]] of the jump distribution <math> f(\Delta X) </math> is given by its [[Fourier transform]]:
 :<math>
-{f}(k)=\int_\Omega d(\Delta X) e^{i k\Delta X} f(\Delta X).
+\hat{f}(k)=\int_\Omega d(\Delta X) \, e^{i k\Delta X} f(\Delta X).
 </math>
-One can show that the Laplace-Fourier transform of the probability <math>P(X,t)</math> is given by
+One can show that the Laplace–Fourier transform of the probability <math>P(X,t)</math> is given by
 :<math>
-\hat{P}(k,s) = \frac{1-\Psi(s)}{s} \frac{1}{1-\Psi(s)f(k)}.
+\hat{\tilde{P}}(k,s) = \frac{1-\tilde{\psi}(s)}{s} \frac{1}{1-\tilde{\psi}(s)\hat{f}(k)}.
 </math>
-The above is called [[Elliott Waters Montroll|Montroll]]-[[George Herbert Weiss|Weiss]] formula.
+The above is called the [[Elliott Waters Montroll|Montroll]]–[[George Herbert Weiss|Weiss]] formula.
 == Examples ==
-The [[Wiener process]] is the standard example of a continuous time random walk in which the waiting times are [[exponential distribution|exponential]] and the jumps are continuous and [[normal distribution|normally distributed]].
 == References ==
 {{reflist}}
-{{probability-stub}}
 {{Stochastic processes}}
-[[Category:Stochastic processes]]
+[[Category:Variants of random walks]]

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