Fractional Fokker-Planck dynamics: Stochastic representation and computer simulation

Magdziarz, Marcin; Weron, Aleksander; Weron, Karina

doi:10.1103/physreve.75.016708

Cited by 232 publications

(319 citation statements)

References 18 publications

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“…The above relation is the extension of the similar behavior of stable subordinator and its inverse. This property is fully examined in [15]. The process {Z(t)} defined in (6) is called the subdiffusion process with time-dependent force and was considered in [10] not only for the case of the tempered stable distribution but for all infinitely divisible distributions of the subordinator.…”

Section: The Subordinated Process As a Limit Of The Ctrw Modelmentioning

confidence: 99%

Stochastic Modeling of Indoor Air Temperature

et al. 2013

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Temperature is one of the main parameters describing thermal comfort and indoor air quality. In this paper we propose an approach, based on a modification of the continuous time random walk, to model the indoor air temperature. We perform a statistical analysis of the recorded time series, that allows us to point out the main statistical properties of the recorded variable. The obtained conclusions about the nature of the process lead to a continuous time random walk, that in contrast to the classical approach, models time dependence of the jumps distribution. Moreover, we show that the waiting times can be modeled by a tempered stable distribution, which yields a subdiffusive behavior in short times and diffusive behavior in longer times. Finally, by conducting a simulation study we illustrate possible applications of the presented approach in the thermal comfort monitoring and forecasting.

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Section: The Subordinated Process As a Limit Of The Ctrw Modelmentioning

confidence: 99%

Stochastic Modeling of Indoor Air Temperature

et al. 2013

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“…In the last decade the anomalous diffusion processes were analyzed by various number of authors in many disciplines. For example the subordinated Brownian motion driven by inverse Lévy-stable subordinator was considered in [11,22,24,25], the inverse tempered stable subordinator was examined in [23,[26][27][28] while inverse gamma process was mentioned in [29]. The general case of Lévy processes that can play a role of inverse subordinators were explored for example in [30][31][32].…”

Section: Introductionmentioning

confidence: 99%

“…In the domain of anomalous diffusion the typical approach is based on continuous time random walk (CTRW), [20,21], and subordinated Lévy processes can be treat as a limit in distribution of CTRW, [22]. The key issue in the framework of CTRW as well as in subordination technique is the waiting-times distribution corresponding to observed constant time periods [23].…”

Section: Introductionmentioning

confidence: 99%

Arithmetic Brownian motion subordinated by tempered stable and inverse tempered stable processes

Wyłomańska

2012

Physica A: Statistical Mechanics and its Applications

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In the last decade the subordinated processes have become popular and found many practical applications. Therefore in this paper we examine two processes related to time-changed (subordinated) classical Brownian motion with drift (called arithmetic Brownian motion). The first one, so called normal tempered stable, is related to the tempered stable subordinator, while the second one -to the inverse tempered stable process. We compare the main properties (such as probability density functions, Laplace transforms, ensemble averaged mean squared displacements) of such two subordinated processes and propose the parameters' estimation procedures. Moreover we calibrate the analyzed systems to real data related to indoor air quality.

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“…However, the derivation of the HN function (1.2), based on the fractional Fokker-Planck equation (Kalmykov et al 2004) and the CTRW (Weron et al 2005;Jurlewicz et al 2008), does not lead to values of g > 1. Only recently, by employing the subordination approach Weron et al 2010), developed in the last decade in the theory of anomalous diffusion (Sokolov 2001(Sokolov , 2002Meerschaert et al 2002;Meerschaert & Scheffler 2004;Piryatinska et al 2005;Magdziarz & Weron 2006;Sokolov & Klafter 2006;Magdziarz et al 2007Magdziarz et al , 2008Lubelski et al 2008), has the effective picture underlying all typical and less typical relaxation patterns been found. In contrast to earlier studies (Weron & Kotulski 1996;Metzler et al 1999) where the anomalous-diffusion approach (based on a decoupled CTRW) has led to CC relaxation only, the compound subordination framework allows one to derive rigorously Weron et al 2010) the original HN function as well as the novel version…”

Section: Introductionmentioning

confidence: 99%

Clustered continuous-time random walks: diffusion and relaxation consequences

et al. 2012

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We present a class of continuous-time random walks (CTRWs), in which random jumps are separated by random waiting times. The novel feature of these CTRWs is that the jumps are clustered. This introduces a coupled effect, with longer waiting times separating larger jump clusters. We show that the CTRW scaling limits are time-changed processes. Their densities solve two different fractional diffusion equations, depending on whether the waiting time is coupled to the preceding jump, or the following one. These fractional diffusion equations can be used to model all types of experimentally observed two power-law relaxation patterns. The parameters of the scaling limit process determine the power-law exponents and loss peak frequencies.

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Fractional Fokker-Planck dynamics: Stochastic representation and computer simulation

Cited by 232 publications

References 18 publications

Stochastic Modeling of Indoor Air Temperature

Stochastic Modeling of Indoor Air Temperature

Arithmetic Brownian motion subordinated by tempered stable and inverse tempered stable processes

Clustered continuous-time random walks: diffusion and relaxation consequences

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