From stochastic processes to numerical methods: A new scheme for solving reaction subdiffusion fractional partial differential equations

C. N. Angstmann, I. C. Donnelly, B. I. Henry, B. A. Jacobs, T. A.M. Langlands, J. A. Nichols

Research output: Contribution to journalArticlepeer-review

26 Citations (Scopus)

Abstract

We have introduced a new explicit numerical method, based on a discrete stochastic process, for solving a class of fractional partial differential equations that model reaction subdiffusion. The scheme is derived from the master equations for the evolution of the probability density of a sum of discrete time random walks. We show that the diffusion limit of the master equations recovers the fractional partial differential equation of interest. This limiting procedure guarantees the consistency of the numerical scheme. The positivity of the solution and stability results are simply obtained, provided that the underlying process is well posed. We also show that the method can be applied to standard reaction-diffusion equations. This work highlights the broader applicability of using discrete stochastic processes to provide numerical schemes for partial differential equations, including fractional partial differential equations.

Original languageEnglish
Pages (from-to)508-534
Number of pages27
JournalJournal of Computational Physics
Volume307
DOIs
Publication statusPublished - 15 Feb 2016
Externally publishedYes

Keywords

  • Anomalous diffusion
  • Continuous time random walk
  • Discrete time random walk
  • Finite difference method
  • Fractional diffusion
  • Fractional reaction diffusion

ASJC Scopus subject areas

  • Numerical Analysis
  • Modeling and Simulation
  • Physics and Astronomy (miscellaneous)
  • General Physics and Astronomy
  • Computer Science Applications
  • Computational Mathematics
  • Applied Mathematics

Fingerprint

Dive into the research topics of 'From stochastic processes to numerical methods: A new scheme for solving reaction subdiffusion fractional partial differential equations'. Together they form a unique fingerprint.

Cite this