A second-order Monte Carlo method for the solution of the Ito stochastic differential equation

D. C. Haworth; S. B. Pope

doi:10.1080/07362998608809086

A second-order Monte Carlo method for the solution of the Ito stochastic differential equation

D. C. Haworth
, S. B. Pope

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

24 Scopus citations

Abstract

A difference approximation that is second-order accurate in the time step h is derived for the general Ito stochastic differential equation. The difference equation has the form of a second-order random walk in which the random terms are non-linear combinations of Gaussian random variables. For a wide class of problems, the transition pdf is joint-normal to second order in h; the technique then reduces to a Gaussian random walk, but its application is not limited to problems having a Gaussian solution. A large number of independent sample paths are generated in a Monte Carlo solution algorithm; any statistical function of the solution (e.g., moments or pdf's) can be estimated by ensemble averaging over these paths.

Original language	English (US)
Pages (from-to)	151-186
Number of pages	36
Journal	Stochastic Analysis and Applications
Volume	4
Issue number	2
DOIs	https://doi.org/10.1080/07362998608809086
State	Published - Jan 1 1986

All Science Journal Classification (ASJC) codes

Statistics and Probability
Statistics, Probability and Uncertainty
Applied Mathematics

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10.1080/07362998608809086

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title = "A second-order Monte Carlo method for the solution of the Ito stochastic differential equation",

abstract = "A difference approximation that is second-order accurate in the time step h is derived for the general Ito stochastic differential equation. The difference equation has the form of a second-order random walk in which the random terms are non-linear combinations of Gaussian random variables. For a wide class of problems, the transition pdf is joint-normal to second order in h; the technique then reduces to a Gaussian random walk, but its application is not limited to problems having a Gaussian solution. A large number of independent sample paths are generated in a Monte Carlo solution algorithm; any statistical function of the solution (e.g., moments or pdf's) can be estimated by ensemble averaging over these paths.",

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note = "Funding Information: ACKNOWLEDGMENTS This work was funded in part by the General Electric Corporation Research and Development Division under the grant {"}Turbulent Flow Modeling{"}. Computations supporting this research were performed on the Cornell Production Supercomputer Facility, which is supported in part by the National Science Foundation and the IBM Corporation.",

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N2 - A difference approximation that is second-order accurate in the time step h is derived for the general Ito stochastic differential equation. The difference equation has the form of a second-order random walk in which the random terms are non-linear combinations of Gaussian random variables. For a wide class of problems, the transition pdf is joint-normal to second order in h; the technique then reduces to a Gaussian random walk, but its application is not limited to problems having a Gaussian solution. A large number of independent sample paths are generated in a Monte Carlo solution algorithm; any statistical function of the solution (e.g., moments or pdf's) can be estimated by ensemble averaging over these paths.

AB - A difference approximation that is second-order accurate in the time step h is derived for the general Ito stochastic differential equation. The difference equation has the form of a second-order random walk in which the random terms are non-linear combinations of Gaussian random variables. For a wide class of problems, the transition pdf is joint-normal to second order in h; the technique then reduces to a Gaussian random walk, but its application is not limited to problems having a Gaussian solution. A large number of independent sample paths are generated in a Monte Carlo solution algorithm; any statistical function of the solution (e.g., moments or pdf's) can be estimated by ensemble averaging over these paths.

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A second-order Monte Carlo method for the solution of the Ito stochastic differential equation

Abstract

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