Hybrid multiscale methods II. kinetic equations

Giacomo Dimarco; Lorenzo Pareschi

doi:10.1137/070680916

Hybrid multiscale methods II. kinetic equations

Giacomo Dimarco
, Lorenzo Pareschi

University of Ferrara

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

54 Scopus citations

Abstract

In this work we consider the development of a new family of hybrid numerical methods for the solution of kinetic equations which involves different scales. The basic idea is to couple macroscopic and microscopic models in all cases in which the macroscopic model does not provide correct results. The key aspect in the development of the algorithms is the choice of a suitable hybrid representation of the solution and a merging of Monte Carlo methods in nonequilibrium regimes with deterministic methods in equilibrium ones. This approach permits us to treat efficiently both the microscopic and the macroscopic scales. Applications to the Boltzmann-BGK equation are presented to show the performance of the new methods.

Original language	English
Pages (from-to)	1169-1197
Number of pages	29
Journal	Multiscale Modeling and Simulation
Volume	6
Issue number	4
DOIs	https://doi.org/10.1137/070680916
State	Published - 2007
Externally published	Yes

Keywords

Boltzmann equation
Euler equation
Fluid-dynamic limit
Kinetic schemes
Monte Carlo methods
Multiscale methods

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10.1137/070680916

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abstract = "In this work we consider the development of a new family of hybrid numerical methods for the solution of kinetic equations which involves different scales. The basic idea is to couple macroscopic and microscopic models in all cases in which the macroscopic model does not provide correct results. The key aspect in the development of the algorithms is the choice of a suitable hybrid representation of the solution and a merging of Monte Carlo methods in nonequilibrium regimes with deterministic methods in equilibrium ones. This approach permits us to treat efficiently both the microscopic and the macroscopic scales. Applications to the Boltzmann-BGK equation are presented to show the performance of the new methods.",

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AU - Dimarco, Giacomo

AU - Pareschi, Lorenzo

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AB - In this work we consider the development of a new family of hybrid numerical methods for the solution of kinetic equations which involves different scales. The basic idea is to couple macroscopic and microscopic models in all cases in which the macroscopic model does not provide correct results. The key aspect in the development of the algorithms is the choice of a suitable hybrid representation of the solution and a merging of Monte Carlo methods in nonequilibrium regimes with deterministic methods in equilibrium ones. This approach permits us to treat efficiently both the microscopic and the macroscopic scales. Applications to the Boltzmann-BGK equation are presented to show the performance of the new methods.

KW - Boltzmann equation

KW - Euler equation

KW - Fluid-dynamic limit

KW - Kinetic schemes

KW - Monte Carlo methods

KW - Multiscale methods

UR - https://www.scopus.com/pages/publications/55249102480

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JO - Multiscale Modeling and Simulation

JF - Multiscale Modeling and Simulation

IS - 4

ER -

Hybrid multiscale methods II. kinetic equations

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Keywords

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