The Features of Parallel Program for 3-D Modeling of Dynamic Processes in Porous Objects with Heat-Evolution

George Tarasov

doi:10.4028/www.scientific.net/KEM.685.109

Paper Titles

Boundary Design of Reflection Properties of a Steady-State Complex Heat Transfer Model
p.90

Numerical Study of Combustion Regimes and Heat Radiation of Cylindrical Porous Burner
p.94

Optimal Control Problem of Complex Heat Transfer for SP₁ Approximation
p.99

Numerical Simulation of Melting of Phase Change Material in a Square Cavity with a Heat Source
p.104

The Features of Parallel Program for 3-D Modeling of Dynamic Processes in Porous Objects with Heat-Evolution
p.109

Two Approaches for Simulating the Burning Surface in Gas Dynamics
p.114

Phenomenological Modeling of Rheological Properties of Polyetheretherketones Reinforced with High Modulus Carbon in the Machining Process by a Reversible Analysis Method
p.119

Decay of Low-Barrier Metastable State: Middle Friction
p.124

Corrections to Kramers Formula Describing the Decay Rate of a Metastable State
p.128

HomeKey Engineering MaterialsKey Engineering Materials Vol. 685The Features of Parallel Program for 3-D Modeling...

The Features of Parallel Program for 3-D Modeling of Dynamic Processes in Porous Objects with Heat-Evolution

Abstract:

The 3-D OpenMP parallel version of an algorithm for modeling dynamic processes in porous media with heat-evolution sources is presented. Parallel methods and techniques which were used for significant speed up of final results obtaining are described in detail. The performance results of parallel program for specific configuration of porous object are presented.

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High Technology: Research and Applications 2015

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Periodical:

Key Engineering Materials (Volume 685)

Pages:

109-113

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.685.109

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Online since:

February 2016

Authors:

George Tarasov*

Keywords:

Explicit Difference Scheme, Implicit Difference Scheme, OpenMP Technology, Parallel Programming, Porous Media

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