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==Single Discretization Method==
==Single Discretization Method==


[[Abaqus]], [[ADINA]]<ref>{{cite web |url=http://www.adina.com/multiphysics.shtml |title=ADINA Multiphysics}}</ref>, [[ANSYS]] Multiphysics<ref>{{cite web |url=http://www.ansys.com/Products/multiphysics.asp |title=ANSYS Multiphysics |publisher=ANSYS, Inc |accessdate=2008-10-30}}</ref> [[CFD-ACE+]], [[CFD-FASTRAN]], [[COMSOL Multiphysics]] <ref>{{cite web |url=http://www.comsol.com/ |title=COMSOL Multiphysics |publisher=COMSOL, Inc. |accessdate=2009-05-30}}</ref>, [[Flexpde|FlexPDE]], [[LS-DYNA]], [[NEi Nastran]], [[Idc-sac simulation]] and OOFELIE<ref>{{cite web |url=http://www.samcef.com/en/pss.php?ID=69&W=products |title=OOFELIE |accessdate=2008-10-30 |publisher= Samtech Group}}</ref> are some examples of commercially available software packages for simulating multiphysics models. These software packages mainly rely on the [[Finite Element Method]] or similar commonplace numerical methods for simulating coupled physics: thermal stress, electromechanical interaction, fluid structure interaction (FSI), fluid flow with heat transport and chemical reactions, electromagnetic fluids (magnetohydrodynamics or plasma), electromagnetically induced heating. In many cases, to get accurate results, it is important to include mutual dependencies where the material properties significant for one field (such as the electric field) vary with the value of another field (such as temperature) and vice versa.
[[Abaqus]], [[ADINA]]<ref>{{cite web |url=http://www.adina.com/multiphysics.shtml |title=ADINA Multiphysics}}</ref>, [[ANSYS]] Multiphysics<ref>{{cite web |url=http://www.ansys.com/Products/multiphysics.asp |title=ANSYS Multiphysics |publisher=ANSYS, Inc |accessdate=2008-10-30}}</ref> [[CFD-ACE+]], [[CFD-FASTRAN]], [[COMSOL Multiphysics]] <ref>{{cite web |url=http://www.comsol.com/ |title=COMSOL Multiphysics |publisher=COMSOL, Inc. |accessdate=2009-05-30}}</ref>, [[Flexpde|FlexPDE]], [[LS-DYNA]], [[NEi Nastran]], [[Idc-sac simulation]] and OOFELIE<ref>{{cite web |url=http://www.open-engineering.com |title=Oofelie |accessdate=2010-01-20 |publisher= Open Engineering}}</ref> are some examples of commercially available software packages for simulating multiphysics models. These software packages mainly rely on the [[Finite Element Method]] or similar commonplace numerical methods for simulating coupled physics: thermal stress, electromechanical interaction, fluid structure interaction (FSI), fluid flow with heat transport and chemical reactions, electromagnetic fluids (magnetohydrodynamics or plasma), electromagnetically induced heating. In many cases, to get accurate results, it is important to include mutual dependencies where the material properties significant for one field (such as the electric field) vary with the value of another field (such as temperature) and vice versa.


==Multiple Discretization Methods==
==Multiple Discretization Methods==

Revision as of 14:14, 11 February 2010

Multiphysics treats simulations that involve multiple physical models or multiple simultaneous physical phenomena. For example, combining chemical kinetics and fluid mechanics or combining finite elements with molecular dynamics. Multiphysics typically involves solving coupled systems of partial differential equations.

Almost any physical simulation involves coupled systems, like E and B (electric and magnetic) fields for electromagnetism or pressure and velocity for sound or the real and the imaginary part of the quantum mechanical wave function. Another case is the mean field approximation for the electronic structure of atoms, where the electric field and the electron wave functions are coupled.

Single Discretization Method

Abaqus, ADINA[1], ANSYS Multiphysics[2] CFD-ACE+, CFD-FASTRAN, COMSOL Multiphysics [3], FlexPDE, LS-DYNA, NEi Nastran, Idc-sac simulation and OOFELIE[4] are some examples of commercially available software packages for simulating multiphysics models. These software packages mainly rely on the Finite Element Method or similar commonplace numerical methods for simulating coupled physics: thermal stress, electromechanical interaction, fluid structure interaction (FSI), fluid flow with heat transport and chemical reactions, electromagnetic fluids (magnetohydrodynamics or plasma), electromagnetically induced heating. In many cases, to get accurate results, it is important to include mutual dependencies where the material properties significant for one field (such as the electric field) vary with the value of another field (such as temperature) and vice versa.

Multiple Discretization Methods

There are cases where each subset of partial differential equations has different mathematical behavior, for example when compressible fluid flow is coupled with structural analysis or heat transfer. To perform an optimal simulation in those cases, a different discretization procedure must be applied to each subset. For example, the compressible flow is discretized with a finite volume method and the conjugate heat transfer with a finite element analysis. Coolfluid is simulation environment developed by the von Karman Institute that supports such multiphysics and multi-method discretization.

References

  1. ^ "ADINA Multiphysics".
  2. ^ "ANSYS Multiphysics". ANSYS, Inc. Retrieved 2008-10-30.
  3. ^ "COMSOL Multiphysics". COMSOL, Inc. Retrieved 2009-05-30.
  4. ^ "Oofelie". Open Engineering. Retrieved 2010-01-20.
  • Susan L. Graham, Marc Snir, and Cynthia A. Patterson (Editors), Getting Up to Speed: The Future of Supercomputing, Appendix D. The National Academies Press, Washington DC, 2004. ISBN 0-309-09502-6.
  • Paul Lethbridge, Multiphysics Analysis, p26, The Industrial Physicist, Dec 2004/Jan 2005, [1]
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