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−	The problem setup is based on a typical Carat++-Inputfile used for a single-field analysis.	+	{| border="1" cellpadding="3" cellspacing="0"
		+	|colspan="3" style="background:#efefef;"| Block Predictor: Defines a predictor for an exchanged Quantitiy used in the first inner itertation of a time step.
		+	|-
		+	!Type
		+	|''polynomial or newmark or adaptive''
		+	|Predictor type, for details see <ref name="Gallinger2010">Gallinger, T.G.: Effiziente Algorithmen zur partitionierten Lösung stark gekoppelter Probleme der Fluid-Struktur-Wechselwirkung, Dissertation, Lehrstuhl für Statik, Technische Universität München, 2010</ref>
		+	|-
		+	!Order - for Type polynomial and newmark
		+	|''int''
		+	|polynomial: 0, 1, 2, 3; newmark: 1, 2;
		+	|-
		+	!Beta - for Type newmark
		+	|''float''
		+	|time integration parameter of Newmark scheme, standard: 0.25
		+	|-
		+	!Gamma - for Type newmark
		+	|''float''
		+	|time integration parameter of Newmark scheme, standard: 0.50
		+	|-
		+	|}
−	To be specific for a coupled analysis, two steps have to made:
−	* The coupled interface hast to be defined. This is the geometric representation of the coupled surface between fluid and structure field.
−	* A FSI-analysis is chosen, which links to an basi analysis type, e.g. a static or dynamic analysis.
		+	{| border="1" cellpadding="3" cellspacing="0"
		+	|colspan="3" style="background:#efefef;"| Block CouplingAlgo: Defines a coupling algorithm for an exchanged Quantitiy used in every inner itertation except the first of a time step.
		+	|-
		+	!Type
		+	|''constant or aitken or quasinewton''
		+	|Coupling algorithm type, for details see <ref name="Gallinger2010">Gallinger, T.G.: Effiziente Algorithmen zur partitionierten Lösung stark gekoppelter Probleme der Fluid-Struktur-Wechselwirkung, Dissertation, Lehrstuhl für Statik, Technische Universität München, 2010</ref>
		+	|-
		+	!Factor - for Type constant, aitken and quasinewton
		+	|''float''
		+	|underrelaxation factor used always in constant relaxation, in the first iteration with Aitken and Quasi-Newton method
		+	|-
		+	!ConstRelax - for Type quasinewton
		+	|''yes or no''
		+	|use constant relaxation in first coupling iteration
		+	|-
		+	!NumHistoryDelta - for Type quasinewton
		+	|''int''
		+	|include delta information from preceeding timesteps into minimization problem
		+	|-
		+	!MinResChange - for Type quasinewton
		+	|''float''
		+	|dummy factor - not used
		+	|-
		+	|}
−	=== Interface Definition ===
−	The interface is the geometric definition of the physical surface between fluid and structure field. It is based on the already exisiting Finite element model. Note the following:	+	{| border="1" cellpadding="3" cellspacing="0"
		+	|colspan="3" style="background:#efefef;"| Block ConvergenceCalculation: Defines convergence properties for coupled computation.
		+	|-
		+	!By
		+	|''CoMA or Processgroup''
		+	|Which code performs convergence calculation
		+	|-
		+	!ProcessgroupID - for By processgroup
		+	|''int''
		+	|which group
		+	|-
		+	!Type - for By CoMA
		+	|''absolute or relative''
		+	|which convergence criterion should CoMA use, a absolute or relatve one
		+	|-
		+	!Limit - for By CoMA
		+	|''float''
		+	|convergence limit, if below=converged
		+	|-
		+	!CouplingSteps - for By CoMA
		+	|''int''
		+	|number of coupling steps (time steps) to be performed in total
		+	|-
		+	!MaxInnerLoopSteps - for By CoMA
		+	|''int''
		+	|number of maximum inner iteration loops
		+	|-
		+	|}
−	* Not all elements of the model have to be part of the interface. E.g. Shell and Membrane elements should be part of the model, because the surface type gives large influence from surrounding flow, but truss elements are not part, because wind influence on a truss may be neglected.
−	* Not all element types are suitable for usage within the interface. Currently only shell and membrane elements are supported.
−	* An export type has to be defined. Shell and membrane elements are defined by their mid-surface. It depends on the flow and the element thickness, if the mid-surface is a proper definition of the interface. If a very thin membrane element has flow influence only from one side, the mid-surface maybe a proper definition of the interface geometry. If a very thick shell is placed in a surrounding fluid (flow on top and bottom), neglecting the thickness may lead to large errors in the correct physical representation of the problem. Currently, three export types are available: (1) Use the mid-surface of the elements as the interface. (2) Do a blow-up of the mid-surface based on the thickness and a director on the surface to define a 3d representation of the model with a top and bottom surface. (3) Using approach (2) leads to wholes on the side parts of the interface. Close the whole by additional surface elements.
−	The interface contains different partitions, at least one. Every partition has a unique element type and a unique type of element treatment. A typical interface defintion in Carat++ looks like:	+	{| border="1" cellpadding="3" cellspacing="0"
−		+	|colspan="3" style="background:#efefef;"| Block Restart: Used for computation with restart possibility
−	<pre>	+	|-
−	EL-IF 1	+	!RestartRun
−	NIP 1 1 0 (1-15)  MSHTAG=1 BORDER=;	+	|''yes or no''
−	NIP 2 3 0 (20-30)  MSHTAG=1,1,2 BORDER=31,62;	+	|Is this run a restart run
−	</pre>	+	|-
−		+	!RestartFromStep - for RestartRun yes
−	This interface consists of two partitions. The first partition (NIP 1) has interface export type 1 (export mid-surface only), format type 0 (dummy), sonsists of elements 1-15, the tag of the surface mesh is 1 (used to match carat and Foam interface meshes) and no border definition is necessary.	+	|''int''
−	The second partition (NIP 2) has interface export type 3 (export top- and bottom surface and side mesh), format type 0 (dummy), consists of elements 20-30, the tag of the three surface meshes is 1 for the top mesh, 1 for the bottom mesh and 2 for the side mesh (used to match carat and Foam interface meshes). The side mesh is defined by defining nodes, which are part of the border.	+	|from which step should the restart be performed
−		+	|-
−	Hint: More details on the interface definition can be found in the diploma thesis of Rupert Fisch.	+	!RestartOutput
−		+	|''yes or no''
−	=== Analysis Definition ===	+	|shoul restart-information be written ot output
−		+	|-
−	Defining a coupled analysis, contains of two part:	+	!RestartFrequency - for RestartOutput yes
−		+	|''int''
−	* Defining a Analysis of type FSI as master analysis.	+	|write restart info every int step
−	* Defining a sub-analysis for the specific structure field behavior (static or dynamic).	+	|-
−		+	!RestartPath - for RestartOutput yes
−	The defintion of the master analysis:	+	|''string''
−	<pre>	+	|absolute or relative path to directory for output, created if necessary
−	PC-ANALYSIS 1: FSI	+	|-
−	ANALYSIS = PC-ANALYSIS 2	+	!RestartFileName - for RestartOutput yes
−	METHOD  = BLACKBOX  !BLACKBOX, SUBSPACE_LP, SUBSPACE_FD	+	|''string''
−	OUTPUT  = PC-OUT 1	+	|prefix of restart info file names
−	INTERFACE = EL-IF 1	+	|-
−	</pre>	+	!RestartInfoInstances - for RestartOutput yes
−		+	|''int''
−	The sub-analysis is given by Analysis 2. The method is given as black-box (standard). Additionally, the output and the interface have to be defined.	+	|instances of restart information in output files to be kept
		+	|-
		+	!PersistPredictorOrder - for RestartOutput yes
		+	|''yes or no''
		+	|write out all info necessary to preserve predictor order in restart
		+	|-
		+	|}
−	The sub-analysis block is the same as in a standard Carat++-analysis. Possible analysis types are static linear and static nonlinear and dynamic linear and nonlinear (all available time integration algorithms).	+	== References ==
−	* Hint 1: The specification of an end time in a dynamic analysis is necessary in the input block, but is overriden in the coupled analysis by CoMA.	+	<references/>
−	* Hint 2: The loads from the fluid are just added to the loads specified in the carat++-input file. So it is possible to add e.g. self weight to the structure model.	+

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Revision as of 10:31, 24 February 2011

Contents 1 Coupling Code CoMA 1.1 Installation and Compilation 1.2 Problem Setup 1.2.1 Input File: Compulsory Block Description 1.2.2 Input File: Optional Block Description 1.3 References

Coupling Code CoMA

CoMA (Coupling for Multiphysics Analysis) is a general code coupling tool, used in the simulation of surface coupled problems. It is developed since some years at the institute. The tasks of CoMA within a coupled analysis are:

• Control of the coupled computation and the single-field solvers
• Convergence control
• Coupling algorithms for implicit computations
• Data transfer between distributed interface meshes
• Communication between parallel single-field solvers and CoMA

This wiki should just give a short overview on how to use CoMA, being specific on FSI-simulation with Carat and OpenFOAM. Detailed information on programming concepts and theoretical aspects can be found in the dissertation of Thomas Gallinger.

Installation and Compilation

CoMA has to installed under Linux operating system, because FSI-jobs only run under Linux. There exists an svn-repository, which contains all CoMA sources. The svn-repository is hosted on the same server as the carat repository. The current IP is 129.187.141.99 and the folder is named "CoMA". Checkout the svn-repository. Open the file "makfile.in" in the src-directory. You have to adapt the variable "CoMA_DIR", which points to your CoMA installation path, and the variable "MPIHOME", pointing to your MPI installation path. Execute the shellscript "make_obj_directories" to set the directorires for the objety, and then type "make" to build CoMA software.

Problem Setup

The structure of the input file reflects the underlying programming concepts of CoMA. An example input file can be found in the svn-repository under the directory "example". The input file is block-structured. At least five different blocks have to specified:

• General
• Two Processgroups
• ExchangedQuantity
• Mapping
• Output

For an implicit FSI-simulation, three additional blocks have to be specified:

• ConvergenceCalculation
• Predictor
• CouplingAlgo

Input File: Compulsory Block Description

Block General: General control of application flow
Type	fsi or ffi or wind	defines MPI Ident tag of CoMA within MPI Environment, used by other codes to identify CoMA process
Method	implicit or explicit	implicit or explicit coupling, implicit with, explicit without inner iteration loops

Block Processgroup: Defines a group of processes, which belong to one field
ID	0 or 1	used to order processgroups and as reference for exchanged quantities
Name	string	for output only
InterfaceType	mpi or file	type of communication between CoMA and processgroup, Warning: type file only partly implemented
MPIIdentTag	1 or 2	used to identify processes of processgroup in MPI-universe

Block ExchangedQuantity: Defines a quantitiy to be exchanged between processgroups
ID	0 or 1 or 2 ...	used to order quantities (0 exchanged before 1 before 2...)
Name	string	for output only
Dimension	int	dofs per node, e.g. displacements 3
InterpolationType	1 or 2	1 = flux mapping (summation e.g. for forces), 2 = field mapping (interpolation e.g. for displacements)
SenderID	int	ID of processgroups, which sends this quantitiy
RecieverID	int	ID of processgroups, which recieves this quantitiy
MpiTagBasis	int	used for MPI-data exchange of this quantitiy
DoFType	node	dummy paramter, quantitiy specified per node
Predictor - optional parameter	yes or no	use a predictor for this quantitiy in the first inner iteration and do not recieve from sender, block "Predictor" is necessary
CouplingAlgo - optional parameter	yes or no	use a coupling algorithm for this quantitiy, block "CouplingAlgo" is necessary
Convergence - optional parameter	yes or no	use a convergence criterion for this quantitiy, block "ConvergenceCalculation" is necessary

Block Mapping: Defines mapping method of exchanged quantities between surface meshes.
Type	TNM or MM	TNM: Triangular Nonmatching Mesh Mapper, MM: Matching Meshes

Block Output: General output of CoMA for postprocessing and simulation control
Path	string	absolute or relative path to directory for output files, created if necessary
Name	string	prefix for output file names
Format	gid or vtk	write ouput in Gid- or Vtk(Paraview)-format, Warning: Vtk writes out the mesh in every step, so huge data amount possible
Frequency	int	ouput ever int step
Energy	yes or no	additional output of energy
Convergence	yes or no	write additional file Path/Name+.cc with iteration information
QuantityID	int	which quantity to examine in .cc-file
Dof	yes or no	write dof-history in .cc-file, yes -> define node by following four entries:
ProcessgroupIndex	int	processgroup of dof
MeshTagIndex	int	meshTag of dof
NodeIndex	int	node index of dof
DofIndex	int	dof index of dof

Input File: Optional Block Description

Block Predictor: Defines a predictor for an exchanged Quantitiy used in the first inner itertation of a time step.
Type	polynomial or newmark or adaptive	Predictor type, for details see [1]
Order - for Type polynomial and newmark	int	polynomial: 0, 1, 2, 3; newmark: 1, 2;
Beta - for Type newmark	float	time integration parameter of Newmark scheme, standard: 0.25
Gamma - for Type newmark	float	time integration parameter of Newmark scheme, standard: 0.50

Block CouplingAlgo: Defines a coupling algorithm for an exchanged Quantitiy used in every inner itertation except the first of a time step.
Type	constant or aitken or quasinewton	Coupling algorithm type, for details see [1]
Factor - for Type constant, aitken and quasinewton	float	underrelaxation factor used always in constant relaxation, in the first iteration with Aitken and Quasi-Newton method
ConstRelax - for Type quasinewton	yes or no	use constant relaxation in first coupling iteration
NumHistoryDelta - for Type quasinewton	int	include delta information from preceeding timesteps into minimization problem
MinResChange - for Type quasinewton	float	dummy factor - not used

Block ConvergenceCalculation: Defines convergence properties for coupled computation.
By	CoMA or Processgroup	Which code performs convergence calculation
ProcessgroupID - for By processgroup	int	which group
Type - for By CoMA	absolute or relative	which convergence criterion should CoMA use, a absolute or relatve one
Limit - for By CoMA	float	convergence limit, if below=converged
CouplingSteps - for By CoMA	int	number of coupling steps (time steps) to be performed in total
MaxInnerLoopSteps - for By CoMA	int	number of maximum inner iteration loops

Block Restart: Used for computation with restart possibility
RestartRun	yes or no	Is this run a restart run
RestartFromStep - for RestartRun yes	int	from which step should the restart be performed
RestartOutput	yes or no	shoul restart-information be written ot output
RestartFrequency - for RestartOutput yes	int	write restart info every int step
RestartPath - for RestartOutput yes	string	absolute or relative path to directory for output, created if necessary
RestartFileName - for RestartOutput yes	string	prefix of restart info file names
RestartInfoInstances - for RestartOutput yes	int	instances of restart information in output files to be kept
PersistPredictorOrder - for RestartOutput yes	yes or no	write out all info necessary to preserve predictor order in restart

References

1. ↑ ^{1.0 1.1} Gallinger, T.G.: Effiziente Algorithmen zur partitionierten Lösung stark gekoppelter Probleme der Fluid-Struktur-Wechselwirkung, Dissertation, Lehrstuhl für Statik, Technische Universität München, 2010

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