Commit e405fa97 authored by Boris Pek's avatar Boris Pek

Imported Upstream version 7.0.svn.6034+dfsg

parent a0800406
......@@ -115,6 +115,10 @@ contains(DEFINES, EG_PYTHONQT) {
#------------------------------------------------------------------------------
win32: LIBS += -lpsapi
#------------------------------------------------------------------------------
# OpenGL GLU
#------------------------------------------------------------------------------
unix: LIBS += -lGLU
#------------------------------------------------------------------------------
# Input files:
#------------------------------------------------------------------------------
......
......@@ -94,7 +94,7 @@
<Parameter Widget="Edit" Enabled="True" Visible="True">
<Name>Capacitance Body</Name>
<Whatis> This keyword should be provided for capacitance matrix computation only. The numbers should provide continous numbering from 1 to the total number of bodies. Ground may be defined with value 0 or by explicitely setting potential to zero somewhere.</Whatis>
<Whatis> This keyword should be provided for capacitance matrix computation only. The numbers should provide continuous numbering from 1 to the total number of bodies. Ground may be defined with value 0 or by explicitely setting potential to zero somewhere.</Whatis>
</Parameter>
<Parameter Widget="Label" > <Name> Neumann conditions </Name> </Parameter>
......@@ -102,7 +102,14 @@
<Name> Electric Flux </Name>
<Whatis> Give electric flux equivalent to the surface charge density. </Whatis>
</Parameter>
</BoundaryCondition>
<Parameter Widget="CheckBox" >
<Name> Electric Infinity BC </Name>
<Type> Logical </Type>
<Whatis> Use a far field condition for the electric flux. </Whatis>
</Parameter>
</BoundaryCondition>
</PDE>
</edf>
......
<?xml version='1.0' encoding='UTF-8'?>
<!DOCTYPE edf>
<edf version="1.0" >
<PDE Name="MgDyn2D" >
<Name>MgDyn2D</Name>
<Material>
<Parameter Widget="Label" > <Name> Properties </Name> </Parameter>
<Parameter Widget="Edit" >
<Name> Reluctivity </Name>
<Type> String </Type>
<Whatis> Give the reluctivitity (inverse of permeability). </Whatis>
</Parameter>
<Parameter Widget="Edit" >
<Name> Relative Permeability </Name>
<Type> String </Type>
<Whatis> Give the relative permeability compared to vacuum. </Whatis>
</Parameter>
<Parameter Widget="Edit" >
<Name> Electric Conductivity </Name>
<Type> String </Type>
<Whatis> Give the electric conductivity. </Whatis>
</Parameter>
<Parameter Widget="Edit" >
<Name> Magnetization 1</Name>
<Type> String </Type>
<Whatis> Give the magnetization in x-direction. </Whatis>
</Parameter>
<Parameter Widget="Edit" >
<Name> Magnetization 2</Name>
<Type> String </Type>
<Whatis> Give the magnetization in y-direction. </Whatis>
</Parameter>
<Parameter Widget="Edit" >
<Name> H-B Curve</Name>
<Type> String </Type>
<Whatis> Give the H-B Curve as a cubic spline. </Whatis>
</Parameter>
</Material>
<BodyForce>
<Parameter Widget="Label" > <Name> Properties </Name> </Parameter>
<Parameter Widget="Edit" >
<Name> Current Density </Name>
<Type> String </Type>
<Whatis> Give the current density. </Whatis>
</Parameter>
<Parameter Widget="CheckBox" >
<Name> Calculate Potential </Name>
<Type> Logical </Type>
<Whatis> Calculate the potential. </Whatis>
</Parameter>
</BodyForce>
<InitialCondition>
<Parameter Widget="Label" > <Name> Properties </Name> </Parameter>
<Parameter Widget="Edit" >
<Name> Az </Name>
<Type> String </Type>
<Whatis> Give the initial condition for the vector potential. </Whatis>
</Parameter>
</InitialCondition>
<Solver>
<Parameter Widget="Edit" >
<Name> Procedure </Name>
<DefaultValue> "MagnetoDynamics2D" "MagnetoDynamics2D" </DefaultValue>
</Parameter>
<Parameter Widget="Edit">
<Name> Variable </Name>
<DefaultValue> Az </DefaultValue>
</Parameter>
</Solver>
<BoundaryCondition>
<Parameter Widget="Label" > <Name> Dirichlet conditions </Name> </Parameter>
<Parameter Widget="Edit">
<Name> Az </Name>
<Whatis> Give vector potential value for this boundary. </Whatis>
</Parameter>
<Parameter Widget="Edit">
<Name> Az Condition </Name>
<Whatis> If the given value is less than zero, apply flux condition insted of the Dirichlet Condition. To be generally useful space and/or time varying values may be given. </Whatis>
</Parameter>
<Parameter Widget="Label" > <Name> Neumann conditions </Name> </Parameter>
<Parameter Widget="CheckBox" >
<Name> Infinity BC </Name>
<Type> Logical </Type>
<Whatis> Use a farfield condition for the vector potential. </Whatis>
</Parameter>
</BoundaryCondition>
</PDE>
<PDE Name="MgDyn2DPost" >
<Name>MgDyn2DPost</Name>
<Solver>
<Parameter Widget="Edit" >
<Name> Procedure </Name>
<DefaultValue> "MagnetoDynamics2D" "BSolver" </DefaultValue>
</Parameter>
<Parameter Widget="CheckBox">
<Name> Discontinuous Galerkin </Name>
<Type> Logical </Type>
<Whatis> To show discontinuities use DG for computation of electric fields</Whatis>
</Parameter>
<Parameter Widget="CheckBox">
<Name> Average Within Materials </Name>
<Type> Logical </Type>
<Whatis> In conjunction with DG apply averaging but only within materials.</Whatis>
</Parameter>
</Solver>
</PDE>
</edf>
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......@@ -25,7 +25,7 @@
<Parameter Widget="CheckBox" >
<Name> Filename Numbering </Name>
<Type> Logical </Type>
<Whatis> Number the files with continous numbering so that existing filenames are not used. False is the default. </Whatis>
<Whatis> Number the files with continuous numbering so that existing filenames are not used. False is the default. </Whatis>
</Parameter>
<Parameter Widget="CheckBox" >
......
<?xml version='1.0' encoding='UTF-8'?>
<!DOCTYPE edf>
<edf version="1.0" >
<PDE Name="SST-K-Omega" >
<Name>SST K-Omega</Name>
<Equation>
<Parameter Widget="Label">
<Name> Free text input </Name>
</Parameter>
<Parameter Widget="TextEdit" Enabled="True">
<Name> Free text </Name>
<Type> String </Type>
<Whatis> Free text is copied into the Equation-block of the SIF as such. </Whatis>
<StatusTip> Free text is copied into the Equation-block of the SIF as such. </StatusTip>
</Parameter>
</Equation>
<Solver>
<Parameter Widget="Edit" >
<Name > Procedure </Name>
<DefaultValue> "SSTKOmega" "SSTKOmega" </DefaultValue>
</Parameter>
<Parameter Widget="Label"> <Name>Additional Variables</Name> </Parameter>
<Parameter Widget="Edit">
<Name> Exported Variable 1 </Name>
<Activate> /SST-K-Omega/Solver/Exported Variable 2</Activate>
</Parameter>
<Parameter Widget="Edit" Enabled="False" Visible="False">
<Name> Exported Variable 2 </Name>
<Activate> /SST-K-Omega/Solver/Exported Variable 3</Activate>
</Parameter>
<Parameter Widget="Edit" Enabled="False" Visible="False">
<Name> Exported Variable 3 </Name>
<Activate> /SST-K-Omega/Solver/Exported Variable 4</Activate>
</Parameter>
<Parameter Widget="Edit" Enabled="False" Visible="False">
<Name> Exported Variable 4 </Name>
<Activate> /SST-K-Omega/Solver/Exported Variable 5</Activate>
</Parameter>
<Parameter Widget="Edit" Enabled="False" Visible="False">
<Name> Exported Variable 5 </Name>
</Parameter>
<Parameter Widget="Label">
<Name> Free text input </Name>
</Parameter>
<Parameter Widget="TextEdit" Enabled="True">
<Name> Free text </Name>
<Type> String </Type>
<Whatis> Free text is copied into the Solver-block of the SIF as such. </Whatis>
<StatusTip> Free text is copied into the Solver-block of the SIF as such. </StatusTip>
</Parameter>
</Solver>
<BodyForce>
<Parameter Widget="Label">
<Name> Free text input </Name>
</Parameter>
<Parameter Widget="TextEdit" Enabled="True">
<Name> Free text </Name>
<Type> String </Type>
<Whatis> Free text is copied into the Body Force-block of the SIF as such. </Whatis>
<StatusTip> Free text is copied into the Body Force-block of the SIF as such. </StatusTip>
</Parameter>
</BodyForce>
<Material>
<Parameter Widget="Label" > <Name> Properties </Name> </Parameter>
<Parameter Widget="Edit" >
<Name> Turbulent Prandtl Number </Name>
</Parameter>
<Parameter Widget="Edit" >
<Name> Dissipation Buoancy Coefficient </Name>
</Parameter>
<Parameter Widget="Edit" >
<Name> KE Cmu </Name>
</Parameter>
<Parameter Widget="Label">
<Name> Free text input </Name>
</Parameter>
<Parameter Widget="TextEdit" Enabled="True">
<Name> Free text </Name>
<Type> String </Type>
<Whatis> Free text is copied into the Material-block of the SIF as such. </Whatis>
<StatusTip> Free text is copied into the Material-block of the SIF as such. </StatusTip>
</Parameter>
</Material>
<InitialCondition>
<Parameter Widget="Label" > <Name> Variables </Name> </Parameter>
<Parameter Widget="Edit">
<Name> Kinetic Energy </Name>
</Parameter>
<Parameter Widget="Edit">
<Name> Kinetic Dissipation </Name>
</Parameter>
<Parameter Widget="Edit">
<Name> Wall Distance </Name>
</Parameter>
<Parameter Widget="Label">
<Name> Free text input </Name>
</Parameter>
<Parameter Widget="TextEdit" Enabled="True">
<Name> Free text </Name>
<Type> String </Type>
<Whatis> Free text is copied into the Initial Condition-block of the SIF as such. </Whatis>
<StatusTip> Free text is copied into the Initial Condition-block of the SIF as such. </StatusTip>
</Parameter>
</InitialCondition>
<BoundaryCondition>
<Parameter Widget="Label" > <Name> Dirichlet Conditions </Name> </Parameter>
<Parameter Widget="Edit">
<Name> Kinetic Energy </Name>
<Activate> /SST-K-Omega/BoundaryCondition/Kinetic Energy Condition </Activate>
</Parameter>
<Parameter Widget="Edit">
<Name> Kinetic Dissipation </Name>
<SifName> Kinetic Dissipation </SifName>
<Activate> /SST-K-Omega/BoundaryCondition/Kinetic Dissipation Condition </Activate>
</Parameter>
<Parameter Widget="Edit" Enabled="False">
<Name> Kinetic Energy Condition </Name>
<Whatis> If the given value is less than zero, apply flux condition insted of the Dirichlet Condition. To be generally useful space and/or time varying values may be given. </Whatis>
<StatusTip> Give kinetic energy condition value for this boundary. </StatusTip>
</Parameter>
<Parameter Widget="Edit" Enabled="False">
<Name> Kinetic Dissipation Condition </Name>
<Whatis> If the given value is less than zero, apply flux condition insted of the Dirichlet Condition. To be generally useful space and/or time varying values may be given. </Whatis>
<StatusTip> Give kinetic energy dissipation condition value for this boundary. </StatusTip>
</Parameter>
<Parameter Widget="Label" > <Name> Wall law </Name> </Parameter>
<Parameter Widget="CheckBox">
<Name> Komega Wall Law </Name>
<SifName> Wall Law </SifName>
<Activate> /SST-K-Omega/BoundaryCondition/Boundary Layer Thickness </Activate>
<Activate> /SST-K-Omega/BoundaryCondition/Su </Activate>
</Parameter>
<Parameter Widget="Edit" Enabled="False">
<Name> Boundary Layer Thickness </Name>
</Parameter>
<Parameter Widget="Edit" Enabled="False">
<Name> Boundary Layer Thickness </Name>
</Parameter>
<Parameter Widget="Label">
<Name> Free text input </Name>
</Parameter>
<Parameter Widget="TextEdit" Enabled="True">
<Name> Free text </Name>
<Type> String </Type>
<Whatis> Free text is copied into the Boundary Condition-block of the SIF as such. </Whatis>
<StatusTip> Free text is copied into the Boundary Condition-block of the SIF as such. </StatusTip>
</Parameter>
</BoundaryCondition>
</PDE>
</edf>
<
<!DOCTYPE egmaterials>
<materiallibrary>
<material name="Vacuum" >
<parameter name="Density" >0.0</parameter>
<parameter name="Relative Permittivity" >1.0</parameter>
<parameter name="Relative Permeability" >1.0</parameter>
</material>
<material name="Air (room temperature)" >
<parameter name="Density" >1.205</parameter>
<parameter name="Heat conductivity" >0.0257</parameter>
......@@ -10,6 +16,7 @@
<parameter name="Turbulent Prandtl number" >0.713</parameter>
<parameter name="Sound speed" >343.0</parameter>
<parameter name="Relative Permittivity" >1.00059</parameter>
<parameter name="Relative Permeability" >1.00000037</parameter>
</material>
<material name="Water (room temperature)" >
......@@ -21,6 +28,7 @@
<parameter name="Turbulent Prandtl number" >7.01</parameter>
<parameter name="Sound speed" >1497.0</parameter>
<parameter name="Relative Permittivity" >80.1</parameter>
<parameter name="Relative Permeability" >0.999992</parameter>
</material>
<material name="Glycerol (room temperature)" >
......@@ -52,9 +60,7 @@
<parameter name="Sound speed" >1430.0</parameter>
<parameter name="Relative Permittivity" >3.1</parameter>
</material>
<material name ="Aluminium (generic)" >
<parameter name="Density" >2700.0</parameter>
<parameter name="Youngs modulus" >70.0e9</parameter>
......@@ -67,6 +73,7 @@
<parameter name="Electric resistivity" >26.50e-9</parameter>
<parameter name="Electric conductivity" >37.73e6</parameter>
<parameter name="Sound speed" >5000.0</parameter>
<parameter name="Relative Permeability" >1.000022</parameter>
</material>
<material name="Steel (carbon - generic)">
......@@ -136,6 +143,21 @@
<parameter name="Electric resistivity" >16.78e-9</parameter>
<parameter name="Electric conductivity" >59.59e6</parameter>
<parameter name="Sound speed" >3810.0</parameter>
<parameter name="Relative Permeability" >0.999994</parameter>
</material>