static public void Simulate(CMshTriangleMesherDouble aMesher, vtkUnstructuredGrid anUnstructuredGrid, vtkRenderer aRenderer)
{
var T = new CPdeFieldDouble();
T.setMesh(aMesher.mesh());
T.setDiscretMethod(EDiscretMethod.DM_FEM);
T.setDiscretOrder(EDiscretOrder.DO_LINEAR);
T.setDiscretLocation(EDiscretLocation.DL_NODE);
T.setSimulationType(ESimulationType.ST_THERMAL);
T.setNbDofs(1);
// Set BC and initial conditions
T.setSize(T.mesh().nbNodes());
for (int i = 0; i < T.mesh().nbNodes(); ++i)
{
int aNodeId = T.mesh().nodeId(i);
var aNode = T.mesh().node(aNodeId);
if (Math.Abs(aNode.x() + 0.0) < 1E-6)
{
T.setFixedValue(i, 0.0);
}
if (Math.Abs(aNode.x() - 1.0) < 1E-6)
{
T.setFixedValue(i, 0.0);
}
if (Math.Abs(aNode.y() + 0.0) < 1E-6)
{
T.setFixedValue(i, 0.0);
}
if (Math.Abs(aNode.y() - 1.0) < 1E-6)
{
T.setFixedValue(i, 1.0);
}
T.setValue(i, 0.0);
}
// Steady conduction in a rectangle
var aPdeEquation = new CPdeEquationDouble(ENigMA.laplacian(T));
aPdeEquation.setElimination(T);
aPdeEquation.solve(T);
var sScalars = vtkFloatArray.New();
sScalars.SetNumberOfTuples(T.mesh().nbNodes());
for (int i = 0; i < T.mesh().nbNodes(); ++i)
{
int aNodeId = T.mesh().nodeId(i);
sScalars.SetTuple1(aNodeId, T.value(i));
}
anUnstructuredGrid.GetPointData().SetScalars(sScalars);
var aGeometryFilter = vtkGeometryFilter.New();
aGeometryFilter.SetInput(anUnstructuredGrid);
aGeometryFilter.Update();
var aBoundedFilter = vtkBandedPolyDataContourFilter.New();
aBoundedFilter.SetInput(aGeometryFilter.GetOutput());
aBoundedFilter.GenerateValues(24, sScalars.GetRange()[0], sScalars.GetRange()[1]);
var aLookupTable = vtkLookupTable.New();
aLookupTable.SetNumberOfColors(256);
aLookupTable.SetHueRange(0.667, 0.0);
aLookupTable.Build();
var aBandedMapper = vtkPolyDataMapper.New();
aBandedMapper.SetInputConnection(aBoundedFilter.GetOutputPort());
aBandedMapper.SetScalarModeToUsePointData();
aBandedMapper.SetScalarRange(sScalars.GetRange()[0], sScalars.GetRange()[1]);
aBandedMapper.SetLookupTable(aLookupTable);
// add actor to the renderer
var aMeshActor = vtkActor.New();
aRenderer.AddActor(aMeshActor);
aMeshActor.SetMapper(aBandedMapper);
var aScalarBarActor = vtkScalarBarActor.New();
aRenderer.AddActor(aScalarBarActor);
aScalarBarActor.SetLookupTable(aLookupTable);
aScalarBarActor.SetTitle("Temperature");
aScalarBarActor.SetNumberOfLabels(6);
aScalarBarActor.Modified();
}
private void Simulate(CMshTriangleMesherDouble aMesher, vtkUnstructuredGrid anUnstructuredGrid, vtkRenderer aRenderer)
{
var T = new CPdeFieldDouble();
T.setMesh(aMesher.mesh());
T.setDiscretMethod(EDiscretMethod.DM_FEM);
T.setDiscretOrder(EDiscretOrder.DO_LINEAR);
T.setDiscretLocation(EDiscretLocation.DL_NODE);
T.setSimulationType(ESimulationType.ST_THERMAL);
T.setNbDofs(1);
// Set BC and initial conditions
T.setSize(T.mesh().nbNodes());
for (int i = 0; i < T.mesh().nbNodes(); ++i)
{
int aNodeId = T.mesh().nodeId(i);
var aNode = T.mesh().node(aNodeId);
if (Math.Abs(aNode.x() + 0.0) < 1E-6)
{
T.setFixedValue(i, 0.0);
}
if (Math.Abs(aNode.x() - 1.0) < 1E-6)
{
T.setFixedValue(i, 0.0);
}
if (Math.Abs(aNode.y() + 0.0) < 1E-6)
{
T.setFixedValue(i, 0.0);
}
if (Math.Abs(aNode.y() - 1.0) < 1E-6)
{
T.setFixedValue(i, 0.0);
}
T.setValue(i, 1.0);
}
double rho = 1.0; // density
double Cp = 1.0; // specific heat
double k = 1.0; // conductivity
double time = 0.1;
int nIter = 10;
double dt = time / nIter;
// Unsteady conduction in a plate
for (int i = 0; i < nIter; ++i)
{
Debug.WriteLine("Time = " + dt * (i + 1));
var aTransientTerm = new CSleSystemDouble();
aTransientTerm = ENigMA.ddt(T);
aTransientTerm.Multiply(rho * Cp / dt);
var aDiffusionTerm = new CSleSystemDouble();
aDiffusionTerm = ENigMA.laplacian(T);
aDiffusionTerm.Multiply(k);
var aSystem = new CSleSystemDouble();
aSystem = aTransientTerm;
aSystem.Plus(aDiffusionTerm);
var aPdeEquation = new CPdeEquationDouble(aSystem);
aPdeEquation.setElimination(T);
aPdeEquation.solve(T);
}
var sScalars = vtkFloatArray.New();
sScalars.SetNumberOfTuples(T.mesh().nbNodes());
for (int i = 0; i < T.mesh().nbNodes(); ++i)
{
int aControlVolumeId = T.mesh().nodeId(i);
sScalars.SetTuple1(aControlVolumeId, T.value(i));
}
anUnstructuredGrid.GetPointData().SetScalars(sScalars);
var aGeometryFilter = vtkGeometryFilter.New();
aGeometryFilter.SetInput(anUnstructuredGrid);
aGeometryFilter.Update();
var aBoundedFilter = vtkBandedPolyDataContourFilter.New();
aBoundedFilter.SetInput(aGeometryFilter.GetOutput());
aBoundedFilter.GenerateValues(24, sScalars.GetRange()[0], sScalars.GetRange()[1]);
var aLookupTable = vtkLookupTable.New();
aLookupTable.SetNumberOfColors(256);
aLookupTable.SetHueRange(0.667, 0.0);
aLookupTable.Build();
var aBandedMapper = vtkPolyDataMapper.New();
aBandedMapper.SetInputConnection(aBoundedFilter.GetOutputPort());
aBandedMapper.SetScalarModeToUsePointData();
aBandedMapper.SetScalarRange(sScalars.GetRange()[0], sScalars.GetRange()[1]);
aBandedMapper.SetLookupTable(aLookupTable);
// add actor to the renderer
var MeshActor = vtkActor.New();
aRenderer.AddActor(MeshActor);
var MeshMapper = vtkDataSetMapper.New();
MeshMapper.SetInput(anUnstructuredGrid);
MeshActor.SetMapper(aBandedMapper);
}
static public void Simulate(CMshBasicMesherDouble aMesher, vtkUnstructuredGrid anUnstructuredGrid, vtkRenderer aRenderer)
{
var T = new CPdeFieldDouble();
aMesher.mesh().generateFaces(1E-12);
aMesher.mesh().calculateFaceCentroid();
aMesher.mesh().calculateElementCentroid();
T.setMesh(aMesher.mesh());
T.setDiscretMethod(EDiscretMethod.DM_FVM);
T.setDiscretOrder(EDiscretOrder.DO_LINEAR);
T.setDiscretLocation(EDiscretLocation.DL_ELEMENT_CENTER);
T.setSimulationType(ESimulationType.ST_THERMAL);
T.setNbDofs(1);
// Set BC and initial conditions
T.setSize(T.mesh().nbElements());
for (int i = 0; i < T.mesh().nbFaces(); ++i)
{
int aFaceId = T.mesh().faceId(i);
if (Math.Abs(T.mesh().faceCentroid(aFaceId).x() - 0.0) < 1E-6)
{
var aFixedTemperature = new CPdeBoundaryConditionDouble(EBoundaryConditionType.BT_GENERIC_FIXED_VALUE);
aFixedTemperature.addCondition(EConditionType.CT_GENERIC_FIXED_VALUE, 0.0);
T.addBCFace(aFaceId, aFixedTemperature);
}
if (Math.Abs(T.mesh().faceCentroid(aFaceId).x() - 1.0) < 1E-6)
{
var aFixedTemperature = new CPdeBoundaryConditionDouble(EBoundaryConditionType.BT_GENERIC_FIXED_VALUE);
aFixedTemperature.addCondition(EConditionType.CT_GENERIC_FIXED_VALUE, 0.0);
T.addBCFace(aFaceId, aFixedTemperature);
}
if (Math.Abs(T.mesh().faceCentroid(aFaceId).y() - 0.0) < 1E-6)
{
var aFixedTemperature = new CPdeBoundaryConditionDouble(EBoundaryConditionType.BT_GENERIC_FIXED_VALUE);
aFixedTemperature.addCondition(EConditionType.CT_GENERIC_FIXED_VALUE, 0.0);
T.addBCFace(aFaceId, aFixedTemperature);
}
if (Math.Abs(T.mesh().faceCentroid(aFaceId).y() - 1.0) < 1E-6)
{
var aFixedTemperature = new CPdeBoundaryConditionDouble(EBoundaryConditionType.BT_GENERIC_FIXED_VALUE);
aFixedTemperature.addCondition(EConditionType.CT_GENERIC_FIXED_VALUE, 1.0);
T.addBCFace(aFaceId, aFixedTemperature);
}
}
// Steady conduction in a rectangle
var aPdeEquation = new CPdeEquationDouble(ENigMA.laplacian(T));
aPdeEquation.solve(T);
var sScalars = vtkFloatArray.New();
sScalars.SetNumberOfTuples(T.mesh().nbElements());
for (int i = 0; i < T.mesh().nbElements(); ++i)
{
int anElementId = T.mesh().elementId(i);
sScalars.SetTuple1(anElementId, T.value(i));
}
anUnstructuredGrid.GetCellData().SetScalars(sScalars);
var aGeometryFilter = vtkGeometryFilter.New();
aGeometryFilter.SetInput(anUnstructuredGrid);
aGeometryFilter.Update();
var aCellDataToPointDataFilter1 = vtkCellDataToPointData.New();
aCellDataToPointDataFilter1.SetInputConnection(aGeometryFilter.GetOutputPort());
aCellDataToPointDataFilter1.Update();
var aBoundedFilter = vtkBandedPolyDataContourFilter.New();
aBoundedFilter.SetInput(aCellDataToPointDataFilter1.GetOutput());
aBoundedFilter.GenerateValues(24, sScalars.GetRange()[0], sScalars.GetRange()[1]);
var aLookupTable = vtkLookupTable.New();
aLookupTable.SetNumberOfColors(256);
aLookupTable.SetHueRange(0.667, 0.0);
aLookupTable.Build();
var aBandedMapper = vtkPolyDataMapper.New();
aBandedMapper.SetInputConnection(aBoundedFilter.GetOutputPort());
aBandedMapper.SetScalarModeToUsePointData();
aBandedMapper.SetScalarRange(sScalars.GetRange()[0], sScalars.GetRange()[1]);
aBandedMapper.SetLookupTable(aLookupTable);
// add actor to the renderer
var aMeshActor = vtkActor.New();
aRenderer.AddActor(aMeshActor);
aMeshActor.SetMapper(aBandedMapper);
var aScalarBarActor = vtkScalarBarActor.New();
aRenderer.AddActor(aScalarBarActor);
aScalarBarActor.SetLookupTable(aLookupTable);
aScalarBarActor.SetTitle("Temperature");
aScalarBarActor.SetNumberOfLabels(6);
aScalarBarActor.Modified();
}
