From: michael <michael@localhost.localdomain>
Date: Thu, 13 Jan 2022 17:31:40 +0000 (+0100)
Subject: Updated tests for gui
X-Git-Url: http://git.salome-platform.org/gitweb/?p=tools%2Fsolverlab.git;a=commitdiff_plain;h=c13202a770b57e7fc7a4700400ca1b70432e422a

Updated tests for gui
---

diff --git a/CoreFlows/examples/Python/DiffusionEquation/DiffusionEquation_2DSpherical.py b/CoreFlows/examples/Python/DiffusionEquation/DiffusionEquation_2DSpherical.py
index 8330537..fab72e4 100644
--- a/CoreFlows/examples/Python/DiffusionEquation/DiffusionEquation_2DSpherical.py
+++ b/CoreFlows/examples/Python/DiffusionEquation/DiffusionEquation_2DSpherical.py
@@ -5,7 +5,11 @@ import sys
 import solverlab
 
 #===============================================================================================================================
-# Name        : Finite Elements simulation of the 2D heat equation -\triangle T = f with Neumann boundary condition
+# Name        : Simulation of a 2D heat equation 
+# Description : Test solving the diffusion of the temperature T in a solid
+#               \rho cp dT/dt-\lambda\Delta T=\Phi + \lambda_{sf} (T_{fluid}-T_{solid}) 
+#               Neumann or Dirichlet boundary conditions
+#               Finite elements or finite volumes
 # Author      : Michaël Ndjinga
 # Copyright   : CEA Saclay 2021
 #================================================================================================================================
@@ -14,9 +18,9 @@ import solverlab
 def DiffusionEquation_2DSpherical(FECalculation, fileName):
 
 	""" Description : Test solving the diffusion of the temperature T in a solid (default is Uranium). 
-		Equation : Thermal diffusion equation  \rho cp dT/dt-\lambda\Delta T=\Phi + \lambda_{sf} (T_{fluid}-T)
-		        Heat capacity, density, and conductivity of the solid MUST be defined
-		        The solid may be extra refrigerated by a fluid with transfer coefficient using functions setFluidTemperature and setHeatTransfertCoeff
+		Equation : Thermal diffusion equation  \rho cp dT/dt-\lambda\Delta T=\Phi + \lambda_{sf} (T_{fluid}-T_{solid})
+		        Heat capacity cp, density \rho, and conductivity \lambda of the solid MUST be defined
+		        The solid may be refrigerated by a fluid with temperature T_{solid} transfer coefficient \lambda_{sf} using functions setFluidTemperature and setHeatTransfertCoeff
 		        The solid may receive some extra heat power due to nuclear fissions using function setHeatSource
 	"""
 	#Space dimension of the problem
@@ -36,8 +40,8 @@ def DiffusionEquation_2DSpherical(FECalculation, fileName):
 		supportOfField=solverlab.CELLS	
 	
     # Set the mesh and initial data
-	initial_data_inputfile="../resources/BoxWithMeshWithTriangularCells";
-	initial_data_fieldName="Temperature";
+	initial_data_inputfile="../resources/meshSquare";
+	initial_data_fieldName="Solid temperature";
 	print("Loading unstructured mesh and initial data", " in file ", initial_data_inputfile )
 	initial_data_time_iteration=0# default value is 0
 	initial_data_time_sub_iteration=0# default value is 0
@@ -46,8 +50,8 @@ def DiffusionEquation_2DSpherical(FECalculation, fileName):
 
     #### Optional physical values (default value is zero) : fluid temperature field, heat transfert coefficient, heat power field 
 	# Loading and setting fluid temperature field
-	fluid_temperature_inputfile="../resources/BoxWithMeshWithTriangularCells";
-	fluid_temperature_fieldName="Fluid temperature field";
+	fluid_temperature_inputfile="../resources/meshSquare";
+	fluid_temperature_fieldName="Fluid temperature";
 	fluid_temperature_time_iteration=0# default value is 0
 	fluid_temperature_time_sub_iteration=0# default value is 0
 	fluid_temperature_meshLevel=0# default value is 0
@@ -58,8 +62,8 @@ def DiffusionEquation_2DSpherical(FECalculation, fileName):
 	heatTransfertCoeff=1000.;#fluid/solid exchange coefficient, default value is 0
 	myProblem.setHeatTransfertCoeff(heatTransfertCoeff);
 	# Loading heat power field
-	heat_power_inputfile="../resources/BoxWithMeshWithTriangularCells";
-	heat_power_fieldName="Heat power field";
+	heat_power_inputfile="../resources/meshSquare";
+	heat_power_fieldName="Heat power";
 	heat_power_time_iteration=0# default value is 0
 	heat_power_time_sub_iteration=0# default value is 0
 	heat_power_meshLevel=0# default value is 0
@@ -69,19 +73,66 @@ def DiffusionEquation_2DSpherical(FECalculation, fileName):
 
     # the boundary conditions :
 	if( FECalculation):
-		boundaryNodeGroupNames=myProblem.getMesh().getNameOfNodeGroups()
-		print(len(boundaryNodeGroupNames), " Boundary Node Group detected : ", boundaryNodeGroupNames)
+		boundaryGroupNames=myProblem.getMesh().getNameOfNodeGroups()
+		print(len(boundaryGroupNames), " Boundary Node Group detected : ", boundaryGroupNames)
 	else:
-		boundaryFaceGroupNames=myProblem.getMesh().getNameOfFaceGroups()
-		print(len(boundaryFaceGroupNames), " Boundary Face Group detected : ", boundaryFaceGroupNames)
-
-	myProblem.setNeumannBoundaryCondition("GAUCHE");
-	myProblem.setNeumannBoundaryCondition("DROITE");
-	myProblem.setNeumannBoundaryCondition("HAUT");
-	myProblem.setNeumannBoundaryCondition("BAS");
+		boundaryGroupNames=myProblem.getMesh().getNameOfFaceGroups()
+		print(len(boundaryGroupNames), " Boundary Face Group detected : ", boundaryGroupNames)
+
+	# for each boundary we load the boundary field (replace by a loop over the boundaries)
+	boundary1_type=solverlab.NeumannDiffusion
+	boundary1_inputfile="../resources/meshSquare";
+	boundary1_fieldName="Left temperature";
+	boundary1_time_iteration=0# default value is 0
+	boundary1_time_sub_iteration=0# default value is 0
+	boundary1_meshLevel=0# default value is 0
+	print("Boundary ", boundaryGroupNames[3], ", loading field :", boundary1_fieldName, " in file ", boundary1_inputfile)
+	boundary1Field=solverlab.Field(boundary1_inputfile, supportOfField, boundary1_fieldName, boundary1_time_iteration, boundary1_time_sub_iteration, boundary1_meshLevel)
+	boundary2_type=solverlab.DirichletDiffusion
+	boundary2_inputfile="../resources/meshSquare";
+	boundary2_fieldName="Right temperature";
+	boundary2_time_iteration=0# default value is 0
+	boundary2_time_sub_iteration=0# default value is 0
+	boundary2_meshLevel=0# default value is 0
+	print("Boundary ", boundaryGroupNames[2], ", loading field :", boundary2_fieldName, " in file ", boundary2_inputfile)
+	boundary2Field=solverlab.Field(boundary2_inputfile, supportOfField, boundary2_fieldName, boundary2_time_iteration, boundary2_time_sub_iteration, boundary2_meshLevel)
+	boundary3_type=solverlab.NeumannDiffusion
+	boundary3_inputfile="../resources/meshSquare";
+	boundary3_fieldName="Top temperature";
+	boundary3_time_iteration=0# default value is 0
+	boundary3_time_sub_iteration=0# default value is 0
+	boundary3_meshLevel=0# default value is 0
+	print("Boundary ", boundaryGroupNames[4], ", loading field :", boundary3_fieldName, " in file ", boundary3_inputfile)
+	boundary3Field=solverlab.Field(boundary3_inputfile, supportOfField, boundary3_fieldName, boundary3_time_iteration, boundary3_time_sub_iteration, boundary3_meshLevel)
+	boundary4_type=solverlab.DirichletDiffusion
+	boundary4_inputfile="../resources/meshSquare";
+	boundary4_fieldName="Bottom temperature";
+	boundary4_time_iteration=0# default value is 0
+	boundary4_time_sub_iteration=0# default value is 0
+	boundary4_meshLevel=0# default value is 0
+	print("Boundary ", boundaryGroupNames[1], ", loading field :", boundary4_fieldName, " in file ", boundary4_inputfile)
+	boundary4Field=solverlab.Field(boundary4_inputfile, supportOfField, boundary4_fieldName, boundary4_time_iteration, boundary4_time_sub_iteration, boundary4_meshLevel)
+
+	# for each boundary we need to know if we want a Neumann or a Dirichlet boundary condition
+	if boundary1_type==solverlab.NeumannDiffusion :
+		myProblem.setNeumannBoundaryCondition("Left", boundary1Field)
+	elif boundary1_type==solverlab.DirichletDiffusion :
+		myProblem.setDirichletBoundaryCondition("Left", boundary1Field)
+	if boundary2_type==solverlab.NeumannDiffusion :
+		myProblem.setNeumannBoundaryCondition("Right", boundary2Field)
+	elif boundary2_type==solverlab.DirichletDiffusion :
+		myProblem.setDirichletBoundaryCondition("Right", boundary2Field)
+	if boundary3_type==solverlab.NeumannDiffusion :
+		myProblem.setNeumannBoundaryCondition("Top", boundary3Field)
+	elif boundary3_type==solverlab.DirichletDiffusion :
+		myProblem.setDirichletBoundaryCondition("Top", boundary3Field);
+	if boundary4_type==solverlab.NeumannDiffusion :
+		myProblem.setNeumannBoundaryCondition("Bottom", boundary4Field)
+	elif boundary4_type==solverlab.DirichletDiffusion :
+		myProblem.setDirichletBoundaryCondition("Bottom", boundary4Field);
 
     # set the numerical method
-	myProblem.setTimeScheme( solverlab.Explicit);
+	myProblem.setTimeScheme( solverlab.Explicit)# Otherwise solverlab.Implicit
 	max_nb_its_lin_solver = 50
 	myProblem.setLinearSolver(solverlab.GMRES, solverlab.ILU, max_nb_its_lin_solver );
 
diff --git a/CoreFlows/examples/Python/TransportEquation/TransportEquation_1DHeatedChannel.py b/CoreFlows/examples/Python/TransportEquation/TransportEquation_1DHeatedChannel.py
index 4d6cabc..7711025 100755
--- a/CoreFlows/examples/Python/TransportEquation/TransportEquation_1DHeatedChannel.py
+++ b/CoreFlows/examples/Python/TransportEquation/TransportEquation_1DHeatedChannel.py
@@ -17,7 +17,7 @@ def TransportEquation_1DHeatedChannel():
     # Set the transport velocity
 	transportVelocity=[5];
 
-	myProblem = cf.TransportEquation(cf.LiquidPhase,cf.around155bars600KTransport,transportVelocity);
+	myProblem = cf.TransportEquation(cf.Water,cf.around155bars600K,transportVelocity);
 	nVar = myProblem.getNumberOfVariables();
 
     # Prepare for the initial condition