void setDirichletBoundaryCondition(string groupName,double Temperature){
_limitField[groupName]=LimitFieldStationaryDiffusion(DirichletStationaryDiffusion,Temperature,-1);
};
+ /** \fn setDirichletBoundaryCondition
+ * \brief adds a new boundary condition of type Dirichlet
+ * \details Reads the boundary field in a med file
+ * \param [in] string : the name of the boundary
+ * \param [in] string : the file name
+ * \param [in] string : the field name
+ * \param [in] int : the time step number
+ * \param [in] int : int corresponding to the enum CELLS or NODES
+ * \param [out] void
+ * */
+ void setDirichletBoundaryCondition(string groupName, string fileName, string fieldName, int timeStepNumber, int order, int meshLevel, int field_support_type);
+ void setDirichletBoundaryCondition(string groupName, Field bc_field){
+ _limitField[groupName]=LimitFieldStationaryDiffusion(DirichletStationaryDiffusion, 0, -1);
+ };
/** \fn setNeumannBoundaryCondition
* \brief adds a new boundary condition of type Neumann
void setNeumannBoundaryCondition(string groupName, double normalFlux=0){
_limitField[groupName]=LimitFieldStationaryDiffusion(NeumannStationaryDiffusion,-1, normalFlux);
};
+ /** \fn setNeumannBoundaryCondition
+ * \brief adds a new boundary condition of type Neumann
+ * \details Reads the boundary field in a med file
+ * \param [in] string : the name of the boundary
+ * \param [in] string : the file name
+ * \param [in] string : the field name
+ * \param [in] int : the time step number
+ * \param [in] int : int corresponding to the enum CELLS or NODES
+ * \param [out] void
+ * */
+ void setNeumannBoundaryCondition(string groupName, string fileName, string fieldName, int timeStepNumber, int order, int meshLevel, int field_support_type);
+ void setNeumannBoundaryCondition(string groupName, Field bc_field){
+ _limitField[groupName]=LimitFieldStationaryDiffusion(NeumannStationaryDiffusion,-1, 0);
+ };
void setDirichletValues(map< int, double> dirichletBoundaryValues);
void setNeumannValues (map< int, double> neumannBoundaryValues);
vector<string> getInputFieldsNames();
void setInputField(const string& nameField, Field& inputField );//supply of a required input field
- void setFluidTemperatureField(Field coupledTemperatureField){
- _fluidTemperatureField=coupledTemperatureField;
- _fluidTemperatureFieldSet=true;
- };
- void setFluidTemperature(double fluidTemperature){
- _fluidTemperature=fluidTemperature;
- }
- Field& getFluidTemperatureField(){
- return _fluidTemperatureField;
- }
+ void setFluidTemperatureField(Field coupledTemperatureField);
+ void setFluidTemperature(double fluidTemperature){ _fluidTemperature=fluidTemperature; }
+ Field& getFluidTemperatureField(){ return _fluidTemperatureField; }
+
/** \fn setHeatPowerField
* \brief set the heat power field (variable in space)
* \details
* \param [in] Field
* \param [out] void
* */
- void setHeatPowerField(Field heatPower){
- heatPower.getMesh().checkFastEquivalWith(_mesh);
- _heatPowerField=heatPower;
- _heatPowerFieldSet=true;
- }
+ void setHeatPowerField(Field heatPower);
/** \fn setHeatPowerField
* \brief set the heat power field (variable in space)
* \param [in] string fieldName
* \param [out] void
* */
- void setHeatPowerField(string fileName, string fieldName, int iteration = 0, int order = 0, int meshLevel=0){
- _heatPowerField=Field(fileName, CELLS,fieldName, iteration, order, meshLevel);
- _heatPowerField.getMesh().checkFastEquivalWith(_mesh);
- _heatPowerFieldSet=true;
- }
+ void setHeatPowerField(string fileName, string fieldName, int iteration = 0, int order = 0, int meshLevel=0);
/** \fn getHeatPowerField
* \brief returns the heat power field