KratosMultiphysics
KRATOS Multiphysics (Kratos) is a framework for building parallel, multi-disciplinary simulation software, aiming at modularity, extensibility, and high performance. Kratos is written in C++, and counts with an extensive Python interface.
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Kratos::BaseShellElement< TCoordinateTransformation > Class Template Reference

#include <base_shell_element.h>

Inheritance diagram for Kratos::BaseShellElement< TCoordinateTransformation >:
Collaboration diagram for Kratos::BaseShellElement< TCoordinateTransformation >:

Public Types

Type Definitions
typedef Element BaseType
 
- Public Types inherited from Kratos::Element
typedef Element ElementType
 definition of element type More...
 
typedef GeometricalObject BaseType
 base type: an GeometricalObject that automatically has a unique number More...
 
typedef Node NodeType
 definition of node type (default is: Node) More...
 
typedef Properties PropertiesType
 
typedef Geometry< NodeTypeGeometryType
 definition of the geometry type with given NodeType More...
 
typedef Geometry< NodeType >::PointsArrayType NodesArrayType
 definition of nodes container type, redefined from GeometryType More...
 
typedef Vector VectorType
 
typedef Matrix MatrixType
 
typedef std::size_t IndexType
 
typedef std::size_t SizeType
 
typedef Dof< doubleDofType
 
typedef std::vector< std::size_t > EquationIdVectorType
 
typedef std::vector< DofType::PointerDofsVectorType
 
typedef PointerVectorSet< DofTypeDofsArrayType
 
typedef GeometryData::IntegrationMethod IntegrationMethod
 Type definition for integration methods. More...
 
typedef GeometryData GeometryDataType
 
- Public Types inherited from Kratos::GeometricalObject
typedef Node NodeType
 Definition of the node type. More...
 
typedef Geometry< NodeTypeGeometryType
 The geometry type definition. More...
 
typedef std::size_t IndexType
 Defines the index type. More...
 
typedef std::size_t result_type
 Defines the result type. More...
 
- Public Types inherited from Kratos::IndexedObject
typedef std::size_t IndexType
 The definition of the index type. More...
 
typedef std::size_t result_type
 The definition of the result_type. More...
 
- Public Types inherited from Kratos::Flags
enum  FlagsList {
  Flag0 = BlockType(1) , Flag1 = BlockType(1) << 1 , Flag2 = BlockType(1) << 2 , Flag3 = BlockType(1) << 3 ,
  Flag4 = BlockType(1) << 4 , Flag5 = BlockType(1) << 5 , Flag6 = BlockType(1) << 6 , Flag7 = BlockType(1) << 7 ,
  Flag8 = BlockType(1) << 8 , Flag9 = BlockType(1) << 9 , Flag10 = BlockType(1) << 10 , Flag11 = BlockType(1) << 11 ,
  Flag12 = BlockType(1) << 12 , Flag13 = BlockType(1) << 13 , Flag14 = BlockType(1) << 14 , Flag15 = BlockType(1) << 15 ,
  Flag16 = BlockType(1) << 16 , Flag17 = BlockType(1) << 17 , Flag18 = BlockType(1) << 18 , Flag19 = BlockType(1) << 19 ,
  Flag20 = BlockType(1) << 20 , Flag21 = BlockType(1) << 21 , Flag22 = BlockType(1) << 22 , Flag23 = BlockType(1) << 23 ,
  Flag24 = BlockType(1) << 24 , Flag25 = BlockType(1) << 25 , Flag26 = BlockType(1) << 26 , Flag27 = BlockType(1) << 27 ,
  Flag28 = BlockType(1) << 28 , Flag29 = BlockType(1) << 29 , Flag30 = BlockType(1) << 30
}
 
typedef int64_t BlockType
 
typedef int64_t FlagType
 
typedef std::size_t IndexType
 

Public Member Functions

Life Cycle
 BaseShellElement (IndexType NewId, GeometryType::Pointer pGeometry)
 
 BaseShellElement (IndexType NewId, GeometryType::Pointer pGeometry, PropertiesType::Pointer pProperties)
 
 ~BaseShellElement () override=default
 
Operations
void EquationIdVector (EquationIdVectorType &rResult, const ProcessInfo &CurrentProcessInfo) const override
 
void GetDofList (DofsVectorType &rElementalDofList, const ProcessInfo &rCurrentProcessInfo) const override
 
void GetValuesVector (Vector &rValues, int Step=0) const override
 
void GetFirstDerivativesVector (Vector &rValues, int Step=0) const override
 
void GetSecondDerivativesVector (Vector &rValues, int Step=0) const override
 
void ResetConstitutiveLaw () override
 
void Initialize (const ProcessInfo &rCurrentProcessInfo) override
 
void InitializeNonLinearIteration (const ProcessInfo &rCurrentProcessInfo) override
 
void FinalizeNonLinearIteration (const ProcessInfo &rCurrentProcessInfo) override
 
void InitializeSolutionStep (const ProcessInfo &rCurrentProcessInfo) override
 
void FinalizeSolutionStep (const ProcessInfo &rCurrentProcessInfo) override
 
void CalculateMassMatrix (MatrixType &rMassMatrix, const ProcessInfo &rCurrentProcessInfo) override
 
void CalculateDampingMatrix (MatrixType &rDampingMatrix, const ProcessInfo &rCurrentProcessInfo) override
 
void CalculateLocalSystem (MatrixType &rLeftHandSideMatrix, VectorType &rRightHandSideVector, const ProcessInfo &rCurrentProcessInfo) override
 
void CalculateLeftHandSide (MatrixType &rLeftHandSideMatrix, const ProcessInfo &rCurrentProcessInfo) override
 
void CalculateRightHandSide (VectorType &rRightHandSideVector, const ProcessInfo &rCurrentProcessInfo) override
 
void CalculateOnIntegrationPoints (const Variable< array_1d< double, 3 > > &rVariable, std::vector< array_1d< double, 3 > > &rOutput, const ProcessInfo &rCurrentProcessInfo) override
 
void CalculateOnIntegrationPoints (const Variable< ConstitutiveLaw::Pointer > &rVariable, std::vector< ConstitutiveLaw::Pointer > &rValues, const ProcessInfo &rCurrentProcessInfo) override
 
void Calculate (const Variable< Matrix > &rVariable, Matrix &Output, const ProcessInfo &rCurrentProcessInfo) override
 
int Check (const ProcessInfo &rCurrentProcessInfo) const override
 
IntegrationMethod GetIntegrationMethod () const override
 
Access
void SetCrossSectionsOnIntegrationPoints (std::vector< ShellCrossSection::Pointer > &crossSections)
 
Input and output
const Parameters GetSpecifications () const override
 This method provides the specifications/requirements of the element. More...
 
virtual std::string Info () const override
 Turn back information as a string. More...
 
virtual void PrintInfo (std::ostream &rOStream) const override
 Print information about this object. More...
 
virtual void PrintData (std::ostream &rOStream) const override
 Print object's data. More...
 
- Public Member Functions inherited from Kratos::Element
 Element (IndexType NewId=0)
 
 Element (IndexType NewId, const NodesArrayType &ThisNodes)
 
 Element (IndexType NewId, GeometryType::Pointer pGeometry)
 
 Element (IndexType NewId, GeometryType::Pointer pGeometry, PropertiesType::Pointer pProperties)
 
 Element (Element const &rOther)
 Copy constructor. More...
 
 ~Element () override
 Destructor. More...
 
Elementoperator= (Element const &rOther)
 Assignment operator. More...
 
virtual Pointer Create (IndexType NewId, NodesArrayType const &ThisNodes, PropertiesType::Pointer pProperties) const
 It creates a new element pointer. More...
 
virtual Pointer Create (IndexType NewId, GeometryType::Pointer pGeom, PropertiesType::Pointer pProperties) const
 It creates a new element pointer. More...
 
virtual Pointer Clone (IndexType NewId, NodesArrayType const &ThisNodes) const
 It creates a new element pointer and clones the previous element data. More...
 
virtual void CalculateFirstDerivativesContributions (MatrixType &rLeftHandSideMatrix, VectorType &rRightHandSideVector, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateFirstDerivativesLHS (MatrixType &rLeftHandSideMatrix, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateFirstDerivativesRHS (VectorType &rRightHandSideVector, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateSecondDerivativesContributions (MatrixType &rLeftHandSideMatrix, VectorType &rRightHandSideVector, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateSecondDerivativesLHS (MatrixType &rLeftHandSideMatrix, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateSecondDerivativesRHS (VectorType &rRightHandSideVector, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateLumpedMassVector (VectorType &rLumpedMassVector, const ProcessInfo &rCurrentProcessInfo) const
 
virtual void AddExplicitContribution (const ProcessInfo &rCurrentProcessInfo)
 
virtual void AddExplicitContribution (const VectorType &rRHSVector, const Variable< VectorType > &rRHSVariable, const Variable< double > &rDestinationVariable, const ProcessInfo &rCurrentProcessInfo)
 This function is designed to make the element to assemble an rRHS vector identified by a variable rRHSVariable by assembling it to the nodes on the variable rDestinationVariable. (This is the double version) More...
 
virtual void AddExplicitContribution (const VectorType &rRHSVector, const Variable< VectorType > &rRHSVariable, const Variable< array_1d< double, 3 > > &rDestinationVariable, const ProcessInfo &rCurrentProcessInfo)
 This function is designed to make the element to assemble an rRHS vector identified by a variable rRHSVariable by assembling it to the nodes on the variable rDestinationVariable. (This is the vector version) More...
 
virtual void AddExplicitContribution (const MatrixType &rLHSMatrix, const Variable< MatrixType > &rLHSVariable, const Variable< Matrix > &rDestinationVariable, const ProcessInfo &rCurrentProcessInfo)
 This function is designed to make the element to assemble an rRHS vector identified by a variable rRHSVariable by assembling it to the nodes on the variable rDestinationVariable. (This is the matrix version) More...
 
virtual void Calculate (const Variable< double > &rVariable, double &Output, const ProcessInfo &rCurrentProcessInfo)
 
virtual void Calculate (const Variable< array_1d< double, 3 > > &rVariable, array_1d< double, 3 > &Output, const ProcessInfo &rCurrentProcessInfo)
 
virtual void Calculate (const Variable< Vector > &rVariable, Vector &Output, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< bool > &rVariable, std::vector< bool > &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< int > &rVariable, std::vector< int > &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< double > &rVariable, std::vector< double > &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< array_1d< double, 3 >> &rVariable, std::vector< array_1d< double, 3 >> &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< array_1d< double, 4 >> &rVariable, std::vector< array_1d< double, 4 >> &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< array_1d< double, 6 >> &rVariable, std::vector< array_1d< double, 6 >> &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< array_1d< double, 9 >> &rVariable, std::vector< array_1d< double, 9 >> &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< Vector > &rVariable, std::vector< Vector > &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateOnIntegrationPoints (const Variable< Matrix > &rVariable, std::vector< Matrix > &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< bool > &rVariable, const std::vector< bool > &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< int > &rVariable, const std::vector< int > &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< double > &rVariable, const std::vector< double > &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< array_1d< double, 3 >> &rVariable, const std::vector< array_1d< double, 3 >> &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< array_1d< double, 4 >> &rVariable, const std::vector< array_1d< double, 4 >> &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< array_1d< double, 6 >> &rVariable, const std::vector< array_1d< double, 6 >> &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< array_1d< double, 9 >> &rVariable, const std::vector< array_1d< double, 9 >> &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< Vector > &rVariable, const std::vector< Vector > &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< Matrix > &rVariable, const std::vector< Matrix > &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void SetValuesOnIntegrationPoints (const Variable< ConstitutiveLaw::Pointer > &rVariable, const std::vector< ConstitutiveLaw::Pointer > &rValues, const ProcessInfo &rCurrentProcessInfo)
 
virtual void MassMatrix (MatrixType &rMassMatrix, const ProcessInfo &rCurrentProcessInfo)
 
virtual void AddMassMatrix (MatrixType &rLeftHandSideMatrix, double coeff, const ProcessInfo &rCurrentProcessInfo)
 
virtual void DampMatrix (MatrixType &rDampMatrix, const ProcessInfo &rCurrentProcessInfo)
 
virtual void AddInertiaForces (VectorType &rRightHandSideVector, double coeff, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateLocalVelocityContribution (MatrixType &rDampingMatrix, VectorType &rRightHandSideVector, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateSensitivityMatrix (const Variable< double > &rDesignVariable, Matrix &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
virtual void CalculateSensitivityMatrix (const Variable< array_1d< double, 3 > > &rDesignVariable, Matrix &rOutput, const ProcessInfo &rCurrentProcessInfo)
 
PropertiesType::Pointer pGetProperties ()
 returns the pointer to the property of the element. Does not throw an error, to allow copying of elements which don't have any property assigned. More...
 
const PropertiesType::Pointer pGetProperties () const
 
PropertiesTypeGetProperties ()
 
PropertiesType const & GetProperties () const
 
void SetProperties (PropertiesType::Pointer pProperties)
 
bool HasProperties () const
 Check that the Element has a correctly initialized pointer to a Properties instance. More...
 
 KRATOS_CLASS_INTRUSIVE_POINTER_DEFINITION (Element)
 
- Public Member Functions inherited from Kratos::GeometricalObject
 GeometricalObject (IndexType NewId=0)
 Default constructor. More...
 
 GeometricalObject (IndexType NewId, GeometryType::Pointer pGeometry)
 Default constructor. More...
 
 ~GeometricalObject () override
 Destructor. More...
 
 GeometricalObject (GeometricalObject const &rOther)
 Copy constructor. More...
 
GeometricalObjectoperator= (GeometricalObject const &rOther)
 Assignment operator. More...
 
virtual void SetGeometry (GeometryType::Pointer pGeometry)
 Sets the pointer to the geometry. More...
 
GeometryType::Pointer pGetGeometry ()
 Returns the pointer to the geometry. More...
 
const GeometryType::Pointer pGetGeometry () const
 Returns the pointer to the geometry (const version) More...
 
GeometryTypeGetGeometry ()
 Returns the reference of the geometry. More...
 
GeometryType const & GetGeometry () const
 Returns the reference of the geometry (const version) More...
 
FlagsGetFlags ()
 Returns the flags of the object. More...
 
Flags const & GetFlags () const
 Returns the flags of the object (const version) More...
 
void SetFlags (Flags const &rThisFlags)
 Sets the flags of the object. More...
 
DataValueContainerData ()
 
DataValueContainerGetData ()
 
DataValueContainer const & GetData () const
 
void SetData (DataValueContainer const &rThisData)
 
template<class TDataType >
bool Has (const Variable< TDataType > &rThisVariable) const
 
template<class TVariableType >
void SetValue (const TVariableType &rThisVariable, typename TVariableType::Type const &rValue)
 
template<class TVariableType >
TVariableType::Type & GetValue (const TVariableType &rThisVariable)
 
template<class TVariableType >
TVariableType::Type const & GetValue (const TVariableType &rThisVariable) const
 
unsigned int use_count () const noexcept
 
 KRATOS_CLASS_INTRUSIVE_POINTER_DEFINITION (GeometricalObject)
 Pointer definition of GeometricalObject. More...
 
bool IsActive () const
 Checks if the GeometricalObject is active. More...
 
- Public Member Functions inherited from Kratos::IndexedObject
 IndexedObject (IndexType NewId=0)
 Default constructor. More...
 
virtual ~IndexedObject ()
 Destructor. More...
 
 IndexedObject (IndexedObject const &rOther)
 Copy constructor. More...
 
IndexedObjectoperator= (IndexedObject const &rOther)
 Assignment operator. More...
 
template<class TObjectType >
IndexType operator() (TObjectType const &rThisObject) const
 
IndexType Id () const
 
IndexType GetId () const
 
virtual void SetId (IndexType NewId)
 
IndexTypeDepricatedIdAccess ()
 TODO: remove this function when removing data_file_io object. More...
 
 KRATOS_CLASS_POINTER_DEFINITION (IndexedObject)
 Pointer definition of IndexedObject. More...
 
- Public Member Functions inherited from Kratos::Flags
Flagsoperator= (Flags const &rOther)
 Assignment operator. More...
 
 operator bool () const
 
Flags operator~ () const
 
bool operator! () const
 
void AssignFlags (Flags const &rOther)
 
void Set (const Flags ThisFlag)
 
void Set (const Flags ThisFlag, bool Value)
 
void Reset (const Flags ThisFlag)
 
void Flip (const Flags ThisFlag)
 
void SetPosition (IndexType Position, bool Value=true)
 
bool GetPosition (IndexType Position) const
 
void FlipPosition (IndexType Position)
 
void ClearPosition (IndexType Position)
 
void Clear ()
 
Flags AsFalse () const
 
bool Is (Flags const &rOther) const
 
bool IsDefined (Flags const &rOther) const
 
bool IsNot (Flags const &rOther) const
 
bool IsNotDefined (Flags const &rOther) const
 
 KRATOS_CLASS_POINTER_DEFINITION (Flags)
 Pointer definition of Flags. More...
 
const Flagsoperator|= (const Flags &Other)
 
const Flagsoperator&= (const Flags &Other)
 
 Flags ()
 Default constructor. More...
 
 Flags (Flags const &rOther)
 Copy constructor. More...
 
virtual ~Flags ()
 Destructor. More...
 

Protected Member Functions

Protected Operations
 BaseShellElement ()
 
SizeType GetNumberOfDofs () const
 
SizeType GetNumberOfGPs () const
 
virtual void CalculateAll (MatrixType &rLeftHandSideMatrix, VectorType &rRightHandSideVector, const ProcessInfo &rCurrentProcessInfo, const bool CalculateStiffnessMatrixFlag, const bool CalculateResidualVectorFlag)
 This functions calculates both the RHS and the LHS. More...
 
void SetupOrientationAngles ()
 
void CheckDofs () const
 
void CheckProperties (const ProcessInfo &rCurrentProcessInfo) const
 
void CheckSpecificProperties () const
 
void ComputeLocalAxis (const Variable< array_1d< double, 3 > > &rVariable, std::vector< array_1d< double, 3 > > &rOutput) const
 
void ComputeLocalMaterialAxis (const Variable< array_1d< double, 3 > > &rVariable, std::vector< array_1d< double, 3 > > &rOutput) const
 
void DecimalCorrection (Vector &a)
 
virtual ShellCrossSection::SectionBehaviorType GetSectionBehavior () const
 

Protected Attributes

Protected member Variables
IntegrationMethod mIntegrationMethod = GeometryData::IntegrationMethod::GI_GAUSS_2
 
CoordinateTransformationPointerType mpCoordinateTransformation = nullptr
 
CrossSectionContainerType mSections
 

Pointer Definitions

Pointer definition of BaseShellElement

typedef std::vector< ShellCrossSection::Pointer > CrossSectionContainerType
 
typedef Quaternion< doubleQuaternionType
 
using CoordinateTransformationPointerType = Kratos::unique_ptr< TCoordinateTransformation >
 
using SizeType = std::size_t
 
using Vector3Type = array_1d< double, 3 >
 
 KRATOS_CLASS_INTRUSIVE_POINTER_DEFINITION (BaseShellElement)
 

Serialization

class Serializer
 

Additional Inherited Members

- Static Public Member Functions inherited from Kratos::GeometricalObject
static bool HasSameType (const GeometricalObject &rLHS, const GeometricalObject &rRHS)
 Checks if two GeometricalObject have the same type. More...
 
static bool HasSameType (const GeometricalObject *rLHS, const GeometricalObject *rRHS)
 Checks if two GeometricalObject have the same type (pointer version) More...
 
static bool HasSameGeometryType (const GeometricalObject &rLHS, const GeometricalObject &rRHS)
 Checks if two GeometricalObject have the same geometry type. More...
 
static bool HasSameGeometryType (const GeometricalObject *rLHS, const GeometricalObject *rRHS)
 Checks if two GeometricalObject have the same geometry type (pointer version) More...
 
static bool IsSame (const GeometricalObject &rLHS, const GeometricalObject &rRHS)
 Checks if two GeometricalObject are the same. More...
 
static bool IsSame (const GeometricalObject *rLHS, const GeometricalObject *rRHS)
 Checks if two GeometricalObject are the same (pointer version) More...
 
- Static Public Member Functions inherited from Kratos::Flags
static const Flags AllDefined ()
 
static const Flags AllTrue ()
 
static Flags Create (IndexType ThisPosition, bool Value=true)
 

Member Typedef Documentation

◆ BaseType

template<class TCoordinateTransformation >
typedef Element Kratos::BaseShellElement< TCoordinateTransformation >::BaseType

◆ CoordinateTransformationPointerType

template<class TCoordinateTransformation >
using Kratos::BaseShellElement< TCoordinateTransformation >::CoordinateTransformationPointerType = Kratos::unique_ptr<TCoordinateTransformation>

◆ CrossSectionContainerType

template<class TCoordinateTransformation >
typedef std::vector< ShellCrossSection::Pointer > Kratos::BaseShellElement< TCoordinateTransformation >::CrossSectionContainerType

◆ QuaternionType

template<class TCoordinateTransformation >
typedef Quaternion<double> Kratos::BaseShellElement< TCoordinateTransformation >::QuaternionType

◆ SizeType

template<class TCoordinateTransformation >
using Kratos::BaseShellElement< TCoordinateTransformation >::SizeType = std::size_t

◆ Vector3Type

template<class TCoordinateTransformation >
using Kratos::BaseShellElement< TCoordinateTransformation >::Vector3Type = array_1d<double, 3>

Constructor & Destructor Documentation

◆ BaseShellElement() [1/3]

template<class TCoordinateTransformation >
Kratos::BaseShellElement< TCoordinateTransformation >::BaseShellElement ( IndexType  NewId,
GeometryType::Pointer  pGeometry 
)

Constructor using Geometry

◆ BaseShellElement() [2/3]

template<class TCoordinateTransformation >
Kratos::BaseShellElement< TCoordinateTransformation >::BaseShellElement ( IndexType  NewId,
GeometryType::Pointer  pGeometry,
PropertiesType::Pointer  pProperties 
)

Constructor using Properties

◆ ~BaseShellElement()

template<class TCoordinateTransformation >
Kratos::BaseShellElement< TCoordinateTransformation >::~BaseShellElement ( )
overridedefault

Destructor

◆ BaseShellElement() [3/3]

template<class TCoordinateTransformation >
Kratos::BaseShellElement< TCoordinateTransformation >::BaseShellElement ( )
inlineprotected

Protected empty constructor

Member Function Documentation

◆ Calculate()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::Calculate ( const Variable< Matrix > &  rVariable,
Matrix Output,
const ProcessInfo rCurrentProcessInfo 
)
overridevirtual

Reimplemented from Kratos::Element.

◆ CalculateAll()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CalculateAll ( MatrixType rLeftHandSideMatrix,
VectorType rRightHandSideVector,
const ProcessInfo rCurrentProcessInfo,
const bool  CalculateStiffnessMatrixFlag,
const bool  CalculateResidualVectorFlag 
)
protectedvirtual

This functions calculates both the RHS and the LHS.

Parameters
rLeftHandSideMatrixThe LHS
rRightHandSideVectorThe RHS
rCurrentProcessInfoThe current process info instance
CalculateStiffnessMatrixFlagThe flag to set if compute the LHS
CalculateResidualVectorFlagThe flag to set if compute the RHS

◆ CalculateDampingMatrix()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CalculateDampingMatrix ( MatrixType rDampingMatrix,
const ProcessInfo rCurrentProcessInfo 
)
overridevirtual

this is called during the assembling process in order to calculate the elemental damping matrix

Parameters
rDampingMatrixthe elemental damping matrix
rCurrentProcessInfothe current process info instance

Reimplemented from Kratos::Element.

◆ CalculateLeftHandSide()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CalculateLeftHandSide ( MatrixType rLeftHandSideMatrix,
const ProcessInfo rCurrentProcessInfo 
)
overridevirtual

this is called during the assembling process in order to calculate the elemental left hand side matrix only

Parameters
rLeftHandSideMatrixthe elemental left hand side matrix
rCurrentProcessInfothe current process info instance

Reimplemented from Kratos::Element.

◆ CalculateLocalSystem()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CalculateLocalSystem ( MatrixType rLeftHandSideMatrix,
VectorType rRightHandSideVector,
const ProcessInfo rCurrentProcessInfo 
)
overridevirtual

ELEMENTS inherited from this class have to implement next CalculateLocalSystem, CalculateLeftHandSide and CalculateRightHandSide methods they can be managed internally with a private method to do the same calculations only once: MANDATORY this is called during the assembling process in order to calculate all elemental contributions to the global system matrix and the right hand side

Parameters
rLeftHandSideMatrixthe elemental left hand side matrix
rRightHandSideVectorthe elemental right hand side
rCurrentProcessInfothe current process info instance

Reimplemented from Kratos::Element.

◆ CalculateMassMatrix()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CalculateMassMatrix ( MatrixType rMassMatrix,
const ProcessInfo rCurrentProcessInfo 
)
overridevirtual

ELEMENTS inherited from this class must implement this methods if they need to add dynamic element contributions CalculateMassMatrix, CalculateDampingMatrix and CalculateLumpedMassVector methods are: OPTIONAL this is called during the assembling process in order to calculate the elemental mass matrix

Parameters
rMassMatrixthe elemental mass matrix
rCurrentProcessInfothe current process info instance

Reimplemented from Kratos::Element.

◆ CalculateOnIntegrationPoints() [1/2]

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CalculateOnIntegrationPoints ( const Variable< array_1d< double, 3 > > &  rVariable,
std::vector< array_1d< double, 3 > > &  rOutput,
const ProcessInfo rCurrentProcessInfo 
)
override

◆ CalculateOnIntegrationPoints() [2/2]

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CalculateOnIntegrationPoints ( const Variable< ConstitutiveLaw::Pointer > &  rVariable,
std::vector< ConstitutiveLaw::Pointer > &  rValues,
const ProcessInfo rCurrentProcessInfo 
)
overridevirtual

Reimplemented from Kratos::Element.

◆ CalculateRightHandSide()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CalculateRightHandSide ( VectorType rRightHandSideVector,
const ProcessInfo rCurrentProcessInfo 
)
overridevirtual

this is called during the assembling process in order to calculate the elemental right hand side vector only

Parameters
rRightHandSideVectorthe elemental right hand side vector
rCurrentProcessInfothe current process info instance

Reimplemented from Kratos::Element.

◆ Check()

template<class TCoordinateTransformation >
int Kratos::BaseShellElement< TCoordinateTransformation >::Check ( const ProcessInfo rCurrentProcessInfo) const
overridevirtual

This method provides the place to perform checks on the completeness of the input and the compatibility with the problem options as well as the contitutive laws selected It is designed to be called only once (or anyway, not often) typically at the beginning of the calculations, so to verify that nothing is missing from the input or that no common error is found.

Parameters
rCurrentProcessInfothis method is: MANDATORY

Reimplemented from Kratos::Element.

Reimplemented in Kratos::ShellThinElement3D4N< ShellKinematics::NONLINEAR_COROTATIONAL >, and Kratos::ShellThickElement3D3N< ShellKinematics::NONLINEAR_COROTATIONAL >.

◆ CheckDofs()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CheckDofs
protected

◆ CheckProperties()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CheckProperties ( const ProcessInfo rCurrentProcessInfo) const
protected

◆ CheckSpecificProperties()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::CheckSpecificProperties
protected

◆ ComputeLocalAxis()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::ComputeLocalAxis ( const Variable< array_1d< double, 3 > > &  rVariable,
std::vector< array_1d< double, 3 > > &  rOutput 
) const
protected

computes the local axis of the element (for visualization)

Parameters
rVariablethe variable to select the output
rOutputthe computed local axis
rpCoordinateTransformationthe coordinate-transformation to be used for computing the local axis

◆ ComputeLocalMaterialAxis()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::ComputeLocalMaterialAxis ( const Variable< array_1d< double, 3 > > &  rVariable,
std::vector< array_1d< double, 3 > > &  rOutput 
) const
protected

computes the local material axis of the element (for visualization)

Parameters
rVariablethe variable to select the output
rOutputthe computed local material axis
rpCoordinateTransformationthe coordinate-transformation to be used for computing the local material axis

◆ DecimalCorrection()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::DecimalCorrection ( Vector a)
protected

◆ EquationIdVector()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::EquationIdVector ( EquationIdVectorType rResult,
const ProcessInfo CurrentProcessInfo 
) const
overridevirtual

this determines the elemental equation ID vector for all elemental DOFs

Parameters
rResultthe elemental equation ID vector
rCurrentProcessInfothe current process info instance

Reimplemented from Kratos::Element.

◆ FinalizeNonLinearIteration()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::FinalizeNonLinearIteration ( const ProcessInfo rCurrentProcessInfo)
overridevirtual

this is called for non-linear analysis at the end of the iteration process

Reimplemented from Kratos::Element.

◆ FinalizeSolutionStep()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::FinalizeSolutionStep ( const ProcessInfo rCurrentProcessInfo)
overridevirtual

this is called at the end of each solution step

Reimplemented from Kratos::Element.

◆ GetDofList()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::GetDofList ( DofsVectorType rElementalDofList,
const ProcessInfo rCurrentProcessInfo 
) const
overridevirtual

determines the elemental list of DOFs

Parameters
ElementalDofListthe list of DOFs
rCurrentProcessInfothe current process info instance

Reimplemented from Kratos::Element.

◆ GetFirstDerivativesVector()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::GetFirstDerivativesVector ( Vector values,
int  Step = 0 
) const
overridevirtual

Getting method to obtain the time derivative of variable which defines the degrees of freedom

Reimplemented from Kratos::Element.

◆ GetIntegrationMethod()

template<class TCoordinateTransformation >
IntegrationMethod Kratos::BaseShellElement< TCoordinateTransformation >::GetIntegrationMethod ( ) const
inlineoverridevirtual

returns the used integration method. In the general case this is the default integration method of the used geometry. I an other integration method is used the method has to be overwritten within the element

Returns
default integration method of the used Geometry

Reimplemented from Kratos::Element.

◆ GetNumberOfDofs()

template<class TCoordinateTransformation >
SizeType Kratos::BaseShellElement< TCoordinateTransformation >::GetNumberOfDofs
protected

◆ GetNumberOfGPs()

template<class TCoordinateTransformation >
SizeType Kratos::BaseShellElement< TCoordinateTransformation >::GetNumberOfGPs
protected

◆ GetSecondDerivativesVector()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::GetSecondDerivativesVector ( Vector values,
int  Step = 0 
) const
overridevirtual

Getting method to obtain the second time derivative of variable which defines the degrees of freedom

Reimplemented from Kratos::Element.

◆ GetSectionBehavior()

template<class TCoordinateTransformation >
ShellCrossSection::SectionBehaviorType Kratos::BaseShellElement< TCoordinateTransformation >::GetSectionBehavior
protectedvirtual

Returns the behavior of this shell (thin/thick)

Returns
the shell behavior

◆ GetSpecifications()

template<class TCoordinateTransformation >
const Parameters Kratos::BaseShellElement< TCoordinateTransformation >::GetSpecifications
overridevirtual

This method provides the specifications/requirements of the element.

This can be used to enhance solvers and analysis. The following is an example: { "time_integration" : [], // NOTE: Options are static, implicit, explicit "framework" : "eulerian", // NOTE: Options are eulerian, lagrangian, ALE "symmetric_lhs" : true, // NOTE: Options are true/false "positive_definite_lhs" : false, // NOTE: Options are true/false "output" : { // NOTE: Values compatible as output "gauss_point" : ["INTEGRATION_WEIGTH"], "nodal_historical" : ["DISPLACEMENT"], "nodal_non_historical" : [], "entity" : [] }, "required_variables" : ["DISPLACEMENT"], // NOTE: Fill with the required variables "required_dofs" : ["DISPLACEMENT_X", "DISPLACEMENT_Y"], // NOTE: Fill with the required dofs "flags_used" : ["BOUNDARY", "ACTIVE"], // NOTE: Fill with the flags used "compatible_geometries" : ["Triangle2D3"], // NOTE: Compatible geometries. Options are "Point2D", "Point3D", "Sphere3D1", "Line2D2", "Line2D3", "Line3D2", "Line3D3", "Triangle2D3", "Triangle2D6", "Triangle3D3", "Triangle3D6", "Quadrilateral2D4", "Quadrilateral2D8", "Quadrilateral2D9", "Quadrilateral3D4", "Quadrilateral3D8", "Quadrilateral3D9", "Tetrahedra3D4" , "Tetrahedra3D10" , "Prism3D6" , "Prism3D15" , "Hexahedra3D8" , "Hexahedra3D20" , "Hexahedra3D27" "element_integrates_in_time" : true, // NOTE: Options are true/false "compatible_constitutive_laws": { "type" : ["PlaneStress","PlaneStrain"], // NOTE: List of CL compatible types. Options are "PlaneStress", "PlaneStrain", "3D" "dimension" : ["2D", "2D"], // NOTE: List of dimensions. Options are "2D", "3D", "2DAxysimm" "strain_size" : [3,3] // NOTE: List of strain sizes }, "documentation" : "This is an element" // NOTE: The documentation of the entity }

Returns
specifications The required specifications/requirements

Reimplemented from Kratos::Element.

◆ GetValuesVector()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::GetValuesVector ( Vector values,
int  Step = 0 
) const
overridevirtual

ELEMENTS inherited from this class must implement this methods if they need the values of the time derivatives of any of the dof set by the element. If the derivatives do not exist can set to zero these methods are: MANDATORY ( when compatibility with dynamics is required ) Getting method to obtain the variable which defines the degrees of freedom

Reimplemented from Kratos::Element.

◆ Info()

template<class TCoordinateTransformation >
std::string Kratos::BaseShellElement< TCoordinateTransformation >::Info
overridevirtual

Turn back information as a string.

Reimplemented from Kratos::Element.

◆ Initialize()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::Initialize ( const ProcessInfo rCurrentProcessInfo)
overridevirtual

ELEMENTS inherited from this class must implement next methods Initialize, ResetConstitutiveLaw if the element needs to perform any operation before any calculation is done reset material and constitutive parameters or clean memory deleting obsolete variables these methods are: OPTIONAL is called to initialize the element if the element needs to perform any operation before any calculation is done the elemental variables will be initialized and set using this method

Reimplemented from Kratos::Element.

◆ InitializeNonLinearIteration()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::InitializeNonLinearIteration ( const ProcessInfo rCurrentProcessInfo)
overridevirtual

this is called for non-linear analysis at the beginning of the iteration process

Reimplemented from Kratos::Element.

◆ InitializeSolutionStep()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::InitializeSolutionStep ( const ProcessInfo rCurrentProcessInfo)
overridevirtual

ELEMENTS inherited from this class must implement next methods InitializeSolutionStep, FinalizeSolutionStep, InitializeNonLinearIteration, FinalizeNonLinearIteration if the element needs to perform any operation before and after the solution step if the element needs to perform any operation before and after the solution iteration these methods are: OPTIONAL this is called in the beginning of each solution step

Reimplemented from Kratos::Element.

◆ KRATOS_CLASS_INTRUSIVE_POINTER_DEFINITION()

template<class TCoordinateTransformation >
Kratos::BaseShellElement< TCoordinateTransformation >::KRATOS_CLASS_INTRUSIVE_POINTER_DEFINITION ( BaseShellElement< TCoordinateTransformation >  )

◆ PrintData()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::PrintData ( std::ostream &  rOStream) const
overridevirtual

Print object's data.

Reimplemented from Kratos::Element.

◆ PrintInfo()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::PrintInfo ( std::ostream &  rOStream) const
overridevirtual

Print information about this object.

Reimplemented from Kratos::Element.

◆ ResetConstitutiveLaw()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::ResetConstitutiveLaw
overridevirtual

is called to reset the constitutive law parameters and the material properties the elemental variables will be changed and reset using this method

Reimplemented from Kratos::Element.

◆ SetCrossSectionsOnIntegrationPoints()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::SetCrossSectionsOnIntegrationPoints ( std::vector< ShellCrossSection::Pointer > &  crossSections)

◆ SetupOrientationAngles()

template<class TCoordinateTransformation >
void Kratos::BaseShellElement< TCoordinateTransformation >::SetupOrientationAngles
protected

Friends And Related Function Documentation

◆ Serializer

template<class TCoordinateTransformation >
friend class Serializer
friend

Member Data Documentation

◆ mIntegrationMethod

template<class TCoordinateTransformation >
IntegrationMethod Kratos::BaseShellElement< TCoordinateTransformation >::mIntegrationMethod = GeometryData::IntegrationMethod::GI_GAUSS_2
protected

◆ mpCoordinateTransformation

template<class TCoordinateTransformation >
CoordinateTransformationPointerType Kratos::BaseShellElement< TCoordinateTransformation >::mpCoordinateTransformation = nullptr
protected

◆ mSections

template<class TCoordinateTransformation >
CrossSectionContainerType Kratos::BaseShellElement< TCoordinateTransformation >::mSections
protected

Container for cross section associated to each integration point


The documentation for this class was generated from the following files: