itk::fem::Element1DStress< TBaseClass > Class Template Reference

Class that is used to define linear elasticity problem in 1D space. More...

#include <itkFEMElement1DStress.h>

List of all members.

[NOHEADER]
virtual Material::ConstPointer	GetMaterial (void) const
virtual void	SetMaterial (Material::ConstPointer mat_)
MaterialLinearElasticity::ConstPointer	m_mat
Public Types
typedef Element1DStress	Self
typedef TBaseClass	Superclass
typedef Self *	Pointer
typedef const Self *	ConstPointer
typedef Superclass::Float	Float
typedef Superclass::MatrixType	MatrixType
typedef Superclass::VectorType	VectorType
Public Member Functions
virtual void	Read (std::istream &, void *info)
virtual void	Write (std::ostream &f) const
	Element1DStress ()
virtual void	GetStrainDisplacementMatrix (MatrixType &B, const MatrixType &shapeDgl) const
virtual void	GetMaterialMatrix (MatrixType &D) const
virtual void	GetStiffnessMatrix (MatrixType &Ke) const
virtual unsigned int	GetNumberOfDegreesOfFreedomPerNode (void) const

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Detailed Description

template<class TBaseClass = Element>
class itk::fem::Element1DStress< TBaseClass >

Class that is used to define linear elasticity problem in 1D space.

This class only defines the physics of the problem. Use his class together with element classes that specify the geometry to fully define the element.

You can specify one template parameter:

TBaseClass - Class from which Element1DStress is derived. TBaseClass must be derived from the Element base class. This enables you to use this class at any level of element definition. If not specified, it defaults to the Element base class.

Definition at line 45 of file itkFEMElement1DStress.h.

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Member Typedef Documentation

template<class TBaseClass = Element> typedef const Self* itk::fem::Element1DStress< TBaseClass >::ConstPointer

Const pointer or SmartPointer to an object. Reimplemented in itk::fem::Element2DC0LinearLineStress. Definition at line 47 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> typedef Superclass::Float itk::fem::Element1DStress< TBaseClass >::Float

Definition at line 51 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> typedef Superclass::MatrixType itk::fem::Element1DStress< TBaseClass >::MatrixType

Definition at line 52 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> typedef Self* itk::fem::Element1DStress< TBaseClass >::Pointer

Pointer or SmartPointer to an object. Reimplemented in itk::fem::Element2DC0LinearLineStress. Definition at line 47 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> typedef Element1DStress itk::fem::Element1DStress< TBaseClass >::Self

Standard Self typedef. Reimplemented in itk::fem::Element2DC0LinearLineStress. Definition at line 47 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> typedef TBaseClass itk::fem::Element1DStress< TBaseClass >::Superclass

Standard Superclass typedef. Reimplemented in itk::fem::Element2DC0LinearLineStress. Definition at line 47 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> typedef Superclass::VectorType itk::fem::Element1DStress< TBaseClass >::VectorType

Definition at line 53 of file itkFEMElement1DStress.h.

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Constructor & Destructor Documentation

template<class TBaseClass = Element> itk::fem::Element1DStress< TBaseClass >::Element1DStress (   )

Default constructor only clears the internal storage

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Member Function Documentation

template<class TBaseClass = Element> virtual Material::ConstPointer itk::fem::Element1DStress< TBaseClass >::GetMaterial (  void   )  const [inline, virtual]

Definition at line 113 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> virtual void itk::fem::Element1DStress< TBaseClass >::GetMaterialMatrix (  MatrixType &  D  )  const [virtual]

Compute the D matrix.

template<class TBaseClass = Element> virtual unsigned int itk::fem::Element1DStress< TBaseClass >::GetNumberOfDegreesOfFreedomPerNode (  void   )  const [inline, virtual]

1D stress elements have 2 DOFs per node. In reality there is only one, but it usually makes sense to separate it into the components that correspond to specific dimensions in space. So the number of DOFs per node is equal to the number of spatial dimensions. Definition at line 102 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> virtual void itk::fem::Element1DStress< TBaseClass >::GetStiffnessMatrix (  MatrixType &  Ke  )  const [virtual]

Element stiffness matrix is reimplemented here, because we want to be able to use this class to implement 1D stress problem in any number of dimensions i.e. Bar1D, Bar2D, Bar3D.

template<class TBaseClass = Element> virtual void itk::fem::Element1DStress< TBaseClass >::GetStrainDisplacementMatrix (  MatrixType &  B, const MatrixType &  shapeDgl )  const [virtual]

Compute the B matrix.

template<class TBaseClass = Element> virtual void itk::fem::Element1DStress< TBaseClass >::Read (  std::istream &  , void *  info )  [virtual]

Read data for this class from input stream

template<class TBaseClass = Element> virtual void itk::fem::Element1DStress< TBaseClass >::SetMaterial (  Material::ConstPointer  mat_  )  [inline, virtual]

Definition at line 114 of file itkFEMElement1DStress.h.

template<class TBaseClass = Element> virtual void itk::fem::Element1DStress< TBaseClass >::Write (  std::ostream &  f  )  const [virtual]

Write this class to output stream

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Member Data Documentation

template<class TBaseClass = Element> MaterialLinearElasticity::ConstPointer itk::fem::Element1DStress< TBaseClass >::m_mat

Pointer to material properties of the element Definition at line 112 of file itkFEMElement1DStress.h.

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

• itkFEMElement1DStress.h

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