mfem::ElasticityIntegrator Class Reference

#include <bilininteg.hpp>

Inheritance diagram for mfem::ElasticityIntegrator:

Collaboration diagram for mfem::ElasticityIntegrator:

Public Member Functions
	ElasticityIntegrator (Coefficient &l, Coefficient &m)
	ElasticityIntegrator (Coefficient &m, double q_l, double q_m)
virtual void	AssembleElementMatrix (const FiniteElement &, ElementTransformation &, DenseMatrix &)
	Given a particular Finite Element computes the element matrix elmat. More...
virtual void	ComputeElementFlux (const FiniteElement &el, ElementTransformation &Trans, Vector &u, const FiniteElement &fluxelem, Vector &flux, bool with_coef=true, const IntegrationRule *ir=NULL)
virtual double	ComputeFluxEnergy (const FiniteElement &fluxelem, ElementTransformation &Trans, Vector &flux, Vector *d_energy=NULL)
Public Member Functions inherited from mfem::BilinearFormIntegrator
virtual void	AssemblePA (const FiniteElementSpace &fes)
	Method defining partial assembly. More...
virtual void	AssemblePA (const FiniteElementSpace &trial_fes, const FiniteElementSpace &test_fes)
virtual void	AssemblePAInteriorFaces (const FiniteElementSpace &fes)
virtual void	AssemblePABoundaryFaces (const FiniteElementSpace &fes)
virtual void	AssembleDiagonalPA (Vector &diag)
	Assemble diagonal and add it to Vector diag. More...
virtual void	AssembleDiagonalPA_ADAt (const Vector &D, Vector &diag)
	Assemble diagonal of ADA^T (A is this integrator) and add it to diag. More...
virtual void	AddMultPA (const Vector &x, Vector &y) const
	Method for partially assembled action. More...
virtual void	AddMultTransposePA (const Vector &x, Vector &y) const
	Method for partially assembled transposed action. More...
virtual void	AssembleEA (const FiniteElementSpace &fes, Vector &emat, const bool add=true)
	Method defining element assembly. More...
virtual void	AssembleMF (const FiniteElementSpace &fes)
	Method defining matrix-free assembly. More...
virtual void	AddMultMF (const Vector &x, Vector &y) const
virtual void	AddMultTransposeMF (const Vector &x, Vector &y) const
virtual void	AssembleDiagonalMF (Vector &diag)
	Assemble diagonal and add it to Vector diag. More...
virtual void	AssembleEAInteriorFaces (const FiniteElementSpace &fes, Vector &ea_data_int, Vector &ea_data_ext, const bool add=true)
virtual void	AssembleEABoundaryFaces (const FiniteElementSpace &fes, Vector &ea_data_bdr, const bool add=true)
virtual void	AssembleElementMatrix2 (const FiniteElement &trial_fe, const FiniteElement &test_fe, ElementTransformation &Trans, DenseMatrix &elmat)
virtual void	AssembleFaceMatrix (const FiniteElement &el1, const FiniteElement &el2, FaceElementTransformations &Trans, DenseMatrix &elmat)
virtual void	AssembleFaceMatrix (const FiniteElement &trial_face_fe, const FiniteElement &test_fe1, const FiniteElement &test_fe2, FaceElementTransformations &Trans, DenseMatrix &elmat)
virtual void	AssembleElementVector (const FiniteElement &el, ElementTransformation &Tr, const Vector &elfun, Vector &elvect)
	Perform the local action of the BilinearFormIntegrator. Note that the default implementation in the base class is general but not efficient. More...
virtual void	AssembleFaceVector (const FiniteElement &el1, const FiniteElement &el2, FaceElementTransformations &Tr, const Vector &elfun, Vector &elvect)
	Perform the local action of the BilinearFormIntegrator resulting from a face integral term. Note that the default implementation in the base class is general but not efficient. More...
virtual void	AssembleElementGrad (const FiniteElement &el, ElementTransformation &Tr, const Vector &elfun, DenseMatrix &elmat)
	Assemble the local gradient matrix. More...
virtual void	AssembleFaceGrad (const FiniteElement &el1, const FiniteElement &el2, FaceElementTransformations &Tr, const Vector &elfun, DenseMatrix &elmat)
	Assemble the local action of the gradient of the NonlinearFormIntegrator resulting from a face integral term. More...
virtual	~BilinearFormIntegrator ()
virtual void	AssemblePA (const FiniteElementSpace &fes)
	Method defining partial assembly. More...
virtual void	AssemblePA (const FiniteElementSpace &trial_fes, const FiniteElementSpace &test_fes)
Public Member Functions inherited from mfem::NonlinearFormIntegrator
virtual void	SetIntRule (const IntegrationRule *ir)
	Prescribe a fixed IntegrationRule to use (when ir != NULL) or let the integrator choose (when ir == NULL). More...
void	SetIntegrationRule (const IntegrationRule &ir)
	Prescribe a fixed IntegrationRule to use. More...
void	SetPAMemoryType (MemoryType mt)
const IntegrationRule *	GetIntegrationRule () const
	Get the integration rule of the integrator (possibly NULL). More...
virtual double	GetElementEnergy (const FiniteElement &el, ElementTransformation &Tr, const Vector &elfun)
	Compute the local energy. More...
virtual void	AssembleGradPA (const Vector &x, const FiniteElementSpace &fes)
	Prepare the integrator for partial assembly (PA) gradient evaluations on the given FE space fes at the state x. More...
virtual double	GetLocalStateEnergyPA (const Vector &x) const
	Compute the local (to the MPI rank) energy with partial assembly. More...
virtual void	AddMultGradPA (const Vector &x, Vector &y) const
	Method for partially assembled gradient action. More...
virtual void	AssembleGradDiagonalPA (Vector &diag) const
	Method for computing the diagonal of the gradient with partial assembly. More...
virtual bool	SupportsCeed () const
	Indicates whether this integrator can use a Ceed backend. More...
ceed::Operator &	GetCeedOp ()
virtual	~NonlinearFormIntegrator ()

Protected Attributes
double	q_lambda
double	q_mu
Coefficient *	lambda
Coefficient *	mu
Protected Attributes inherited from mfem::NonlinearFormIntegrator
const IntegrationRule *	IntRule
ceed::Operator *	ceedOp
MemoryType	pa_mt = MemoryType::DEFAULT

Additional Inherited Members
Protected Member Functions inherited from mfem::BilinearFormIntegrator
	BilinearFormIntegrator (const IntegrationRule *ir=NULL)
Protected Member Functions inherited from mfem::NonlinearFormIntegrator
	NonlinearFormIntegrator (const IntegrationRule *ir=NULL)

Detailed Description

Integrator for the linear elasticity form: a(u,v) = (lambda div(u), div(v)) + (2 mu e(u), e(v)), where e(v) = (1/2) (grad(v) + grad(v)^T). This is a 'Vector' integrator, i.e. defined for FE spaces using multiple copies of a scalar FE space.

Definition at line 2896 of file bilininteg.hpp.

Constructor & Destructor Documentation

ElasticityIntegrator() [1/2]

mfem::ElasticityIntegrator::ElasticityIntegrator ( Coefficient &  l, Coefficient &  m  )

inline

Definition at line 2910 of file bilininteg.hpp.

ElasticityIntegrator() [2/2]

mfem::ElasticityIntegrator::ElasticityIntegrator ( Coefficient &  m, double  q_l, double  q_m  )

inline

With this constructor lambda = q_l * m and mu = q_m * m; if dim * q_l + 2 * q_m = 0 then trace(sigma) = 0.

Definition at line 2914 of file bilininteg.hpp.

Member Function Documentation

AssembleElementMatrix()

void mfem::ElasticityIntegrator::AssembleElementMatrix ( const FiniteElement &  el, ElementTransformation &  Trans, DenseMatrix &  elmat  )

virtual

Given a particular Finite Element computes the element matrix elmat.

Reimplemented from mfem::BilinearFormIntegrator.

Definition at line 2966 of file bilininteg.cpp.

ComputeElementFlux()

void mfem::ElasticityIntegrator::ComputeElementFlux ( const FiniteElement &  el, ElementTransformation &  Trans, Vector &  u, const FiniteElement &  fluxelem, Vector &  flux, bool  with_coef = true, const IntegrationRule *  ir = NULL  )

virtual

Compute the stress corresponding to the local displacement u and interpolate it at the nodes of the given fluxelem. Only the symmetric part of the stress is stored, so that the size of flux is equal to the number of DOFs in fluxelem times dim*(dim+1)/2. In 2D, the order of the stress components is: s_xx, s_yy, s_xy. In 3D, it is: s_xx, s_yy, s_zz, s_xy, s_xz, s_yz. In other words, flux is the local vector for a FE space with dim*(dim+1)/2 vector components, based on the finite element fluxelem. The integration rule is taken from fluxelem. ir exists to specific an alternative integration rule.

Reimplemented from mfem::BilinearFormIntegrator.

Definition at line 3048 of file bilininteg.cpp.

ComputeFluxEnergy()

double mfem::ElasticityIntegrator::ComputeFluxEnergy ( const FiniteElement &  fluxelem, ElementTransformation &  Trans, Vector &  flux, Vector *  d_energy = NULL  )

virtual

Compute the element energy (integral of the strain energy density) corresponding to the stress represented by flux which is a vector of coefficients multiplying the basis functions defined by fluxelem. In other words, flux is the local vector for a FE space with dim*(dim+1)/2 vector components, based on the finite element fluxelem. The number of components, dim*(dim+1)/2 is such that it represents the symmetric part of the (symmetric) stress tensor. The order of the components is: s_xx, s_yy, s_xy in 2D, and s_xx, s_yy, s_zz, s_xy, s_xz, s_yz in 3D.

Reimplemented from mfem::BilinearFormIntegrator.

Definition at line 3127 of file bilininteg.cpp.

Member Data Documentation

lambda

Coefficient* mfem::ElasticityIntegrator::lambda

protected

Definition at line 2900 of file bilininteg.hpp.

mu

Coefficient * mfem::ElasticityIntegrator::mu

protected

Definition at line 2900 of file bilininteg.hpp.

q_lambda

double mfem::ElasticityIntegrator::q_lambda

protected

Definition at line 2899 of file bilininteg.hpp.

q_mu

double mfem::ElasticityIntegrator::q_mu

protected

Definition at line 2899 of file bilininteg.hpp.

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

• fem/bilininteg.hpp
• fem/bilininteg.cpp