FE_Nedelec< dim > Class Template Reference

#include <deal.II/fe/fe_nedelec.h>

Inheritance diagram for FE_Nedelec< dim >:

Public Member Functions
	FE_Nedelec (const unsigned int order)
virtual std::string	get_name () const override
virtual bool	has_support_on_face (const unsigned int shape_index, const unsigned int face_index) const override
virtual bool	hp_constraints_are_implemented () const override
virtual FiniteElementDomination::Domination	compare_for_face_domination (const FiniteElement< dim > &fe_other) const override
virtual std::vector< std::pair< unsigned int, unsigned int > >	hp_vertex_dof_identities (const FiniteElement< dim > &fe_other) const override
virtual std::vector< std::pair< unsigned int, unsigned int > >	hp_line_dof_identities (const FiniteElement< dim > &fe_other) const override
virtual std::vector< std::pair< unsigned int, unsigned int > >	hp_quad_dof_identities (const FiniteElement< dim > &fe_other) const override
virtual void	get_face_interpolation_matrix (const FiniteElement< dim > &source, FullMatrix< double > &matrix) const override
virtual void	get_subface_interpolation_matrix (const FiniteElement< dim > &source, const unsigned int subface, FullMatrix< double > &matrix) const override
virtual const FullMatrix< double > &	get_restriction_matrix (const unsigned int child, const RefinementCase< dim > &refinement_case=RefinementCase< dim >::isotropic_refinement) const override
virtual const FullMatrix< double > &	get_prolongation_matrix (const unsigned int child, const RefinementCase< dim > &refinement_case=RefinementCase< dim >::isotropic_refinement) const override
virtual void	convert_generalized_support_point_values_to_dof_values (const std::vector< Vector< double >> &support_point_values, std::vector< double > &nodal_values) const override
virtual std::pair< Table< 2, bool >, std::vector< unsigned int > >	get_constant_modes () const override
virtual std::size_t	memory_consumption () const override
virtual std::unique_ptr< FiniteElement< dim, dim > >	clone () const override
Public Member Functions inherited from FE_PolyTensor< PolynomialsNedelec< dim >, dim >
	FE_PolyTensor (const unsigned int degree, const FiniteElementData< dim > &fe_data, const std::vector< bool > &restriction_is_additive_flags, const std::vector< ComponentMask > &nonzero_components)
virtual double	shape_value (const unsigned int i, const Point< dim > &p) const override
virtual Tensor< 1, dim >	shape_grad (const unsigned int i, const Point< dim > &p) const override
virtual Tensor< 2, dim >	shape_grad_grad (const unsigned int i, const Point< dim > &p) const override
Public Member Functions inherited from FiniteElement< dim, dim >
	FiniteElement (const FiniteElementData< dim > &fe_data, const std::vector< bool > &restriction_is_additive_flags, const std::vector< ComponentMask > &nonzero_components)
	FiniteElement (FiniteElement< dim, spacedim > &&)=default
	FiniteElement (const FiniteElement< dim, spacedim > &)=default
virtual	~FiniteElement () override=default
std::pair< std::unique_ptr< FiniteElement< dim, spacedim > >, unsigned int >	operator^ (const unsigned int multiplicity) const
const FiniteElement< dim, spacedim > &	operator[] (const unsigned int fe_index) const
virtual bool	operator== (const FiniteElement< dim, spacedim > &fe) const
bool	operator!= (const FiniteElement< dim, spacedim > &) const
virtual Tensor< 3, dim >	shape_3rd_derivative (const unsigned int i, const Point< dim > &p) const
virtual Tensor< 3, dim >	shape_3rd_derivative_component (const unsigned int i, const Point< dim > &p, const unsigned int component) const
virtual Tensor< 4, dim >	shape_4th_derivative (const unsigned int i, const Point< dim > &p) const
virtual Tensor< 4, dim >	shape_4th_derivative_component (const unsigned int i, const Point< dim > &p, const unsigned int component) const
bool	prolongation_is_implemented () const
bool	isotropic_prolongation_is_implemented () const
bool	restriction_is_implemented () const
bool	isotropic_restriction_is_implemented () const
bool	restriction_is_additive (const unsigned int index) const
const FullMatrix< double > &	constraints (const ::internal::SubfaceCase< dim > &subface_case=::internal::SubfaceCase< dim >::case_isotropic) const
bool	constraints_are_implemented (const ::internal::SubfaceCase< dim > &subface_case=::internal::SubfaceCase< dim >::case_isotropic) const
virtual void	get_interpolation_matrix (const FiniteElement< dim, spacedim > &source, FullMatrix< double > &matrix) const
virtual void	get_face_interpolation_matrix (const FiniteElement< dim, spacedim > &source, FullMatrix< double > &matrix) const
virtual void	get_subface_interpolation_matrix (const FiniteElement< dim, spacedim > &source, const unsigned int subface, FullMatrix< double > &matrix) const
virtual std::vector< std::pair< unsigned int, unsigned int > >	hp_vertex_dof_identities (const FiniteElement< dim, spacedim > &fe_other) const
virtual std::vector< std::pair< unsigned int, unsigned int > >	hp_line_dof_identities (const FiniteElement< dim, spacedim > &fe_other) const
virtual std::vector< std::pair< unsigned int, unsigned int > >	hp_quad_dof_identities (const FiniteElement< dim, spacedim > &fe_other) const
virtual FiniteElementDomination::Domination	compare_for_face_domination (const FiniteElement< dim, spacedim > &fe_other) const
std::pair< unsigned int, unsigned int >	system_to_component_index (const unsigned int index) const
unsigned int	component_to_system_index (const unsigned int component, const unsigned int index) const
std::pair< unsigned int, unsigned int >	face_system_to_component_index (const unsigned int index) const
unsigned int	adjust_quad_dof_index_for_face_orientation (const unsigned int index, const bool face_orientation, const bool face_flip, const bool face_rotation) const
virtual unsigned int	face_to_cell_index (const unsigned int face_dof_index, const unsigned int face, const bool face_orientation=true, const bool face_flip=false, const bool face_rotation=false) const
unsigned int	adjust_line_dof_index_for_line_orientation (const unsigned int index, const bool line_orientation) const
const ComponentMask &	get_nonzero_components (const unsigned int i) const
unsigned int	n_nonzero_components (const unsigned int i) const
bool	is_primitive () const
bool	is_primitive (const unsigned int i) const
unsigned int	n_base_elements () const
virtual const FiniteElement< dim, spacedim > &	base_element (const unsigned int index) const
unsigned int	element_multiplicity (const unsigned int index) const
const FiniteElement< dim, spacedim > &	get_sub_fe (const ComponentMask &mask) const
virtual const FiniteElement< dim, spacedim > &	get_sub_fe (const unsigned int first_component, const unsigned int n_selected_components) const
std::pair< std::pair< unsigned int, unsigned int >, unsigned int >	system_to_base_index (const unsigned int index) const
std::pair< std::pair< unsigned int, unsigned int >, unsigned int >	face_system_to_base_index (const unsigned int index) const
types::global_dof_index	first_block_of_base (const unsigned int b) const
std::pair< unsigned int, unsigned int >	component_to_base_index (const unsigned int component) const
std::pair< unsigned int, unsigned int >	block_to_base_index (const unsigned int block) const
std::pair< unsigned int, types::global_dof_index >	system_to_block_index (const unsigned int component) const
unsigned int	component_to_block_index (const unsigned int component) const
ComponentMask	component_mask (const FEValuesExtractors::Scalar &scalar) const
ComponentMask	component_mask (const FEValuesExtractors::Vector &vector) const
ComponentMask	component_mask (const FEValuesExtractors::SymmetricTensor< 2 > &sym_tensor) const
ComponentMask	component_mask (const BlockMask &block_mask) const
BlockMask	block_mask (const FEValuesExtractors::Scalar &scalar) const
BlockMask	block_mask (const FEValuesExtractors::Vector &vector) const
BlockMask	block_mask (const FEValuesExtractors::SymmetricTensor< 2 > &sym_tensor) const
BlockMask	block_mask (const ComponentMask &component_mask) const
const std::vector< Point< dim > > &	get_unit_support_points () const
bool	has_support_points () const
virtual Point< dim >	unit_support_point (const unsigned int index) const
const std::vector< Point< dim-1 > > &	get_unit_face_support_points () const
bool	has_face_support_points () const
virtual Point< dim-1 >	unit_face_support_point (const unsigned int index) const
const std::vector< Point< dim > > &	get_generalized_support_points () const
bool	has_generalized_support_points () const
const std::vector< Point< dim-1 > > &	get_generalized_face_support_points () const
bool	has_generalized_face_support_points () const
GeometryPrimitive	get_associated_geometry_primitive (const unsigned int cell_dof_index) const
Public Member Functions inherited from Subscriptor
	Subscriptor ()
	Subscriptor (const Subscriptor &)
	Subscriptor (Subscriptor &&) noexcept
virtual	~Subscriptor ()
Subscriptor &	operator= (const Subscriptor &)
Subscriptor &	operator= (Subscriptor &&) noexcept
void	subscribe (const char *identifier=nullptr) const
void	unsubscribe (const char *identifier=nullptr) const
unsigned int	n_subscriptions () const
template<typename StreamType >
void	list_subscribers (StreamType &stream) const
void	list_subscribers () const
template<class Archive >
void	serialize (Archive &ar, const unsigned int version)
Public Member Functions inherited from FiniteElementData< dim >
	FiniteElementData (const std::vector< unsigned int > &dofs_per_object, const unsigned int n_components, const unsigned int degree, const Conformity conformity=unknown, const BlockIndices &block_indices=BlockIndices())
unsigned int	n_dofs_per_vertex () const
unsigned int	n_dofs_per_line () const
unsigned int	n_dofs_per_quad () const
unsigned int	n_dofs_per_hex () const
unsigned int	n_dofs_per_face () const
unsigned int	n_dofs_per_cell () const
template<int structdim>
unsigned int	n_dofs_per_object () const
unsigned int	n_components () const
unsigned int	n_blocks () const
const BlockIndices &	block_indices () const
unsigned int	tensor_degree () const
bool	conforms (const Conformity) const
bool	operator== (const FiniteElementData &) const

Private Member Functions
void	initialize_support_points (const unsigned int order)
void	initialize_restriction ()

Static Private Member Functions
static std::vector< unsigned int >	get_dpo_vector (const unsigned int degree, bool dg=false)

Private Attributes
Table< 2, double >	boundary_weights

Friends
template<int dim1>
class	FE_Nedelec

Additional Inherited Members
Public Types inherited from FiniteElementData< dim >
Static Public Member Functions inherited from FiniteElement< dim, dim >
static::ExceptionBase &	ExcShapeFunctionNotPrimitive (int arg1)
static::ExceptionBase &	ExcFENotPrimitive ()
static::ExceptionBase &	ExcUnitShapeValuesDoNotExist ()
static::ExceptionBase &	ExcFEHasNoSupportPoints ()
static::ExceptionBase &	ExcEmbeddingVoid ()
static::ExceptionBase &	ExcProjectionVoid ()
static::ExceptionBase &	ExcWrongInterfaceMatrixSize (int arg1, int arg2)
static::ExceptionBase &	ExcInterpolationNotImplemented ()
Static Public Member Functions inherited from Subscriptor
static::ExceptionBase &	ExcInUse (int arg1, std::string arg2, std::string arg3)
static::ExceptionBase &	ExcNoSubscriber (std::string arg1, std::string arg2)
Public Attributes inherited from FiniteElementData< dim >
const unsigned int	dofs_per_vertex
const unsigned int	dofs_per_line
const unsigned int	dofs_per_quad
const unsigned int	dofs_per_hex
const unsigned int	first_line_index
const unsigned int	first_quad_index
const unsigned int	first_hex_index
const unsigned int	first_face_line_index
const unsigned int	first_face_quad_index
const unsigned int	dofs_per_face
const unsigned int	dofs_per_cell
const unsigned int	components
const unsigned int	degree
const Conformity	conforming_space
const BlockIndices	block_indices_data
Static Public Attributes inherited from FiniteElement< dim, dim >
static const unsigned int	space_dimension
Static Public Attributes inherited from FiniteElementData< dim >
static const unsigned int	dimension = dim
Protected Member Functions inherited from FiniteElement< dim, dim >
void	reinit_restriction_and_prolongation_matrices (const bool isotropic_restriction_only=false, const bool isotropic_prolongation_only=false)
TableIndices< 2 >	interface_constraints_size () const
virtual std::unique_ptr< InternalDataBase >	get_data (const UpdateFlags update_flags, const Mapping< dim, spacedim > &mapping, const Quadrature< dim > &quadrature,::internal::FEValuesImplementation::FiniteElementRelatedData< dim, spacedim > &output_data) const =0
virtual std::unique_ptr< InternalDataBase >	get_face_data (const UpdateFlags update_flags, const Mapping< dim, spacedim > &mapping, const Quadrature< dim-1 > &quadrature,::internal::FEValuesImplementation::FiniteElementRelatedData< dim, spacedim > &output_data) const
virtual std::unique_ptr< InternalDataBase >	get_subface_data (const UpdateFlags update_flags, const Mapping< dim, spacedim > &mapping, const Quadrature< dim-1 > &quadrature,::internal::FEValuesImplementation::FiniteElementRelatedData< dim, spacedim > &output_data) const
virtual void	fill_fe_values (const typename Triangulation< dim, spacedim >::cell_iterator &cell, const CellSimilarity::Similarity cell_similarity, const Quadrature< dim > &quadrature, const Mapping< dim, spacedim > &mapping, const typename Mapping< dim, spacedim >::InternalDataBase &mapping_internal, const ::internal::FEValuesImplementation::MappingRelatedData< dim, spacedim > &mapping_data, const InternalDataBase &fe_internal,::internal::FEValuesImplementation::FiniteElementRelatedData< dim, spacedim > &output_data) const =0
virtual void	fill_fe_face_values (const typename Triangulation< dim, spacedim >::cell_iterator &cell, const unsigned int face_no, const Quadrature< dim-1 > &quadrature, const Mapping< dim, spacedim > &mapping, const typename Mapping< dim, spacedim >::InternalDataBase &mapping_internal, const ::internal::FEValuesImplementation::MappingRelatedData< dim, spacedim > &mapping_data, const InternalDataBase &fe_internal,::internal::FEValuesImplementation::FiniteElementRelatedData< dim, spacedim > &output_data) const =0
virtual void	fill_fe_subface_values (const typename Triangulation< dim, spacedim >::cell_iterator &cell, const unsigned int face_no, const unsigned int sub_no, const Quadrature< dim-1 > &quadrature, const Mapping< dim, spacedim > &mapping, const typename Mapping< dim, spacedim >::InternalDataBase &mapping_internal, const ::internal::FEValuesImplementation::MappingRelatedData< dim, spacedim > &mapping_data, const InternalDataBase &fe_internal,::internal::FEValuesImplementation::FiniteElementRelatedData< dim, spacedim > &output_data) const =0
Static Protected Member Functions inherited from FiniteElement< dim, dim >
static std::vector< unsigned int >	compute_n_nonzero_components (const std::vector< ComponentMask > &nonzero_components)
Protected Attributes inherited from FE_PolyTensor< PolynomialsNedelec< dim >, dim >
MappingType	mapping_type
PolynomialsNedelec< dim >	poly_space
FullMatrix< double >	inverse_node_matrix
Threads::Mutex	cache_mutex
Point< dim >	cached_point
std::vector< Tensor< 1, dim > >	cached_values
std::vector< Tensor< 2, dim > >	cached_grads
std::vector< Tensor< 3, dim > >	cached_grad_grads
Protected Attributes inherited from FiniteElement< dim, dim >
std::vector< std::vector< FullMatrix< double > > >	restriction
std::vector< std::vector< FullMatrix< double > > >	prolongation
FullMatrix< double >	interface_constraints
std::vector< Point< dim > >	unit_support_points
std::vector< Point< dim-1 > >	unit_face_support_points
std::vector< Point< dim > >	generalized_support_points
std::vector< Point< dim-1 > >	generalized_face_support_points
Table< 2, int >	adjust_quad_dof_index_for_face_orientation_table
std::vector< int >	adjust_line_dof_index_for_line_orientation_table
std::vector< std::pair< unsigned int, unsigned int > >	system_to_component_table
std::vector< std::pair< unsigned int, unsigned int > >	face_system_to_component_table
std::vector< std::pair< std::pair< unsigned int, unsigned int >, unsigned int > >	system_to_base_table
std::vector< std::pair< std::pair< unsigned int, unsigned int >, unsigned int > >	face_system_to_base_table
BlockIndices	base_to_block_indices
std::vector< std::pair< std::pair< unsigned int, unsigned int >, unsigned int > >	component_to_base_table
const std::vector< bool >	restriction_is_additive_flags
const std::vector< ComponentMask >	nonzero_components
const std::vector< unsigned int >	n_nonzero_components_table
const bool	cached_primitivity

Detailed Description

template<int dim>
class FE_Nedelec< dim >

Warning

Several aspects of the implementation are experimental. For the moment, it is safe to use the element on globally refined meshes with consistent orientation of faces. See the todo entries below for more detailed caveats.

Implementation of Nédélec elements, conforming with the space H^curl. These elements generate vector fields with tangential components continuous between mesh cells.

We follow the convention that the degree of Nédélec elements denotes the polynomial degree of the largest complete polynomial subspace contained in the Nédélec space. This leads to the consistently numbered sequence of spaces

\[ Q_{k+1} \stackrel{\text{grad}}{\rightarrow} \text{Nedelec}_k \stackrel{\text{curl}}{\rightarrow} \text{RaviartThomas}_k \stackrel{\text{div}}{\rightarrow} DGQ_{k} \]

Consequently, approximation order of the Nédélec space equals the value degree given to the constructor. In this scheme, the lowest order element would be created by the call FE_Nedelec<dim>(0). Note that this follows the convention of Brezzi and Raviart, though not the one used in the original paper by Nédélec.

This class is not implemented for the codimension one case (spacedim != dim).

Todo:

Even if this element is implemented for two and three space dimensions, the definition of the node values relies on consistently oriented faces in 3D. Therefore, care should be taken on complicated meshes.

Interpolation

The interpolation operators associated with the Nédélec element are constructed such that interpolation and computing the curl are commuting operations on rectangular mesh cells. We require this from interpolating arbitrary functions as well as the restriction matrices.

Node values

The node values for an element of degree k on the reference cell are:

1. On edges: the moments of the tangential component with respect to polynomials of degree k.
2. On faces: the moments of the tangential components with respect to dim-1 dimensional FE_Nedelec polynomials of degree k-1.
3. In cells: the moments with respect to gradients of polynomials in FE_Q of degree k.

Generalized support points

The node values above rely on integrals, which will be computed by quadrature rules themselves. The generalized support points are a set of points such that this quadrature can be performed with sufficient accuracy. The points needed are those of QGauss_k+1 on each edge and QGauss_k+2 on each face and in the interior of the cell (or none for N₁).

Author

Markus Bürg

Date

2009, 2010, 2011

Definition at line 113 of file fe_nedelec.h.

Constructor & Destructor Documentation

template<int dim>

FE_Nedelec< dim >::FE_Nedelec

(

const unsigned int

order

)

Constructor for the Nédélec element of given order. The maximal polynomial degree of the shape functions is order+1 (in each variable; the total polynomial degree may be higher).

Definition at line 71 of file fe_nedelec.cc.

Member Function Documentation

template<int dim>

std::string FE_Nedelec< dim >::get_name ( ) const

overridevirtual

Return a string that uniquely identifies a finite element. This class returns FE_Nedelec<dim>(degree), with dim and degree replaced by appropriate values.

Implements FiniteElement< dim, dim >.

Definition at line 207 of file fe_nedelec.cc.

template<int dim>

bool FE_Nedelec< dim >::has_support_on_face ( const unsigned int  shape_index, const unsigned int  face_index  ) const

overridevirtual

This function returns true, if the shape function shape_index has non-zero function values somewhere on the face face_index.

Reimplemented from FiniteElement< dim, dim >.

Definition at line 2036 of file fe_nedelec.cc.

template<int dim>

bool FE_Nedelec< dim >::hp_constraints_are_implemented ( ) const

overridevirtual

Return whether this element implements its hanging node constraints in the new way, which has to be used to make elements "hp compatible".

For the FE_Nedelec class the result is always true (independent of the degree of the element), as it implements the complete set of functions necessary for hp capability.

Reimplemented from FiniteElement< dim, dim >.

Definition at line 2324 of file fe_nedelec.cc.

template<int dim>

FiniteElementDomination::Domination FE_Nedelec< dim >::compare_for_face_domination ( const FiniteElement< dim > &  fe_other ) const

overridevirtual

Return whether this element dominates the one, which is given as argument.

Definition at line 2277 of file fe_nedelec.cc.

template<int dim>

std::vector< std::pair< unsigned int, unsigned int > > FE_Nedelec< dim >::hp_vertex_dof_identities ( const FiniteElement< dim > &  fe_other ) const

overridevirtual

If, on a vertex, several finite elements are active, the hp code first assigns the degrees of freedom of each of these FEs different global indices. It then calls this function to find out which of them should get identical values, and consequently can receive the same global DoF index. This function therefore returns a list of identities between DoFs of the present finite element object with the DoFs of fe_other, which is a reference to a finite element object representing one of the other finite elements active on this particular vertex. The function computes which of the degrees of freedom of the two finite element objects are equivalent, both numbered between zero and the corresponding value of dofs_per_vertex of the two finite elements. The first index of each pair denotes one of the vertex dofs of the present element, whereas the second is the corresponding index of the other finite element.

Definition at line 2331 of file fe_nedelec.cc.

template<int dim>

std::vector< std::pair< unsigned int, unsigned int > > FE_Nedelec< dim >::hp_line_dof_identities ( const FiniteElement< dim > &  fe_other ) const

overridevirtual

Same as hp_vertex_dof_indices(), except that the function treats degrees of freedom on lines.

Definition at line 2340 of file fe_nedelec.cc.

template<int dim>

std::vector< std::pair< unsigned int, unsigned int > > FE_Nedelec< dim >::hp_quad_dof_identities ( const FiniteElement< dim > &  fe_other ) const

overridevirtual

Same as hp_vertex_dof_indices(), except that the function treats degrees of freedom on lines.

Definition at line 2382 of file fe_nedelec.cc.

template<int dim>

void FE_Nedelec< dim >::get_face_interpolation_matrix ( const FiniteElement< dim > &  source, FullMatrix< double > &  matrix  ) const

overridevirtual

Return the matrix interpolating from a face of one element to the face of the neighboring element. The size of the matrix is then source.dofs_per_face times this->dofs_per_face.

Derived elements will have to implement this function. They may only provide interpolation matrices for certain source finite elements, for example those from the same family. If they don't implement interpolation from a given element, then they must throw an exception of type FiniteElement<dim>::ExcInterpolationNotImplemented.

Definition at line 2436 of file fe_nedelec.cc.

template<int dim>

void FE_Nedelec< dim >::get_subface_interpolation_matrix ( const FiniteElement< dim > &  source, const unsigned int  subface, FullMatrix< double > &  matrix  ) const

overridevirtual

Return the matrix interpolating from a face of one element to the subface of the neighboring element. The size of the matrix is then source.dofs_per_face times this->dofs_per_face.

Derived elements will have to implement this function. They may only provide interpolation matrices for certain source finite elements, for example those from the same family. If they don't implement interpolation from a given element, then they must throw an exception of type ExcInterpolationNotImplemented.

Definition at line 2538 of file fe_nedelec.cc.

template<int dim>

const FullMatrix< double > & FE_Nedelec< dim >::get_restriction_matrix ( const unsigned int  child, const RefinementCase< dim > &  refinement_case = RefinementCase<dim>::isotropic_refinement  ) const

overridevirtual

Projection from a fine grid space onto a coarse grid space. If this projection operator is associated with a matrix P, then the restriction of this matrix P_i to a single child cell is returned here.

The matrix P is the concatenation or the sum of the cell matrices P_i, depending on the restriction_is_additive_flags. This distinguishes interpolation (concatenation) and projection with respect to scalar products (summation).

Row and column indices are related to coarse grid and fine grid spaces, respectively, consistent with the definition of the associated operator.

Reimplemented from FiniteElement< dim, dim >.

Definition at line 3029 of file fe_nedelec.cc.

template<int dim>

const FullMatrix< double > & FE_Nedelec< dim >::get_prolongation_matrix ( const unsigned int  child, const RefinementCase< dim > &  refinement_case = RefinementCase<dim>::isotropic_refinement  ) const

overridevirtual

Embedding matrix between grids.

The identity operator from a coarse grid space into a fine grid space is associated with a matrix P. The restriction of this matrix P_i to a single child cell is returned here.

The matrix P is the concatenation, not the sum of the cell matrices P_i. That is, if the same non-zero entry j,k exists in two different child matrices P_i, the value should be the same in both matrices and it is copied into the matrix P only once.

Row and column indices are related to fine grid and coarse grid spaces, respectively, consistent with the definition of the associated operator.

These matrices are used by routines assembling the prolongation matrix for multi-level methods. Upon assembling the transfer matrix between cells using this matrix array, zero elements in the prolongation matrix are discarded and will not fill up the transfer matrix.

Reimplemented from FiniteElement< dim, dim >.

Definition at line 2969 of file fe_nedelec.cc.

template<int dim>

void FE_Nedelec< dim >::convert_generalized_support_point_values_to_dof_values ( const std::vector< Vector< double >> &  support_point_values, std::vector< double > &  nodal_values  ) const

overridevirtual

Given the values of a function \(f(\mathbf x)\) at the (generalized) support points of the reference cell, this function then computes what the nodal values of the element are, i.e., \(\Psi_i[f]\), where \(\Psi_i\) are the node functionals of the element (see also Node values or node functionals). The values \(\Psi_i[f]\) are then the expansion coefficients for the shape functions of the finite element function that interpolates the given function \(f(x)\), i.e., \( f_h(\mathbf x) = \sum_i \Psi_i[f] \varphi_i(\mathbf x) \) is the finite element interpolant of \(f\) with the current element. The operation described here is used, for example, in the FETools::compute_node_matrix() function.

In more detail, let us assume that the generalized support points (see this glossary entry ) of the current element are \(\hat{\mathbf x}_i\) and that the node functionals associated with the current element are \(\Psi_i[\cdot]\). Then, the fact that the element is based on generalized support points, implies that if we apply \(\Psi_i\) to a (possibly vector-valued) finite element function \(\varphi\), the result must have the form \(\Psi_i[\varphi] = f_i(\varphi(\hat{\mathbf x}_i))\) – in other words, the value of the node functional \(\Psi_i\) applied to \(\varphi\) only depends on the values of \(\varphi\) at \(\hat{\mathbf x}_i\) and not on values anywhere else, or integrals of \(\varphi\), or any other kind of information.

The exact form of \(f_i\) depends on the element. For example, for scalar Lagrange elements, we have that in fact \(\Psi_i[\varphi] = \varphi(\hat{\mathbf x}_i)\). If you combine multiple scalar Lagrange elements via an FESystem object, then \(\Psi_i[\varphi] = \varphi(\hat{\mathbf x}_i)_{c(i)}\) where \(c(i)\) is the result of the FiniteElement::system_to_component_index() function's return value's first component. In these two cases, \(f_i\) is therefore simply the identity (in the scalar case) or a function that selects a particular vector component of its argument. On the other hand, for Raviart-Thomas elements, one would have that \(f_i(\mathbf y) = \mathbf y \cdot \mathbf n_i\) where \(\mathbf n_i\) is the normal vector of the face at which the shape function is defined.

Given all of this, what this function does is the following: If you input a list of values of a function \(\varphi\) at all generalized support points (where each value is in fact a vector of values with as many components as the element has), then this function returns a vector of values obtained by applying the node functionals to these values. In other words, if you pass in \(\{\varphi(\hat{\mathbf x}_i)\}_{i=0}^{N-1}\) then you will get out a vector \(\{\Psi[\varphi]\}_{i=0}^{N-1}\) where \(N\) equals dofs_per_cell.

Parameters

[in]	support_point_values	An array of size dofs_per_cell (which equals the number of points the get_generalized_support_points() function will return) where each element is a vector with as many entries as the element has vector components. This array should contain the values of a function at the generalized support points of the current element.
[out]	nodal_values	An array of size dofs_per_cell that contains the node functionals of the element applied to the given function.

Note

It is safe to call this function for (transformed) values on the real cell only for elements with trivial MappingType. For all other elements (for example for H(curl), or H(div) conforming elements) vector values have to be transformed to the reference cell first.

Given what the function is supposed to do, the function clearly can only work for elements that actually implement (generalized) support points. Elements that do not have generalized support points – e.g., elements whose nodal functionals evaluate integrals or moments of functions (such as FE_Q_Hierarchical) – can in general not make sense of the operation that is required for this function. They consequently may not implement it.

Reimplemented from FiniteElement< dim, dim >.

Definition at line 3098 of file fe_nedelec.cc.

template<int dim>

std::pair< Table< 2, bool >, std::vector< unsigned int > > FE_Nedelec< dim >::get_constant_modes ( ) const

overridevirtual

Return a list of constant modes of the element.

Reimplemented from FiniteElement< dim, dim >.

Definition at line 4046 of file fe_nedelec.cc.

template<int dim>

std::size_t FE_Nedelec< dim >::memory_consumption ( ) const

overridevirtual

Determine an estimate for the memory consumption (in bytes) of this object.

This function is made virtual, since finite element objects are usually accessed through pointers to their base class, rather than the class itself.

Reimplemented from FiniteElement< dim, dim >.

Definition at line 4062 of file fe_nedelec.cc.

template<int dim>

std::unique_ptr< FiniteElement< dim, dim > > FE_Nedelec< dim >::clone ( ) const

overridevirtual

A sort of virtual copy constructor, this function returns a copy of the finite element object. Derived classes need to override the function here in this base class and return an object of the same type as the derived class.

Some places in the library, for example the constructors of FESystem as well as the hp::FECollection class, need to make copies of finite elements without knowing their exact type. They do so through this function.

Implements FiniteElement< dim, dim >.

Definition at line 225 of file fe_nedelec.cc.

template<int dim>

std::vector< unsigned int > FE_Nedelec< dim >::get_dpo_vector ( const unsigned int  degree, bool  dg = false  )

staticprivate

Only for internal use. Its full name is get_dofs_per_object_vector function and it creates the dofs_per_object vector that is needed within the constructor to be passed to the constructor of FiniteElementData.

If the optional argument dg is true, the vector returned will have all degrees of freedom assigned to the cell, none on the faces and edges.

Definition at line 2000 of file fe_nedelec.cc.

template<int dim>

void FE_Nedelec< dim >::initialize_support_points ( const unsigned int  order )

private

Initialize the generalized_support_points field of the FiniteElement class and fill the tables with interpolation weights (boundary_weights and interior_weights). Called from the constructor.

template<int dim>

void FE_Nedelec< dim >::initialize_restriction ( )

private

Initialize the interpolation from functions on refined mesh cells onto the father cell. According to the philosophy of the Nédélec element, this restriction operator preserves the curl of a function weakly.

Definition at line 516 of file fe_nedelec.cc.

Friends And Related Function Documentation

template<int dim>

template<int dim1>

friend class FE_Nedelec

friend

Allow access from other dimensions.

Definition at line 335 of file fe_nedelec.h.

Member Data Documentation

template<int dim>

Table<2, double> FE_Nedelec< dim >::boundary_weights

private

These are the factors multiplied to a function in the generalized_face_support_points when computing the integration.

See the glossary entry on generalized support points for more information.

Definition at line 324 of file fe_nedelec.h.

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

• deal.II/fe/fe_nedelec.h
• /mnt/data/darndt/Sources/dealii-clang-6.0.0/source/fe/fe_nedelec.cc