#include <NodalTetElec.h>

Inheritance diagram for Nektar::LibUtilities::NodalTetElec:

Collaboration diagram for Nektar::LibUtilities::NodalTetElec:

Public Member Functions
virtual	~NodalTetElec ()

const MatrixSharedPtrType	GetI (const PointsKey &pkey)

const MatrixSharedPtrType	GetI (const Array< OneD, const NekDouble > &x, const Array< OneD, const NekDouble > &y, const Array< OneD, const NekDouble > &z)

	NodalTetElec (const PointsKey &key)

Public Member Functions inherited from Nektar::LibUtilities::Points< NekDouble >
virtual	~Points ()

virtual void	Initialize (void)

unsigned int	GetPointsDim () const

unsigned int	GetNumPoints () const

unsigned int	GetTotNumPoints () const

PointsType	GetPointsType () const

const Array< OneD, const DataType > &	GetZ () const

const Array< OneD, const DataType > &	GetW () const

void	GetZW (Array< OneD, const DataType > &z, Array< OneD, const DataType > &w) const

void	GetPoints (Array< OneD, const DataType > &x) const

void	GetPoints (Array< OneD, const DataType > &x, Array< OneD, const DataType > &y) const

void	GetPoints (Array< OneD, const DataType > &x, Array< OneD, const DataType > &y, Array< OneD, const DataType > &z) const

const MatrixSharedPtrType &	GetD (Direction dir=xDir) const

virtual const MatrixSharedPtrType	GetI (const Array< OneD, const DataType > &x)

virtual const MatrixSharedPtrType	GetI (unsigned int numpoints, const Array< OneD, const DataType > &x)

virtual const MatrixSharedPtrType	GetI (const Array< OneD, const DataType > &x, const Array< OneD, const DataType > &y)

virtual const MatrixSharedPtrType	GetGalerkinProjection (const PointsKey &pkey)

Static Public Member Functions
static boost::shared_ptr < PointsBaseType >	Create (const PointsKey &key)

Private Member Functions
	NodalTetElec ()

void	CalculatePoints ()

void	CalculateWeights ()

void	CalculateDerivMatrix ()

void	NodalPointReorder3d ()

void	CalculateInterpMatrix (const Array< OneD, const NekDouble > &xia, const Array< OneD, const NekDouble > &yia, const Array< OneD, const NekDouble > &zia, Array< OneD, NekDouble > &interp)

Additional Inherited Members
Public Types inherited from Nektar::LibUtilities::Points< NekDouble >
typedef NekDouble	DataType

typedef boost::shared_ptr < NekMatrix< DataType > >	MatrixSharedPtrType

Protected Member Functions inherited from Nektar::LibUtilities::Points< NekDouble >
	Points (const PointsKey &key)

Protected Attributes inherited from Nektar::LibUtilities::Points< NekDouble >
PointsKey	m_pointsKey

Array< OneD, DataType >	m_points [3]

Array< OneD, DataType >	m_weights

MatrixSharedPtrType	m_derivmatrix [3]

NekManager< PointsKey, NekMatrix< DataType > , PointsKey::opLess >	m_InterpManager

NekManager< PointsKey, NekMatrix< DataType > , PointsKey::opLess >	m_GalerkinProjectionManager

Detailed Description

Definition at line 52 of file NodalTetElec.h.

Constructor & Destructor Documentation

virtual Nektar::LibUtilities::NodalTetElec::~NodalTetElec ( )

inlinevirtual

Definition at line 55 of file NodalTetElec.h.

56 {

57 }

Nektar::LibUtilities::NodalTetElec::NodalTetElec ( const PointsKey & key )

inline

Definition at line 88 of file NodalTetElec.h.

                                                : PointsBaseType(key)
             {
                 
             }

Nektar::LibUtilities::NodalTetElec::NodalTetElec ( )

inlineprivate

Definition at line 94 of file NodalTetElec.h.

                           :PointsBaseType(NullPointsKey)
             {
               
             }

Member Function Documentation

void Nektar::LibUtilities::NodalTetElec::CalculateDerivMatrix ( )

privatevirtual

Reimplemented from Nektar::LibUtilities::Points< NekDouble >.

Definition at line 233 of file NodalTetElec.cpp.

References Nektar::LibUtilities::Points< NekDouble >::CalculateDerivMatrix(), Nektar::LibUtilities::GetTetXDerivativeMatrix(), Nektar::LibUtilities::GetTetYDerivativeMatrix(), Nektar::LibUtilities::GetTetZDerivativeMatrix(), Nektar::LibUtilities::Points< NekDouble >::m_derivmatrix, and Nektar::LibUtilities::Points< NekDouble >::m_points.

         {
              // Allocate the derivative matrix.
             PointsBaseType::CalculateDerivMatrix();
 
             NekVector<NekDouble> x( m_points[0] );
             NekVector<NekDouble> y( m_points[1] );
             NekVector<NekDouble> z( m_points[2] );
             NekVector<NekDouble> xi = x;
             NekVector<NekDouble> yi = y;
             NekVector<NekDouble> zi = z;
 
             *m_derivmatrix[0] = *GetTetXDerivativeMatrix(x,y,z,xi,yi,zi);
 
             *m_derivmatrix[1] = *GetTetYDerivativeMatrix(x,y,z,xi,yi,zi);
 
             *m_derivmatrix[2] = *GetTetZDerivativeMatrix(x,y,z,xi,yi,zi);
         }

void Nektar::LibUtilities::NodalTetElec::CalculateInterpMatrix	(	const Array< OneD, const NekDouble > &	xia,
		const Array< OneD, const NekDouble > &	yia,
		const Array< OneD, const NekDouble > &	zia,
		Array< OneD, NekDouble > &	interp
	)

private

Definition at line 213 of file NodalTetElec.cpp.

References Nektar::NekVector< DataType >::GetRows(), Nektar::LibUtilities::GetTetInterpolationMatrix(), Nektar::LibUtilities::Points< NekDouble >::GetTotNumPoints(), and Nektar::LibUtilities::Points< NekDouble >::m_points.

Referenced by GetI().

         {
              NekVector<NekDouble>  x( m_points[0] );
              NekVector<NekDouble>  y( m_points[1] );
              NekVector<NekDouble>  z( m_points[2] );
              NekVector<NekDouble> xi( xia );
              NekVector<NekDouble> yi( yia );
              NekVector<NekDouble> zi( zia );
              NekMatrix<NekDouble> interMat = GetTetInterpolationMatrix(x, y, z, xi, yi, zi);
 
              int rows = xi.GetRows(), cols = GetTotNumPoints();
              for( int i = 0; i < rows; ++i ) {
                 for( int j = 0; j < cols; ++j ) {
                     interp[j + i*cols] = interMat(i,j);
                 }
              }             
          }

void Nektar::LibUtilities::NodalTetElec::CalculatePoints ( )

privatevirtual

Reimplemented from Nektar::LibUtilities::Points< NekDouble >.

Definition at line 51 of file NodalTetElec.cpp.

         {
             // Allocate the storage for points
             Points<NekDouble>::CalculatePoints();
 
             int index=0,isum=0;
             const int offset = 5; //offset to match Datafile
             NekDouble b,c,d;
             unsigned int numPoints = GetNumPoints();
 
             // initialize values
             for(unsigned int i=0; i < numPoints-2; ++i)
             {
                 index += NodalTetElecNPTS[i];
             }
 
             for(unsigned int i=0; i < NodalTetElecNPTS[numPoints-2]; ++i, ++index)
             {
                 // 1 Point Symmetry: aaaa
                 if(int(NodalTetElecData[index][0]))
                 {
                     b = NodalTetElecData[index][6];
                     c = NodalTetElecData[index][7];
                     d = NodalTetElecData[index][8];
 
                     m_points[0][isum] = 2.0*b - 1.0;
                     m_points[1][isum] = 2.0*c - 1.0;
                     m_points[2][isum] = 2.0*d - 1.0;
                     isum++;
                     continue;
                 }//end symmetry 1
 
                 
                 // 4 Point symmetry: aaab or abbb
                 if(int(NodalTetElecData[index][1]))
                 {
                     for(unsigned int j=0; j < 4; ++j)
                     {
                         b = NodalTetElecData[index][offset + perm4_3d[j][1]];
                         c = NodalTetElecData[index][offset + perm4_3d[j][2]];
                         d = NodalTetElecData[index][offset + perm4_3d[j][3]];
                         
                         m_points[0][isum] = 2.0*b - 1.0;
                         m_points[1][isum] = 2.0*c - 1.0;
                         m_points[2][isum] = 2.0*d - 1.0;
                         isum++;
                     }//end j
                     continue;
                 }//end symmetry 4
 
                 
                 // 6 Point symmetry: aabb
                 if(int(NodalTetElecData[index][2]))
                 {
                     for(unsigned int j=0; j < 6; ++j)
                     {
                         b = NodalTetElecData[index][offset + perm6_3d[j][1]];
                         c = NodalTetElecData[index][offset + perm6_3d[j][2]];
                         d = NodalTetElecData[index][offset + perm6_3d[j][3]];
                         
                         m_points[0][isum] = 2.0*b - 1.0;
                         m_points[1][isum] = 2.0*c - 1.0;
                         m_points[2][isum] = 2.0*d - 1.0;
                         isum++;
                     }//end j
                     continue;   
                 }//end symmetry6                
                 
 
                 // 12 Point symmetry: case aabc
                 if(int(NodalTetElecData[index][3]) == 1)
                 {
                     for(unsigned int j=0; j < 12; ++j)
                     {
                         b = NodalTetElecData[index][offset + perm12A_3d[j][1]];
                         c = NodalTetElecData[index][offset + perm12A_3d[j][2]];
                         d = NodalTetElecData[index][offset + perm12A_3d[j][3]];
                         
                         m_points[0][isum] = 2.0*b - 1.0;
                         m_points[1][isum] = 2.0*c - 1.0;
                         m_points[2][isum] = 2.0*d - 1.0;
                         isum++;
                     }//end j
                     continue;
                 }//end symmetry 12 aabc
 
                 
                 // 12 Point symmetry: case abcc
                 if(int(NodalTetElecData[index][3]) == 2)
                 {
                     for(unsigned int j=0; j < 12; ++j)
                     {
                         b = NodalTetElecData[index][offset + perm12B_3d[j][1]];
                         c = NodalTetElecData[index][offset + perm12B_3d[j][2]];
                         d = NodalTetElecData[index][offset + perm12B_3d[j][3]];
                         
                         m_points[0][isum] = 2.0*b - 1.0;
                         m_points[1][isum] = 2.0*c - 1.0;
                         m_points[2][isum] = 2.0*d - 1.0;
                         isum++;
                     }//end j
                     continue;
                 }//end symmetry 12 abcc
 
 
                 // 12 Point symmetry: case abbc
                 if(int(NodalTetElecData[index][3]) == 3)
                 {
                     for(unsigned int j=0; j < 12; ++j)
                     {
                         b = NodalTetElecData[index][offset + perm12C_3d[j][1]];
                         c = NodalTetElecData[index][offset + perm12C_3d[j][2]];
                         d = NodalTetElecData[index][offset + perm12C_3d[j][3]];
                         
                         m_points[0][isum] = 2.0*b - 1.0;
                         m_points[1][isum] = 2.0*c - 1.0;
                         m_points[2][isum] = 2.0*d - 1.0;
                         isum++;
                     }//end j
                     continue;
                 }//end symmetry 12 abbc
 
                 // 24 Point symmetry: case abcd
                 if(int(NodalTetElecData[index][4]))
                 {
                     for(unsigned int j=0; j < 24; ++j)
                     {
                         b = NodalTetElecData[index][offset + perm24_3d[j][1]];
                         c = NodalTetElecData[index][offset + perm24_3d[j][2]];
                         d = NodalTetElecData[index][offset + perm24_3d[j][3]];
                         
                         m_points[0][isum] = 2.0*b - 1.0;
                         m_points[1][isum] = 2.0*c - 1.0;
                         m_points[2][isum] = 2.0*d - 1.0;
                         isum++;
                     }//end j
                     continue;
                 }//end symmetry24abcd
                                 
 
             }//end npts
 
             NodalPointReorder3d();
 
             ASSERTL1((static_cast<unsigned int>(isum)==m_pointsKey.GetTotNumPoints()),"sum not equal to npts");
         }

void Nektar::LibUtilities::NodalTetElec::CalculateWeights ( )

privatevirtual

Reimplemented from Nektar::LibUtilities::Points< NekDouble >.

Definition at line 198 of file NodalTetElec.cpp.

References Nektar::LibUtilities::Points< NekDouble >::CalculateWeights(), Nektar::NekVector< DataType >::GetPtr(), Nektar::NekVector< DataType >::GetRows(), Nektar::LibUtilities::Points< NekDouble >::m_points, Nektar::LibUtilities::Points< NekDouble >::m_weights, and Nektar::LibUtilities::MakeTetWeights().

         {
             // Allocate the storage for points
             PointsBaseType::CalculateWeights();
 
             typedef DataType T;
             
             // Solve the Vandermonde system of integrals for the weight vector
             NekVector<T> w = MakeTetWeights(NekVector<T>(m_points[0]), NekVector<T>(m_points[1]), NekVector<T>(m_points[2]));
             
             m_weights = Array<OneD,T>( w.GetRows(), w.GetPtr() );
         }

boost::shared_ptr< PointsBaseType > Nektar::LibUtilities::NodalTetElec::Create ( const PointsKey & key )

static

Definition at line 252 of file NodalTetElec.cpp.

         {
             boost::shared_ptr<PointsBaseType> returnval(MemoryManager<NodalTetElec>::AllocateSharedPtr(key));
             returnval->Initialize();
             return returnval;
         }

const MatrixSharedPtrType Nektar::LibUtilities::NodalTetElec::GetI ( const PointsKey & pkey )

inlinevirtual

Reimplemented from Nektar::LibUtilities::Points< NekDouble >.

Definition at line 62 of file NodalTetElec.h.

References ASSERTL0, Nektar::LibUtilities::PointsKey::GetPointsDim(), and Nektar::LibUtilities::PointsManager().

             {
                 ASSERTL0(pkey.GetPointsDim() == 3, 
                          "NodalTetElec Points can only interp to other 3d "
                          "point distributions");
                 Array<OneD, const NekDouble> x, y, z;
                 PointsManager()[pkey]->GetPoints(x, y, z);
                 return GetI(x, y, z);
             }

const MatrixSharedPtrType Nektar::LibUtilities::NodalTetElec::GetI	(	const Array< OneD, const NekDouble > &	x,
		const Array< OneD, const NekDouble > &	y,
		const Array< OneD, const NekDouble > &	z
	)

inlinevirtual

Reimplemented from Nektar::LibUtilities::Points< NekDouble >.

Definition at line 72 of file NodalTetElec.h.

References CalculateInterpMatrix(), and Nektar::LibUtilities::Points< NekDouble >::GetTotNumPoints().

            {
                 int          numpoints = x.num_elements();
                 unsigned int np        = GetTotNumPoints();
                 
                 Array<OneD, NekDouble> interp(np*numpoints);
                 CalculateInterpMatrix(x, y, z, interp);
                 
                 NekDouble* d = interp.data();
                 return MemoryManager<NekMatrix<NekDouble> >
                     ::AllocateSharedPtr(numpoints, np, d);
             }

void Nektar::LibUtilities::NodalTetElec::NodalPointReorder3d ( )

private

Definition at line 259 of file NodalTetElec.cpp.

Referenced by CalculatePoints().

260 {

261 }

Public Member Functions

Static Public Member Functions

Private Member Functions

Additional Inherited Members

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation