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vtkQuadraticPyramid Class Reference

cell represents a parabolic, 13-node isoparametric pyramid More...

#include <vtkQuadraticPyramid.h>

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List of all members.

Public Types

typedef vtkNonLinearCell Superclass

Public Member Functions

virtual int IsA (const char *type)
vtkQuadraticPyramidNewInstance () const
void PrintSelf (ostream &os, vtkIndent indent)
int CellBoundary (int subId, double pcoords[3], vtkIdList *pts)
void Contour (double value, vtkDataArray *cellScalars, vtkIncrementalPointLocator *locator, vtkCellArray *verts, vtkCellArray *lines, vtkCellArray *polys, vtkPointData *inPd, vtkPointData *outPd, vtkCellData *inCd, vtkIdType cellId, vtkCellData *outCd)
int EvaluatePosition (double x[3], double *closestPoint, int &subId, double pcoords[3], double &dist2, double *weights)
void EvaluateLocation (int &subId, double pcoords[3], double x[3], double *weights)
int Triangulate (int index, vtkIdList *ptIds, vtkPoints *pts)
void Derivatives (int subId, double pcoords[3], double *values, int dim, double *derivs)
virtual doubleGetParametricCoords ()
int GetParametricCenter (double pcoords[3])
void JacobianInverse (double pcoords[3], double **inverse, double derivs[39])
int GetCellType ()
int GetCellDimension ()
int GetNumberOfEdges ()
int GetNumberOfFaces ()
vtkCellGetEdge (int edgeId)
vtkCellGetFace (int faceId)
void Clip (double value, vtkDataArray *cellScalars, vtkIncrementalPointLocator *locator, vtkCellArray *tets, vtkPointData *inPd, vtkPointData *outPd, vtkCellData *inCd, vtkIdType cellId, vtkCellData *outCd, int insideOut)
int IntersectWithLine (double p1[3], double p2[3], double tol, double &t, double x[3], double pcoords[3], int &subId)
virtual void InterpolateFunctions (double pcoords[3], double weights[13])
virtual void InterpolateDerivs (double pcoords[3], double derivs[39])

Static Public Member Functions

static vtkQuadraticPyramidNew ()
static int IsTypeOf (const char *type)
static vtkQuadraticPyramidSafeDownCast (vtkObjectBase *o)
static void InterpolationFunctions (double pcoords[3], double weights[13])
static void InterpolationDerivs (double pcoords[3], double derivs[39])
static intGetEdgeArray (int edgeId)
static intGetFaceArray (int faceId)

Protected Member Functions

virtual vtkObjectBaseNewInstanceInternal () const
 vtkQuadraticPyramid ()
 ~vtkQuadraticPyramid ()
void Subdivide (vtkPointData *inPd, vtkCellData *inCd, vtkIdType cellId, vtkDataArray *cellScalars)

Protected Attributes

vtkQuadraticEdgeEdge
vtkQuadraticTriangleTriangleFace
vtkQuadraticQuadFace
vtkTetraTetra
vtkPyramidPyramid
vtkPointDataPointData
vtkCellDataCellData
vtkDoubleArrayCellScalars
vtkDoubleArrayScalars

Detailed Description

cell represents a parabolic, 13-node isoparametric pyramid

vtkQuadraticPyramid is a concrete implementation of vtkNonLinearCell to represent a three-dimensional, 13-node isoparametric parabolic pyramid. The interpolation is the standard finite element, quadratic isoparametric shape function. The cell includes a mid-edge node. The ordering of the thirteen points defining the cell is point ids (0-4,5-12) where point ids 0-4 are the five corner vertices of the pyramid; followed by eight midedge nodes (5-12). Note that these midedge nodes correspond lie on the edges defined by (0,1), (1,2), (2,3), (3,0), (0,4), (1,4), (2,4), (3,4).

See also:
vtkQuadraticEdge vtkQuadraticTriangle vtkQuadraticTetra vtkQuadraticHexahedron vtkQuadraticQuad vtkQuadraticWedge
Thanks:
The shape functions and derivatives could be implemented thanks to the report Pyramid Solid Elements Linear and Quadratic Iso-P Models From Center For Aerospace Structures
Tests:
vtkQuadraticPyramid (Tests)

Definition at line 54 of file vtkQuadraticPyramid.h.


Member Typedef Documentation

Reimplemented from vtkNonLinearCell.

Definition at line 58 of file vtkQuadraticPyramid.h.


Constructor & Destructor Documentation


Member Function Documentation

Create an object with Debug turned off, modified time initialized to zero, and reference counting on.

Reimplemented from vtkObject.

static int vtkQuadraticPyramid::IsTypeOf ( const char *  name) [static]

Return 1 if this class type is the same type of (or a subclass of) the named class. Returns 0 otherwise. This method works in combination with vtkTypeMacro found in vtkSetGet.h.

Reimplemented from vtkNonLinearCell.

virtual int vtkQuadraticPyramid::IsA ( const char *  name) [virtual]

Return 1 if this class is the same type of (or a subclass of) the named class. Returns 0 otherwise. This method works in combination with vtkTypeMacro found in vtkSetGet.h.

Reimplemented from vtkNonLinearCell.

Reimplemented from vtkNonLinearCell.

virtual vtkObjectBase* vtkQuadraticPyramid::NewInstanceInternal ( ) const [protected, virtual]

Reimplemented from vtkNonLinearCell.

Reimplemented from vtkNonLinearCell.

void vtkQuadraticPyramid::PrintSelf ( ostream &  os,
vtkIndent  indent 
) [virtual]

Methods invoked by print to print information about the object including superclasses. Typically not called by the user (use Print() instead) but used in the hierarchical print process to combine the output of several classes.

Reimplemented from vtkNonLinearCell.

int vtkQuadraticPyramid::GetCellType ( ) [inline, virtual]

Implement the vtkCell API. See the vtkCell API for descriptions of these methods.

Implements vtkCell.

Definition at line 64 of file vtkQuadraticPyramid.h.

Implement the vtkCell API. See the vtkCell API for descriptions of these methods.

Implements vtkCell.

Definition at line 65 of file vtkQuadraticPyramid.h.

Implement the vtkCell API. See the vtkCell API for descriptions of these methods.

Implements vtkCell.

Definition at line 66 of file vtkQuadraticPyramid.h.

Implement the vtkCell API. See the vtkCell API for descriptions of these methods.

Implements vtkCell.

Definition at line 67 of file vtkQuadraticPyramid.h.

vtkCell* vtkQuadraticPyramid::GetEdge ( int  edgeId) [virtual]

Implement the vtkCell API. See the vtkCell API for descriptions of these methods.

Implements vtkCell.

vtkCell* vtkQuadraticPyramid::GetFace ( int  faceId) [virtual]

Implement the vtkCell API. See the vtkCell API for descriptions of these methods.

Implements vtkCell.

int vtkQuadraticPyramid::CellBoundary ( int  subId,
double  pcoords[3],
vtkIdList pts 
) [virtual]

Given parametric coordinates of a point, return the closest cell boundary, and whether the point is inside or outside of the cell. The cell boundary is defined by a list of points (pts) that specify a face (3D cell), edge (2D cell), or vertex (1D cell). If the return value of the method is != 0, then the point is inside the cell.

Implements vtkCell.

void vtkQuadraticPyramid::Contour ( double  value,
vtkDataArray cellScalars,
vtkIncrementalPointLocator locator,
vtkCellArray verts,
vtkCellArray lines,
vtkCellArray polys,
vtkPointData inPd,
vtkPointData outPd,
vtkCellData inCd,
vtkIdType  cellId,
vtkCellData outCd 
) [virtual]

Generate contouring primitives. The scalar list cellScalars are scalar values at each cell point. The point locator is essentially a points list that merges points as they are inserted (i.e., prevents duplicates). Contouring primitives can be vertices, lines, or polygons. It is possible to interpolate point data along the edge by providing input and output point data - if outPd is NULL, then no interpolation is performed. Also, if the output cell data is non-NULL, the cell data from the contoured cell is passed to the generated contouring primitives. (Note: the CopyAllocate() method must be invoked on both the output cell and point data. The cellId refers to the cell from which the cell data is copied.)

Implements vtkCell.

int vtkQuadraticPyramid::EvaluatePosition ( double  x[3],
double closestPoint,
int subId,
double  pcoords[3],
double dist2,
double weights 
) [virtual]

Given a point x[3] return inside(=1), outside(=0) cell, or (-1) computational problem encountered; evaluate parametric coordinates, sub-cell id (!=0 only if cell is composite), distance squared of point x[3] to cell (in particular, the sub-cell indicated), closest point on cell to x[3] (unless closestPoint is null, in which case, the closest point and dist2 are not found), and interpolation weights in cell. (The number of weights is equal to the number of points defining the cell). Note: on rare occasions a -1 is returned from the method. This means that numerical error has occurred and all data returned from this method should be ignored. Also, inside/outside is determine parametrically. That is, a point is inside if it satisfies parametric limits. This can cause problems for cells of topological dimension 2 or less, since a point in 3D can project onto the cell within parametric limits but be "far" from the cell. Thus the value dist2 may be checked to determine true in/out.

Implements vtkCell.

void vtkQuadraticPyramid::EvaluateLocation ( int subId,
double  pcoords[3],
double  x[3],
double weights 
) [virtual]

Determine global coordinate (x[3]) from subId and parametric coordinates. Also returns interpolation weights. (The number of weights is equal to the number of points in the cell.)

Implements vtkCell.

int vtkQuadraticPyramid::Triangulate ( int  index,
vtkIdList ptIds,
vtkPoints pts 
) [virtual]

Generate simplices of proper dimension. If cell is 3D, tetrahedron are generated; if 2D triangles; if 1D lines; if 0D points. The form of the output is a sequence of points, each n+1 points (where n is topological cell dimension) defining a simplex. The index is a parameter that controls which triangulation to use (if more than one is possible). If numerical degeneracy encountered, 0 is returned, otherwise 1 is returned. This method does not insert new points: all the points that define the simplices are the points that define the cell.

Implements vtkCell.

void vtkQuadraticPyramid::Derivatives ( int  subId,
double  pcoords[3],
double values,
int  dim,
double derivs 
) [virtual]

Compute derivatives given cell subId and parametric coordinates. The values array is a series of data value(s) at the cell points. There is a one-to-one correspondence between cell point and data value(s). Dim is the number of data values per cell point. Derivs are derivatives in the x-y-z coordinate directions for each data value. Thus, if computing derivatives for a scalar function in a hexahedron, dim=1, 8 values are supplied, and 3 deriv values are returned (i.e., derivatives in x-y-z directions). On the other hand, if computing derivatives of velocity (vx,vy,vz) dim=3, 24 values are supplied ((vx,vy,vz)1, (vx,vy,vz)2, ....()8), and 9 deriv values are returned ((d(vx)/dx),(d(vx)/dy),(d(vx)/dz), (d(vy)/dx),(d(vy)/dy), (d(vy)/dz), (d(vz)/dx),(d(vz)/dy),(d(vz)/dz)).

Implements vtkCell.

Return a contiguous array of parametric coordinates of the points defining this cell. In other words, (px,py,pz, px,py,pz, etc..) The coordinates are ordered consistent with the definition of the point ordering for the cell. This method returns a non-NULL pointer when the cell is a primary type (i.e., IsPrimaryCell() is true). Note that 3D parametric coordinates are returned no matter what the topological dimension of the cell.

Reimplemented from vtkCell.

void vtkQuadraticPyramid::Clip ( double  value,
vtkDataArray cellScalars,
vtkIncrementalPointLocator locator,
vtkCellArray tets,
vtkPointData inPd,
vtkPointData outPd,
vtkCellData inCd,
vtkIdType  cellId,
vtkCellData outCd,
int  insideOut 
) [virtual]

Clip this quadratic triangle using scalar value provided. Like contouring, except that it cuts the triangle to produce linear triangles.

Implements vtkCell.

int vtkQuadraticPyramid::IntersectWithLine ( double  p1[3],
double  p2[3],
double  tol,
double t,
double  x[3],
double  pcoords[3],
int subId 
) [virtual]

Line-edge intersection. Intersection has to occur within [0,1] parametric coordinates and with specified tolerance.

Implements vtkCell.

int vtkQuadraticPyramid::GetParametricCenter ( double  pcoords[3]) [inline, virtual]

Return the center of the quadratic pyramid in parametric coordinates.

Reimplemented from vtkCell.

Definition at line 164 of file vtkQuadraticPyramid.h.

static void vtkQuadraticPyramid::InterpolationFunctions ( double  pcoords[3],
double  weights[13] 
) [static]
static void vtkQuadraticPyramid::InterpolationDerivs ( double  pcoords[3],
double  derivs[39] 
) [static]
virtual void vtkQuadraticPyramid::InterpolateFunctions ( double  pcoords[3],
double  weights[13] 
) [inline, virtual]

Compute the interpolation functions/derivatives (aka shape functions/derivatives)

Definition at line 119 of file vtkQuadraticPyramid.h.

virtual void vtkQuadraticPyramid::InterpolateDerivs ( double  pcoords[3],
double  derivs[39] 
) [inline, virtual]

Compute the interpolation functions/derivatives (aka shape functions/derivatives)

Definition at line 123 of file vtkQuadraticPyramid.h.

static int* vtkQuadraticPyramid::GetEdgeArray ( int  edgeId) [static]

Return the ids of the vertices defining edge/face (edgeId/`faceId'). Ids are related to the cell, not to the dataset.

static int* vtkQuadraticPyramid::GetFaceArray ( int  faceId) [static]

Return the ids of the vertices defining edge/face (edgeId/`faceId'). Ids are related to the cell, not to the dataset.

void vtkQuadraticPyramid::JacobianInverse ( double  pcoords[3],
double **  inverse,
double  derivs[39] 
)

Given parametric coordinates compute inverse Jacobian transformation matrix. Returns 9 elements of 3x3 inverse Jacobian plus interpolation function derivatives.

void vtkQuadraticPyramid::Subdivide ( vtkPointData inPd,
vtkCellData inCd,
vtkIdType  cellId,
vtkDataArray cellScalars 
) [protected]

Member Data Documentation

Definition at line 144 of file vtkQuadraticPyramid.h.

Definition at line 145 of file vtkQuadraticPyramid.h.

Definition at line 146 of file vtkQuadraticPyramid.h.

Definition at line 147 of file vtkQuadraticPyramid.h.

Definition at line 148 of file vtkQuadraticPyramid.h.

Definition at line 149 of file vtkQuadraticPyramid.h.

Definition at line 150 of file vtkQuadraticPyramid.h.

Definition at line 151 of file vtkQuadraticPyramid.h.

Definition at line 152 of file vtkQuadraticPyramid.h.


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