KratosMultiphysics
KRATOS Multiphysics (Kratos) is a framework for building parallel, multi-disciplinary simulation software, aiming at modularity, extensibility, and high performance. Kratos is written in C++, and counts with an extensive Python interface.
calculate_velocity_laplacian.h
Go to the documentation of this file.
1 //
2 // Project Name: Kratos
3 // Last Modified by: $Author: gcasas $
4 // Date: $Date: 2016-03-12
5 //
6 
7 #if !defined(KRATOS_COMPUTE_VELOCITY_LAPLACIAN_SIMPLEX_ELEMENT_H_INCLUDED )
8 #define KRATOS_COMPUTE_VELOCITY_LAPLACIAN_SIMPLEX_ELEMENT_H_INCLUDED
9 
10 // System includes
11 #include <string>
12 #include <iostream>
13 
14 
15 // External includes
16 
17 
18 // Project includes
19 #include "containers/array_1d.h"
20 #include "includes/define.h"
21 #include "includes/element.h"
22 #include "includes/serializer.h"
23 #include "geometries/geometry.h"
24 #include "utilities/math_utils.h"
25 #include "utilities/geometry_utilities.h"
26 
27 // Application includes
28 #include "includes/variables.h"
30 
31 namespace Kratos
32 {
33 
36 
39 
43 
47 
51 
55 
57 
59 template< unsigned int TDim,
60  unsigned int TNumNodes = TDim + 1 >
61 class KRATOS_API(SWIMMING_DEM_APPLICATION) ComputeVelocityLaplacianSimplex : public ComputeMaterialDerivativeSimplex<TDim, TNumNodes>
62 {
63 public:
66 
69 
71 
73  typedef Node NodeType;
74 
77 
80 
82  typedef Vector VectorType;
83 
85  typedef Matrix MatrixType;
86 
88 
89  typedef std::size_t IndexType;
90 
91  typedef std::size_t SizeType;
92 
93  typedef std::vector<std::size_t> EquationIdVectorType;
94 
95  typedef std::vector< Dof<double>::Pointer > DofsVectorType;
96 
98 
101 
104 
107 
111 
112  //Constructors.
113 
115 
119  BaseType(NewId)
120  {}
121 
123 
128  BaseType(NewId, ThisNodes)
129  {}
130 
132 
136  ComputeVelocityLaplacianSimplex(IndexType NewId, GeometryType::Pointer pGeometry) :
137  BaseType(NewId, pGeometry)
138  {}
139 
141 
146  ComputeVelocityLaplacianSimplex(IndexType NewId, GeometryType::Pointer pGeometry, PropertiesType::Pointer pProperties) :
147  BaseType(NewId, pGeometry, pProperties)
148  {}
149 
152  {}
153 
154 
158 
159 
163 
165 
172  Element::Pointer Create(IndexType NewId, NodesArrayType const& ThisNodes,
173  PropertiesType::Pointer pProperties) const override
174  {
175  return Element::Pointer(new ComputeVelocityLaplacianSimplex(NewId, this->GetGeometry().Create(ThisNodes), pProperties));
176  }
177 
179 
185  void EquationIdVector(EquationIdVectorType& rResult, const ProcessInfo& rCurrentProcessInfo) const override;
186 
188 
192  void GetDofList(DofsVectorType& rElementalDofList, const ProcessInfo& rCurrentProcessInfo) const override;
193 
197 
201 
203 
211  int Check(const ProcessInfo& rCurrentProcessInfo) const override;
212 
216 
217 
221 
223  virtual std::string Info() const override
224  {
225  std::stringstream buffer;
226  buffer << "ComputeVelocityLaplacianSimplex #" << this->Id();
227  return buffer.str();
228  }
229 
231  virtual void PrintInfo(std::ostream& rOStream) const override
232  {
233  rOStream << "ComputeVelocityLaplacianSimplex" << TDim << "D";
234  }
235 
236 // /// Print object's data.
237 // virtual void PrintData(std::ostream& rOStream) const;
238 
242 
243 
245 
246 protected:
249 
250 
254 
255 
259 
260 
264 
265 
269 
270  void AddIntegrationPointRHSContribution(VectorType& F, const array_1d<double,TNumNodes>& rShapeFunc, const BoundedMatrix<double, TNumNodes, TDim>& rShapeDeriv, const double Weight) override;
271 
275 
276 
280 
281 
283 
284 private:
287 
291 
295 
296  friend class Serializer;
297 
301 
303 
313 
314 
318 
319 
323 
324 
328 
331 
334 
336 
337 }; // Class ComputeVelocityLaplacianSimplex
338 
340 
343 
344 
348 
349 
351 template< unsigned int TDim >
352 inline std::istream& operator >>(std::istream& rIStream,
354 {
355  return rIStream;
356 }
357 
359 template< unsigned int TDim >
360 inline std::ostream& operator <<(std::ostream& rOStream,
362 {
363  rThis.PrintInfo(rOStream);
364  rOStream << std::endl;
365  rThis.PrintData(rOStream);
366 
367  return rOStream;
368 }
370 
372 
373 } // namespace Kratos.
374 
375 #endif // KRATOS_COMPUTE_VELOCITY_LAPLACIAN_SIMPLEX_ELEMENT_H_INCLUDED defined
PeriodicInterfaceProcess & operator=(const PeriodicInterfaceProcess &)=delete
A post-processing element to recover the Laplacian from the velocity solution.
Definition: calculate_mat_deriv_simplex_element.h:62
A post-processing element to recover the Laplacian from the velocity solution.
Definition: calculate_velocity_laplacian.h:62
Geometry< NodeType > GeometryType
Geometry type (using with given NodeType)
Definition: calculate_velocity_laplacian.h:76
GeometryType::ShapeFunctionsGradientsType ShapeFunctionDerivativesArrayType
Type for an array of shape function gradient matrices.
Definition: calculate_velocity_laplacian.h:106
ComputeVelocityLaplacianSimplex(IndexType NewId, GeometryType::Pointer pGeometry)
Constructor using a geometry object.
Definition: calculate_velocity_laplacian.h:136
Kratos::Vector ShapeFunctionsType
Type for shape function values container.
Definition: calculate_velocity_laplacian.h:100
Properties PropertiesType
Definition: calculate_velocity_laplacian.h:87
std::vector< Dof< double >::Pointer > DofsVectorType
Definition: calculate_velocity_laplacian.h:95
KRATOS_CLASS_INTRUSIVE_POINTER_DEFINITION(ComputeVelocityLaplacianSimplex)
Pointer definition of ComputeVelocityLaplacianSimplex.
Kratos::Matrix ShapeFunctionDerivativesType
Type for a matrix containing the shape function gradients.
Definition: calculate_velocity_laplacian.h:103
std::vector< std::size_t > EquationIdVectorType
Definition: calculate_velocity_laplacian.h:93
PointerVectorSet< Dof< double >, IndexedObject > DofsArrayType
Definition: calculate_velocity_laplacian.h:97
virtual ~ComputeVelocityLaplacianSimplex()
Destructor.
Definition: calculate_velocity_laplacian.h:151
Element::Pointer Create(IndexType NewId, NodesArrayType const &ThisNodes, PropertiesType::Pointer pProperties) const override
Create a new element of this type.
Definition: calculate_velocity_laplacian.h:172
Node NodeType
Node type (default is: Node)
Definition: calculate_velocity_laplacian.h:73
std::size_t SizeType
Definition: calculate_velocity_laplacian.h:91
Vector VectorType
Vector type for local contributions to the linear system.
Definition: calculate_velocity_laplacian.h:82
ComputeMaterialDerivativeSimplex< TDim, TNumNodes > BaseType
Definition: calculate_velocity_laplacian.h:70
std::size_t IndexType
Definition: calculate_velocity_laplacian.h:89
Geometry< NodeType >::PointsArrayType NodesArrayType
Definition of nodes container type, redefined from GeometryType.
Definition: calculate_velocity_laplacian.h:79
Matrix MatrixType
Matrix type for local contributions to the linear system.
Definition: calculate_velocity_laplacian.h:85
ComputeVelocityLaplacianSimplex(IndexType NewId, const NodesArrayType &ThisNodes)
Constructor using an array of nodes.
Definition: calculate_velocity_laplacian.h:127
ComputeVelocityLaplacianSimplex(IndexType NewId, GeometryType::Pointer pGeometry, PropertiesType::Pointer pProperties)
Constuctor using geometry and properties.
Definition: calculate_velocity_laplacian.h:146
virtual void PrintInfo(std::ostream &rOStream) const override
Print information about this object.
Definition: calculate_velocity_laplacian.h:231
ComputeVelocityLaplacianSimplex(IndexType NewId=0)
Default constuctor.
Definition: calculate_velocity_laplacian.h:118
virtual std::string Info() const override
Turn back information as a string.
Definition: calculate_velocity_laplacian.h:223
void PrintData(std::ostream &rOStream) const override
Print object's data.
Definition: element.h:1135
std::size_t IndexType
Definition: flags.h:74
This defines the geometrical object, base definition of the element and condition entities.
Definition: geometrical_object.h:58
Geometry base class.
Definition: geometry.h:71
This object defines an indexed object.
Definition: indexed_object.h:54
This class defines the node.
Definition: node.h:65
PointerVector is a container like stl vector but using a vector to store pointers to its data.
Definition: pointer_vector.h:72
A sorted associative container similar to an STL set, but uses a vector to store pointers to its data...
Definition: pointer_vector_set.h:72
ProcessInfo holds the current value of different solution parameters.
Definition: process_info.h:59
Properties encapsulates data shared by different Elements or Conditions. It can store any type of dat...
Definition: properties.h:69
The serialization consists in storing the state of an object into a storage format like data file or ...
Definition: serializer.h:123
Modeler::Pointer Create(const std::string &ModelerName, Model &rModel, const Parameters ModelParameters)
Checks if the modeler is registered.
Definition: modeler_factory.cpp:30
REF: G. R. Cowper, GAUSSIAN QUADRATURE FORMULAS FOR TRIANGLES.
Definition: mesh_condition.cpp:21
std::istream & operator>>(std::istream &rIStream, LinearMasterSlaveConstraint &rThis)
input stream function
std::ostream & operator<<(std::ostream &rOStream, const LinearMasterSlaveConstraint &rThis)
output stream function
Definition: linear_master_slave_constraint.h:432
F
Definition: hinsberg_optimization.py:144