SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM > Class Template Reference
#include <SimpleNonlinearEllipticAssembler.hpp>
Public Types | |
| typedef SimpleNonlinearEllipticAssembler < ELEMENT_DIM, SPACE_DIM > | SelfType |
| typedef AbstractNonlinearAssembler < ELEMENT_DIM, SPACE_DIM, 1, SelfType > | BaseClassType |
Public Member Functions | |
| SimpleNonlinearEllipticAssembler (AbstractTetrahedralMesh< ELEMENT_DIM, SPACE_DIM > *pMesh, AbstractNonlinearEllipticPde< SPACE_DIM > *pPde, BoundaryConditionsContainer< ELEMENT_DIM, SPACE_DIM, 1 > *pBoundaryConditions, unsigned numQuadPoints=2) | |
Static Public Attributes | |
| static const unsigned | E_DIM = ELEMENT_DIM |
| static const unsigned | S_DIM = SPACE_DIM |
| static const unsigned | P_DIM = 1u |
Private Member Functions | |
| virtual c_matrix< double, 1 *(ELEMENT_DIM+1), 1 *(ELEMENT_DIM+1)> | ComputeMatrixTerm (c_vector< double, ELEMENT_DIM+1 > &rPhi, c_matrix< double, ELEMENT_DIM, ELEMENT_DIM+1 > &rGradPhi, ChastePoint< SPACE_DIM > &rX, c_vector< double, 1 > &rU, c_matrix< double, 1, SPACE_DIM > &rGradU, Element< ELEMENT_DIM, SPACE_DIM > *pElement) |
| virtual c_vector< double, 1 *(ELEMENT_DIM+1)> | ComputeVectorTerm (c_vector< double, ELEMENT_DIM+1 > &rPhi, c_matrix< double, ELEMENT_DIM, ELEMENT_DIM+1 > &rGradPhi, ChastePoint< SPACE_DIM > &rX, c_vector< double, 1 > &rU, c_matrix< double, 1, SPACE_DIM > &rGradU, Element< ELEMENT_DIM, SPACE_DIM > *pElement) |
| virtual c_vector< double, 1 *ELEMENT_DIM > | ComputeVectorSurfaceTerm (const BoundaryElement< ELEMENT_DIM-1, SPACE_DIM > &rSurfaceElement, c_vector< double, ELEMENT_DIM > &rPhi, ChastePoint< SPACE_DIM > &rX) |
Private Attributes | |
| AbstractNonlinearEllipticPde < SPACE_DIM > * | mpNonlinearEllipticPde |
Friends | |
| class | AbstractStaticAssembler< ELEMENT_DIM, SPACE_DIM, 1, true, SelfType > |
| class | TestSimpleNonlinearEllipticAssembler |
Detailed Description
template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
class SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >
Concrete simple class that assembles and solves the nonlinear system for a nonlinear elliptic PDE.USAGE: call the constructor with the mesh, pde and boundary conditions, then call Solve() with the initial guess.
- Todo:
- [old todo, maybe not true anymore after refactor(?)] This class could do with some tidying. More (3D) tests are also needed. It probably needs re-writing to take advantage of parallel machines.
Definition at line 49 of file SimpleNonlinearEllipticAssembler.hpp.
Member Typedef Documentation
| typedef SimpleNonlinearEllipticAssembler<ELEMENT_DIM, SPACE_DIM> SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::SelfType |
This type (to save typing).
Definition at line 57 of file SimpleNonlinearEllipticAssembler.hpp.
| typedef AbstractNonlinearAssembler<ELEMENT_DIM, SPACE_DIM, 1, SelfType> SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::BaseClassType |
Base class type (to save typing).
Reimplemented from AbstractNonlinearAssembler< ELEMENT_DIM, SPACE_DIM, 1, SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM > >.
Definition at line 58 of file SimpleNonlinearEllipticAssembler.hpp.
Constructor & Destructor Documentation
| SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::SimpleNonlinearEllipticAssembler | ( | AbstractTetrahedralMesh< ELEMENT_DIM, SPACE_DIM > * | pMesh, | |
| AbstractNonlinearEllipticPde< SPACE_DIM > * | pPde, | |||
| BoundaryConditionsContainer< ELEMENT_DIM, SPACE_DIM, 1 > * | pBoundaryConditions, | |||
| unsigned | numQuadPoints = 2 | |||
| ) | [inline] |
Constructor - takes in the mesh, pde and boundary conditions container to be solved. Can also define the number of quad points (in each dimension), the default value of which is 2.
- Parameters:
-
pMesh pointer to the mesh pPde pointer to the PDE pBoundaryConditions pointer to the boundary conditions numQuadPoints number of quadrature points (defaults to 2)
Definition at line 34 of file SimpleNonlinearEllipticAssembler.cpp.
References SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::mpNonlinearEllipticPde, AbstractAssembler< ELEMENT_DIM, SPACE_DIM, PROBLEM_DIM >::SetBoundaryConditionsContainer(), and AbstractStaticAssembler< ELEMENT_DIM, SPACE_DIM, PROBLEM_DIM, true, SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM > >::SetMesh().
Member Function Documentation
| c_matrix< double, 1 *(ELEMENT_DIM+1), 1 *(ELEMENT_DIM+1)> SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::ComputeMatrixTerm | ( | c_vector< double, ELEMENT_DIM+1 > & | rPhi, | |
| c_matrix< double, ELEMENT_DIM, ELEMENT_DIM+1 > & | rGradPhi, | |||
| ChastePoint< SPACE_DIM > & | rX, | |||
| c_vector< double, 1 > & | rU, | |||
| c_matrix< double, 1, SPACE_DIM > & | rGradU, | |||
| Element< ELEMENT_DIM, SPACE_DIM > * | pElement | |||
| ) | [inline, private, virtual] |
This method returns the matrix to be added to element stiffness matrix for a given gauss point. The arguments are the bases, bases gradients, x and current solution computed at the Gauss point. The returned matrix will be multiplied by the gauss weight and jacobian determinent and added to the element stiffness matrix (see AssembleOnElement()).
- Parameters:
-
rPhi The basis functions, rPhi(i) = phi_i, i=1..numBases rGradPhi Basis gradients, rGradPhi(i,j) = d(phi_j)/d(X_i) rX The point in space rU The unknown as a vector, u(i) = u_i
- Todo:
- should this be rU?
- Parameters:
-
rGradU The gradient of the unknown as a matrix, rGradU(i,j) = d(u_i)/d(X_j) pElement Pointer to the element
Definition at line 54 of file SimpleNonlinearEllipticAssembler.cpp.
References SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::mpNonlinearEllipticPde.
| c_vector< double, 1 *(ELEMENT_DIM+1)> SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::ComputeVectorTerm | ( | c_vector< double, ELEMENT_DIM+1 > & | rPhi, | |
| c_matrix< double, ELEMENT_DIM, ELEMENT_DIM+1 > & | rGradPhi, | |||
| ChastePoint< SPACE_DIM > & | rX, | |||
| c_vector< double, 1 > & | rU, | |||
| c_matrix< double, 1, SPACE_DIM > & | rGradU, | |||
| Element< ELEMENT_DIM, SPACE_DIM > * | pElement | |||
| ) | [inline, private, virtual] |
This method returns the vector to be added to element stiffness vector for a given gauss point. The arguments are the bases, x and current solution computed at the Gauss point. The returned vector will be multiplied by the gauss weight and jacobian determinent and added to the element stiffness matrix (see AssembleOnElement()).
- Parameters:
-
rPhi The basis functions, rPhi(i) = phi_i, i=1..numBases rGradPhi Basis gradients, rGradPhi(i,j) = d(phi_j)/d(X_i) rX The point in space rU The unknown as a vector, u(i) = u_i rGradU The gradient of the unknown as a matrix, rGradU(i,j) = d(u_i)/d(X_j) pElement Pointer to the element
Definition at line 88 of file SimpleNonlinearEllipticAssembler.cpp.
References SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::mpNonlinearEllipticPde.
| c_vector< double, 1 *ELEMENT_DIM > SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::ComputeVectorSurfaceTerm | ( | const BoundaryElement< ELEMENT_DIM-1, SPACE_DIM > & | rSurfaceElement, | |
| c_vector< double, ELEMENT_DIM > & | rPhi, | |||
| ChastePoint< SPACE_DIM > & | rX | |||
| ) | [inline, private, virtual] |
This method returns the vector to be added to element stiffness vector for a given gauss point in BoundaryElement. The arguments are the bases, x and current solution computed at the Gauss point. The returned vector will be multiplied by the gauss weight and jacobian determinent and added to the element stiffness matrix (see AssembleOnElement()).
- Parameters:
-
rSurfaceElement the element which is being considered. rPhi The basis functions, rPhi(i) = phi_i, i=1..numBases rX The point in space
Implements AbstractAssembler< ELEMENT_DIM, SPACE_DIM, PROBLEM_DIM >.
Definition at line 122 of file SimpleNonlinearEllipticAssembler.cpp.
References BoundaryConditionsContainer< ELEM_DIM, SPACE_DIM, PROBLEM_DIM >::GetNeumannBCValue(), and AbstractAssembler< ELEMENT_DIM, SPACE_DIM, PROBLEM_DIM >::mpBoundaryConditions.
Member Data Documentation
const unsigned SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::E_DIM = ELEMENT_DIM [static] |
The element dimension (to save typing).
Definition at line 53 of file SimpleNonlinearEllipticAssembler.hpp.
const unsigned SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::S_DIM = SPACE_DIM [static] |
The space dimension (to save typing).
Definition at line 54 of file SimpleNonlinearEllipticAssembler.hpp.
const unsigned SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::P_DIM = 1u [static] |
The problem dimension (to save typing).
Definition at line 55 of file SimpleNonlinearEllipticAssembler.hpp.
AbstractNonlinearEllipticPde<SPACE_DIM>* SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::mpNonlinearEllipticPde [private] |
The PDE to be solved.
Definition at line 67 of file SimpleNonlinearEllipticAssembler.hpp.
Referenced by SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::ComputeMatrixTerm(), SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::ComputeVectorTerm(), and SimpleNonlinearEllipticAssembler< ELEMENT_DIM, SPACE_DIM >::SimpleNonlinearEllipticAssembler().
The documentation for this class was generated from the following files:
- /tmp/release_1.1/pde/src/solver/common/SimpleNonlinearEllipticAssembler.hpp
- /tmp/release_1.1/pde/src/solver/common/SimpleNonlinearEllipticAssembler.cpp
