Chaste Release::3.1
StokesFlowAssembler.hpp
00001 /*
00002 
00003 Copyright (c) 2005-2012, University of Oxford.
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00006 University of Oxford means the Chancellor, Masters and Scholars of the
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00008 Square, Oxford OX1 2JD, UK.
00009 
00010 This file is part of Chaste.
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00034 */
00035 
00036 #ifndef STOKESFLOWASSEMBLER_HPP_
00037 #define STOKESFLOWASSEMBLER_HPP_
00038 
00039 #include "AbstractContinuumMechanicsAssembler.hpp"
00040 #include "StokesFlowProblemDefinition.hpp"
00041 
00042 
00061 template<unsigned DIM>
00062 class StokesFlowAssembler : public AbstractContinuumMechanicsAssembler<DIM,true,true>
00063 {
00064 friend class TestStokesFlowAssembler;
00065 
00066 private:
00068     static const unsigned NUM_VERTICES_PER_ELEMENT = DIM+1;
00069 
00071     static const unsigned NUM_NODES_PER_ELEMENT = (DIM+1)*(DIM+2)/2; // assuming quadratic
00072 
00077     static const unsigned SPATIAL_BLOCK_SIZE_ELEMENTAL = DIM*NUM_NODES_PER_ELEMENT;
00078 
00083     static const unsigned PRESSURE_BLOCK_SIZE_ELEMENTAL = NUM_VERTICES_PER_ELEMENT;
00084 
00086     StokesFlowProblemDefinition<DIM>* mpProblemDefinition;
00087 
00095     double mScaleFactor;
00096 
00097 
00112     c_matrix<double,SPATIAL_BLOCK_SIZE_ELEMENTAL,SPATIAL_BLOCK_SIZE_ELEMENTAL> ComputeSpatialSpatialMatrixTerm(
00113         c_vector<double, NUM_NODES_PER_ELEMENT>& rQuadPhi,
00114         c_matrix<double, DIM, NUM_NODES_PER_ELEMENT>& rGradQuadPhi,
00115         c_vector<double,DIM>& rX,
00116         Element<DIM,DIM>* pElement)
00117     {
00118         c_matrix<double,SPATIAL_BLOCK_SIZE_ELEMENTAL,SPATIAL_BLOCK_SIZE_ELEMENTAL> ret = zero_matrix<double>(SPATIAL_BLOCK_SIZE_ELEMENTAL,SPATIAL_BLOCK_SIZE_ELEMENTAL);
00119 
00120         double mu = mpProblemDefinition->GetViscosity();
00121 
00122         for (unsigned index1=0; index1<NUM_NODES_PER_ELEMENT*DIM; index1++)
00123         {
00124             unsigned spatial_dim1 = index1%DIM;
00125             unsigned node_index1 = (index1-spatial_dim1)/DIM;
00126 
00127             for (unsigned index2=0; index2<NUM_NODES_PER_ELEMENT*DIM; index2++)
00128             {
00129                 unsigned spatial_dim2 = index2%DIM;
00130                 unsigned node_index2 = (index2-spatial_dim2)/DIM;
00131 
00132                 ret(index1,index2) +=   mu
00133                                       * mScaleFactor // virtually always 1, see doxygen for this variable
00134                                       * rGradQuadPhi(spatial_dim1, node_index2)
00135                                       * rGradQuadPhi(spatial_dim2, node_index1);
00136 
00137                 for(unsigned k=0; k<DIM; k++)
00138                 {
00139                     ret(index1,index2) +=   mu
00140                                           * (spatial_dim1==spatial_dim2)
00141                                           * rGradQuadPhi(k, node_index1)
00142                                           * rGradQuadPhi(k, node_index2);
00143                 }
00144             }
00145         }
00146         return ret;
00147 
00148     }
00149 
00166     c_matrix<double,SPATIAL_BLOCK_SIZE_ELEMENTAL,PRESSURE_BLOCK_SIZE_ELEMENTAL> ComputeSpatialPressureMatrixTerm(
00167         c_vector<double, NUM_NODES_PER_ELEMENT>& rQuadPhi,
00168         c_matrix<double, DIM, NUM_NODES_PER_ELEMENT>& rGradQuadPhi,
00169         c_vector<double, NUM_VERTICES_PER_ELEMENT>& rLinearPhi,
00170         c_matrix<double, DIM, NUM_VERTICES_PER_ELEMENT>& rGradLinearPhi,
00171         c_vector<double,DIM>& rX,
00172         Element<DIM,DIM>* pElement)
00173     {
00174         c_matrix<double,SPATIAL_BLOCK_SIZE_ELEMENTAL,PRESSURE_BLOCK_SIZE_ELEMENTAL> ret = zero_matrix<double>(SPATIAL_BLOCK_SIZE_ELEMENTAL,PRESSURE_BLOCK_SIZE_ELEMENTAL);
00175 
00176         for (unsigned index1=0; index1<NUM_NODES_PER_ELEMENT*DIM; index1++)
00177         {
00178             unsigned spatial_dim1 = index1%DIM;
00179             unsigned node_index1 = (index1-spatial_dim1)/DIM;
00180 
00181             for (unsigned index2=0; index2<NUM_VERTICES_PER_ELEMENT; index2++)
00182             {
00183                 ret(index1,index2) += -rGradQuadPhi(spatial_dim1, node_index1) * rLinearPhi(index2);
00184             }
00185         }
00186 
00187         return ret;
00188     }
00189 
00190     // We don't implement this method - so it is a zero block
00191     //c_matrix<double,PRESSURE_BLOCK_SIZE_ELEMENTAL,PRESSURE_BLOCK_SIZE_ELEMENTAL> ComputePressurePressureMatrixTerm(
00192     //    c_vector<double, NUM_VERTICES_PER_ELEMENT>& rLinearPhi,
00193     //    c_matrix<double, DIM, NUM_VERTICES_PER_ELEMENT>& rGradLinearPhi,
00194     //    c_vector<double,DIM>& rX,
00195     //    Element<DIM,DIM>* pElement)
00196 
00197 
00214     c_vector<double,SPATIAL_BLOCK_SIZE_ELEMENTAL> ComputeSpatialVectorTerm(
00215         c_vector<double, NUM_NODES_PER_ELEMENT>& rQuadPhi,
00216         c_matrix<double, DIM, NUM_NODES_PER_ELEMENT>& rGradQuadPhi,
00217         c_vector<double,DIM>& rX,
00218         Element<DIM,DIM>* pElement)
00219     {
00220         c_vector<double,SPATIAL_BLOCK_SIZE_ELEMENTAL> ret = zero_vector<double>(SPATIAL_BLOCK_SIZE_ELEMENTAL);
00221 
00222         c_vector<double,DIM> body_force = mpProblemDefinition->GetBodyForce(rX, 0.0);
00223 
00224         for (unsigned index=0; index<NUM_NODES_PER_ELEMENT*DIM; index++)
00225         {
00226             unsigned spatial_dim = index%DIM;
00227             unsigned node_index = (index-spatial_dim)/DIM;
00228 
00229             ret(index) += body_force(spatial_dim) * rQuadPhi(node_index);
00230         }
00231 
00232         return ret;
00233     }
00234 
00235     // We don't implement this method - so it is a zero block of the vector:
00236     //c_vector<double,PRESSURE_BLOCK_SIZE_ELEMENTAL> ComputePressureVectorTerm(
00237     //        c_vector<double, NUM_VERTICES_PER_ELEMENT>& rLinearPhi,
00238     //        c_matrix<double, DIM, NUM_VERTICES_PER_ELEMENT>& rGradLinearPhi,
00239     //        c_vector<double,DIM>& rX,
00240     //        Element<DIM,DIM>* pElement)
00241 
00242 public:
00248     StokesFlowAssembler(QuadraticMesh<DIM>* pMesh,
00249                         StokesFlowProblemDefinition<DIM>* pProblemDefinition)
00250         : AbstractContinuumMechanicsAssembler<DIM,true,true>(pMesh),
00251           mpProblemDefinition(pProblemDefinition),
00252           mScaleFactor(1.0)
00253     {
00254     }
00255 };
00256 
00257 #endif // STOKESFLOWASSEMBLER_HPP_