OrthotropicConductivityTensors.cpp
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00029 #include "OrthotropicConductivityTensors.hpp"
00030 #include "Exception.hpp"
00031
00032 template<unsigned SPACE_DIM>
00033 void OrthotropicConductivityTensors<SPACE_DIM>::ReadOrientationMatrixFromFile (c_matrix<double,SPACE_DIM,SPACE_DIM>& orientMatrix)
00034 {
00035 std::vector<double> items;
00036 unsigned num_elems = this->GetTokensAtNextLine(items);
00037
00038 if (num_elems != SPACE_DIM*SPACE_DIM)
00039 {
00040 this->CloseFibreOrientationFile();
00041 EXCEPTION("Orthotropic media defined. Number of vectors in fibre orientation file and size of them should match SPACE_DIM");
00042 }
00043
00044 for (unsigned vector_index=0; vector_index<SPACE_DIM; vector_index++)
00045 {
00046 for (unsigned component_index=0; component_index<SPACE_DIM; component_index++)
00047 {
00048 orientMatrix(component_index, vector_index) = items[vector_index*SPACE_DIM + component_index];
00049 }
00050 }
00051 }
00052
00053 template<unsigned SPACE_DIM>
00054 void OrthotropicConductivityTensors<SPACE_DIM>::Init() throw (Exception)
00055 {
00056 if (!this->mUseNonConstantConductivities && !this->mUseFibreOrientation)
00057 {
00058
00059 c_matrix<double, SPACE_DIM, SPACE_DIM> conductivity_matrix(zero_matrix<double>(SPACE_DIM,SPACE_DIM));
00060
00061 for (unsigned dim=0; dim<SPACE_DIM; dim++)
00062 {
00063 assert(this->mConstantConductivities(dim) != DBL_MAX);
00064 conductivity_matrix(dim,dim) = this->mConstantConductivities(dim);
00065 }
00066
00067 this->mTensors.push_back(conductivity_matrix);
00068 }
00069 else
00070 {
00071 c_matrix<double,SPACE_DIM,SPACE_DIM> orientation_matrix((identity_matrix<double>(SPACE_DIM)));
00072
00073 if (this->mUseFibreOrientation)
00074 {
00075 this->OpenFibreOrientationFile();
00076 this->mNumElements = this->GetNumElementsFromFile();
00077 }
00078 else
00079 {
00080 this->mNumElements = this->mpNonConstantConductivities->size();
00081 }
00082
00083
00084
00085 this->mTensors.reserve(this->mNumElements);
00086
00087 c_matrix<double, SPACE_DIM, SPACE_DIM> conductivity_matrix(zero_matrix<double>(SPACE_DIM,SPACE_DIM));
00088
00089 for (unsigned element_index=0; element_index<this->mNumElements; element_index++)
00090 {
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00109 if (this->mUseNonConstantConductivities)
00110 {
00111 for (unsigned dim=0; dim<SPACE_DIM; dim++)
00112 {
00113 conductivity_matrix(dim,dim) = (*this->mpNonConstantConductivities)[element_index][dim];
00114 }
00115 }
00116 else
00117 {
00118 for (unsigned dim=0; dim<SPACE_DIM; dim++)
00119 {
00120 assert(this->mConstantConductivities(dim) != DBL_MAX);
00121 conductivity_matrix(dim,dim) = this->mConstantConductivities(dim);
00122 }
00123 }
00124
00125 if (this->mUseFibreOrientation)
00126 {
00127 ReadOrientationMatrixFromFile(orientation_matrix);
00128 }
00129
00130 c_matrix<double,SPACE_DIM,SPACE_DIM> temp;
00131 noalias(temp) = prod(orientation_matrix, conductivity_matrix);
00132 this->mTensors.push_back( prod(temp, trans(orientation_matrix) ) );
00133 }
00134
00135 if (this->mUseFibreOrientation)
00136 {
00137 this->CloseFibreOrientationFile();
00138 }
00139 }
00140
00141 this->mInitialised = true;
00142 }
00143
00144
00146
00148
00149 template class OrthotropicConductivityTensors<1>;
00150 template class OrthotropicConductivityTensors<2>;
00151 template class OrthotropicConductivityTensors<3>;