/* * Copyright (C) 2011 Thorsten Liebig (Thorsten.Liebig@gmx.de) * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include "processfields_sar.h" #include "operator_base.h" #include "tools/vtk_file_writer.h" #include "tools/hdf5_file_writer.h" #include "tools/sar_calculation.h" #include "CSPropMaterial.h" ProcessFieldsSAR::ProcessFieldsSAR(Engine_Interface_Base* eng_if) : ProcessFieldsFD(eng_if) { m_UseCellKappa = true; m_SAR_method = "Simple"; } ProcessFieldsSAR::~ProcessFieldsSAR() { for (size_t n = 0; nGetInterpolationType()!=Engine_Interface_Base::CELL_INTERPOLATE) { cerr << "ProcessFieldsSAR::InitProcess(): Warning, interpolation type is not supported, resetting to CELL!" << endl; SetDumpMode2Cell(); } if ((m_DumpType==SAR_RAW_DATA) && (m_fileType!=HDF5_FILETYPE)) { Enabled=false; cerr << "ProcessFieldsSAR::InitProcess(): Error, wrong file type for dumping raw SAR data! skipping" << endl; return; } ProcessFieldsFD::InitProcess(); if (Enabled==false) return; //create data structures... for (size_t n = 0; n >(numLines)); if (!m_UseCellKappa) m_J_FD_Fields.push_back(Create_N_3DArray >(numLines)); } } int ProcessFieldsSAR::Process() { if (Enabled==false) return -1; if (CheckTimestep()==false) return GetNextInterval(); if ((m_FD_Interval==0) || (m_Eng_Interface->GetNumberOfTimesteps()%m_FD_Interval!=0)) return GetNextInterval(); std::complex**** field_fd = NULL; unsigned int pos[3]; double T; FDTD_FLOAT**** field_td=NULL; //save dump type DumpType save_dump_type = m_DumpType; // calc E-field m_DumpType = E_FIELD_DUMP; field_td = CalcField(); T = m_Eng_Interface->GetTime(m_dualTime); for (size_t n = 0; n exp_jwt_2_dt = std::exp( (std::complex)(-2.0 * _I * M_PI * m_FD_Samples.at(n) * T) ); exp_jwt_2_dt *= 2; // *2 for single-sided spectrum exp_jwt_2_dt *= Op->GetTimestep() * m_FD_Interval; // multiply with timestep-interval field_fd = m_E_FD_Fields.at(n); for (pos[0]=0; pos[0](field_td,numLines); // calc J-field if (!m_UseCellKappa) { m_DumpType = J_FIELD_DUMP; field_td = CalcField(); T = m_Eng_Interface->GetTime(m_dualTime); for (size_t n = 0; n exp_jwt_2_dt = std::exp( (std::complex)(-2.0 * _I * M_PI * m_FD_Samples.at(n) * T) ); exp_jwt_2_dt *= 2; // *2 for single-sided spectrum exp_jwt_2_dt *= Op->GetTimestep() * m_FD_Interval; // multiply with timestep-interval field_fd = m_J_FD_Fields.at(n); for (pos[0]=0; pos[0](field_td,numLines); } //reset dump type m_DumpType = save_dump_type; ++m_FD_SampleCount; return GetNextInterval(); } void ProcessFieldsSAR::DumpFDData() { if (Enabled==false) return; unsigned int pos[3]; unsigned int orig_pos[3]; float*** SAR = Create3DArray(numLines); double coord[3]; ContinuousStructure* CSX = Op->GetGeometryCSX(); CSProperties* prop = NULL; CSPropMaterial* matProp = NULL; double power; float*** cell_volume = Create3DArray(numLines); float*** cell_density = Create3DArray(numLines); float*** cell_kappa = NULL; if (m_UseCellKappa) cell_kappa = Create3DArray(numLines); bool found_UnIsotropic=false; // calculate volumes and masses for all cells for (pos[0]=0; pos[0] vPrims = Op->GetPrimitivesBoundBox(orig_pos[0], orig_pos[1], -1, CSProperties::MATERIAL); for (pos[2]=0; pos[2]GetCellVolume(orig_pos); cell_density[pos[0]][pos[1]][pos[2]] = 0.0; Op->GetCellCenterMaterialAvgCoord(orig_pos, coord); prop = CSX->GetPropertyByCoordPriority(coord, vPrims); // prop = CSX->GetPropertyByCoordPriority(coord,CSProperties::MATERIAL); if (prop!=0) { matProp = dynamic_cast(prop); if (matProp) { found_UnIsotropic |= !matProp->GetIsotropy(); cell_density[pos[0]][pos[1]][pos[2]] = matProp->GetDensityWeighted(coord); if (m_UseCellKappa) cell_kappa[pos[0]][pos[1]][pos[2]] = matProp->GetKappaWeighted(0,coord); } } } } } if (found_UnIsotropic) cerr << "ProcessFieldsSAR::DumpFDData(): Warning, found unisotropic material in SAR calculation... this is unsupported!" << endl; float* cellWidth[3]; for (int n=0;n<3;++n) { cellWidth[n]=new float[numLines[n]]; for (unsigned int i=0;iGetDiscDelta(n,posLines[n][i])*Op->GetGridDelta(); } if (m_DumpType == SAR_RAW_DATA) { if (m_fileType!=HDF5_FILETYPE) { cerr << "ProcessFieldsSAR::DumpFDData(): Error, wrong file type, this should not happen!!! skipped" << endl; return; } size_t datasize[]={numLines[0],numLines[1],numLines[2]}; for (size_t n = 0; nWriteVectorField(ss.str(), m_E_FD_Fields.at(n), datasize)==false) cerr << "ProcessFieldsSAR::DumpFDData: can't dump to file...! " << endl; } m_HDF5_Dump_File->SetCurrentGroup("/CellData"); if (m_UseCellKappa==false) cerr << "ProcessFieldsSAR::DumpFDData: Error, cell conductivity data not available, this should not happen... skipping! " << endl; else if (m_HDF5_Dump_File->WriteScalarField("Conductivity", cell_kappa, datasize)==false) cerr << "ProcessFieldsSAR::DumpFDData: can't dump to file...! " << endl; if (m_HDF5_Dump_File->WriteScalarField("Density", cell_density, datasize)==false) cerr << "ProcessFieldsSAR::DumpFDData: can't dump to file...! " << endl; if (m_HDF5_Dump_File->WriteScalarField("Volume", cell_volume, datasize)==false) cerr << "ProcessFieldsSAR::DumpFDData: can't dump to file...! " << endl; } else { SAR_Calculation SAR_Calc; SAR_Calc.SetAveragingMethod(m_SAR_method, g_settings.GetVerboseLevel()==0); SAR_Calc.SetDebugLevel(g_settings.GetVerboseLevel()); SAR_Calc.SetNumLines(numLines); if (m_DumpType == SAR_LOCAL_DUMP) SAR_Calc.SetAveragingMass(0); else if (m_DumpType == SAR_1G_DUMP) SAR_Calc.SetAveragingMass(1e-3); else if (m_DumpType == SAR_10G_DUMP) SAR_Calc.SetAveragingMass(10e-3); else { cerr << "ProcessFieldsSAR::DumpFDData: unknown SAR dump type...!" << endl; } SAR_Calc.SetCellDensities(cell_density); SAR_Calc.SetCellWidth(cellWidth); SAR_Calc.SetCellVolumes(cell_volume); SAR_Calc.SetCellCondictivity(cell_kappa); // cell_kappa will be NULL if m_UseCellKappa is false for (size_t n = 0; nWriteScalarField(ss.str(), SAR, datasize)==false) cerr << "ProcessFieldsSAR::DumpFDData: can't dump to file...! " << endl; float freq[1] = {(float)m_FD_Samples.at(n)}; if (m_HDF5_Dump_File->WriteAtrribute("/FieldData/FD/"+ss.str(),"frequency",freq,1)==false) cerr << "ProcessFieldsSAR::DumpFDData: can't dump to file...! " << endl; float pow[1] = {(float)power}; if (m_HDF5_Dump_File->WriteAtrribute("/FieldData/FD/"+ss.str(),"power",pow,1)==false) cerr << "ProcessFieldsSAR::DumpFDData: can't dump to file...! " << endl; } else cerr << "ProcessFieldsSAR::DumpFDData: unknown File-Type" << endl; } } for (int n=0;n<3;++n) delete[] cellWidth[n]; Delete3DArray(cell_volume,numLines); Delete3DArray(cell_density,numLines); Delete3DArray(cell_kappa,numLines); Delete3DArray(SAR,numLines); }