openEMS/nf2ff/nf2ff.cpp

550 lines
14 KiB
C++
Raw Normal View History

/*
* Copyright (C) 2012 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 <http://www.gnu.org/licenses/>.
*/
#include "nf2ff.h"
#include "nf2ff_calc.h"
#include "../tools/array_ops.h"
#include "../tools/useful.h"
#include "../tools/hdf5_file_reader.h"
#include "../tools/hdf5_file_writer.h"
#include <hdf5.h>
#include <boost/algorithm/string.hpp>
#include <stdio.h>
#include <stdlib.h>
#include <vector>
#include <cmath>
#include <complex>
#include <iostream>
#include <sstream>
//external libs
#include "tinyxml.h"
nf2ff::nf2ff(vector<float> freq, vector<float> theta, vector<float> phi, vector<float> center, unsigned int numThreads)
{
m_freq = freq;
m_numTheta = theta.size();
m_theta = new float[m_numTheta];
for (size_t n=0;n<m_numTheta;++n)
m_theta[n]=theta.at(n);
m_numPhi = phi.size();
m_phi = new float[m_numPhi];
for (size_t n=0;n<m_numPhi;++n)
m_phi[n]=phi.at(n);
m_nf2ff.resize(freq.size(),NULL);
for (size_t fn=0;fn<freq.size();++fn)
{
m_nf2ff.at(fn) = new nf2ff_calc(freq.at(fn),theta, phi, center);
if (numThreads)
m_nf2ff.at(fn)->SetNumThreads(numThreads);
}
m_radius = 1;
m_Verbose = 0;
}
nf2ff::~nf2ff()
{
m_freq.clear();
for (size_t fn=0;fn<m_nf2ff.size();++fn)
delete m_nf2ff.at(fn);
m_nf2ff.clear();
delete[] m_phi;
m_phi = NULL;
delete[] m_theta;
m_theta = NULL;
}
bool nf2ff::AnalyseXMLNode(TiXmlElement* ti_nf2ff)
{
if (ti_nf2ff==NULL)
return false;
unsigned int numThreads=0;
int ihelp=0;
if (ti_nf2ff->QueryIntAttribute("NumThreads",&ihelp) == TIXML_SUCCESS)
{
numThreads = ihelp;
cerr << "nf2ff: Set number of threads to: " << numThreads << endl;
}
int Verbose=0;
if (ti_nf2ff->QueryIntAttribute("Verbose",&Verbose) == TIXML_SUCCESS)
cerr << "nf2ff: Set verbose level to " << Verbose << endl;
else
Verbose = 0;
const char* attr = NULL;
attr = ti_nf2ff->Attribute("freq");
if (attr==NULL)
{
cerr << "nf2ff::AnalyseXMLNode: Can't read frequency inforamtions ... " << endl;
return false;
}
vector<float> freq = SplitString2Float(attr);
vector<float> center;
attr = ti_nf2ff->Attribute("Center");
if (attr!=NULL)
center = SplitString2Float(attr);
attr = ti_nf2ff->Attribute("Outfile");
if (attr==NULL)
{
cerr << "nf2ff::AnalyseXMLNode: Can't read frequency inforamtions ... " << endl;
return false;
}
string outfile = string(attr);
if (outfile.empty())
{
cerr << "nf2ff::AnalyseXMLNode: outfile is empty, skipping nf2ff... " << endl;
return false;
}
TiXmlElement* ti_theta = ti_nf2ff->FirstChildElement("theta");
if (ti_theta==NULL)
{
cerr << "nf2ff::AnalyseXMLNode: Can't read theta values ... " << endl;
return false;
}
TiXmlNode* ti_theta_node = ti_theta->FirstChild();
if (ti_theta_node==NULL)
{
cerr << "nf2ff::AnalyseXMLNode: Can't read theta text child ... " << endl;
return false;
}
TiXmlText* ti_theta_text = ti_theta_node->ToText();
if (ti_theta_text==NULL)
{
cerr << "nf2ff::AnalyseXMLNode: Can't read theta text values ... " << endl;
return false;
}
vector<float> theta = SplitString2Float(ti_theta_text->Value());
TiXmlElement* ti_phi = ti_nf2ff->FirstChildElement("phi");
if (ti_phi==NULL)
{
cerr << "nf2ff::AnalyseXMLNode: Can't read phi values ... " << endl;
return false;
}
TiXmlNode* ti_phi_node = ti_phi->FirstChild();
if (ti_phi_node==NULL)
{
cerr << "nf2ff::AnalyseXMLNode: Can't read phi text child ... " << endl;
return false;
}
TiXmlText* ti_phi_text = ti_phi_node->ToText();
if (ti_phi_text==NULL)
{
cerr << "nf2ff::AnalyseXMLNode: Can't read phi text values ... " << endl;
return false;
}
vector<float> phi = SplitString2Float(ti_phi_text->Value());
nf2ff* l_nf2ff = new nf2ff(freq,theta,phi,center,numThreads);
l_nf2ff->SetVerboseLevel(Verbose);
TiXmlElement* ti_Planes = ti_nf2ff->FirstChildElement();
string E_name;
string H_name;
while (ti_Planes!=NULL)
{
E_name = string(ti_Planes->Attribute("E_Field"));
H_name = string(ti_Planes->Attribute("H_Field"));
if ((!E_name.empty()) && (!H_name.empty()))
{
if (l_nf2ff->AnalyseFile(E_name,H_name)==false)
{
cerr << "nf2ff::AnalyseXMLNode: Error, analysing Plane ... " << endl;
return false;
}
}
else
{
cerr << "nf2ff::AnalyseXMLNode: Error, invalid plane entry ... " << endl;
return false;
}
ti_Planes = ti_Planes->NextSiblingElement("Planes");
}
l_nf2ff->Write2HDF5(outfile);
delete l_nf2ff;
return true;
}
bool nf2ff::AnalyseXMLFile(string filename)
{
TiXmlDocument doc(filename.c_str());
if (!doc.LoadFile())
{
cerr << "nf2ff::AnalyseXMLFile: Error loading xml-file failed!!! File: " << filename << endl;
return false;
}
TiXmlElement* ti_nf2ff = doc.FirstChildElement("nf2ff");
if (ti_nf2ff==NULL)
{
cerr << "nf2ff::AnalyseXMLFile: Can't read nf2ff ... " << endl;
return false;
}
return AnalyseXMLNode(ti_nf2ff);
}
bool nf2ff::AnalyseFile(string E_Field_file, string H_Field_file)
{
HDF5_File_Reader E_file(E_Field_file);
HDF5_File_Reader H_file(H_Field_file);
if (m_Verbose>0)
2012-02-27 14:13:01 +00:00
cerr << "nf2ff: Reading planes: " << E_Field_file << " & " << H_Field_file << endl;
// read E-mesh
float* E_lines[3]={NULL,NULL,NULL};
unsigned int E_numLines[3];
int E_meshType;
if (E_file.ReadMesh(E_lines, E_numLines, E_meshType) == false)
{
cerr << "nf2ff::AnalyseFile: Error reading E-field mesh..." << endl;
return false;
}
// read H-mesh
float* H_lines[3]={NULL,NULL,NULL};
unsigned int H_numLines[3];
int H_meshType;
if (H_file.ReadMesh(H_lines, H_numLines, H_meshType) == false)
{
cerr << "nf2ff::AnalyseFile: Error reading H-Field mesh..." << endl;
for (int n=0;n<3;++n)
delete[] E_lines[n];
return false;
}
// compare E/H meshs
if (E_meshType!=H_meshType)
{
cerr << "nf2ff::AnalyseFile: Error mesh types don't agree" << endl;
for (int n=0;n<3;++n)
{
delete[] H_lines[n];
delete[] E_lines[n];
}
return false;
}
if ((E_numLines[0]!=H_numLines[0]) || (E_numLines[1]!=H_numLines[1]) || (E_numLines[2]!=H_numLines[2]))
{
cerr << "nf2ff::AnalyseFile: Error mesh dimensions don't agree" << endl;
for (int n=0;n<3;++n)
{
delete[] H_lines[n];
delete[] E_lines[n];
}
return false;
}
for (int n=0;n<3;++n)
for (unsigned int m=0;m<E_numLines[n];++m)
if (E_lines[n][m]!=H_lines[n][m])
{
cerr << "nf2ff::AnalyseFile: Error mesh lines don't agree" << endl;
for (int n=0;n<3;++n)
{
delete[] H_lines[n];
delete[] E_lines[n];
}
return false;
}
for (int n=0;n<3;++n)
delete[] H_lines[n];
if (m_Verbose>0)
cerr << "nf2ff: Data-Size: " << E_numLines[0] << "x" << E_numLines[1] << "x" << E_numLines[2] << endl;
// test if FD data available or fallback to TD is necessary
bool fallBack_TD=false;
vector<float> FD_freq;
if (E_file.ReadFrequencies(FD_freq)==false)
fallBack_TD = true;
if (FD_freq.size()>0)
{
vector<float> H_freq;
if (H_file.ReadFrequencies(H_freq)==false)
{
cerr << "nf2ff::AnalyseFile: Error, number of FD data mismatch, fallback to TD data..." << endl;
fallBack_TD = true;
}
else
{
for (size_t nf=0;nf<FD_freq.size();++nf)
if (FD_freq.at(nf)!=H_freq.at(nf))
{
cerr << "nf2ff::AnalyseFile: Error, frequency data mismatch, fallback to TD data..." << endl;
fallBack_TD = true;
break;
}
}
}
else
fallBack_TD = true;
// search FD-data frequency index that matches requested nf2ff frequencies
vector<size_t> FD_index;
if (fallBack_TD==false)
{
FD_index.resize(FD_freq.size(),-1);
for (size_t n=0;n<m_freq.size();++n)
{
bool found=false;
for (size_t nf=0;nf<FD_freq.size();++nf)
{
if (FD_freq.at(nf)==m_freq.at(n))
{
FD_index.at(n)=nf;
found = true;
break;
}
}
if (found==false)
{
fallBack_TD=true;
cerr << "nf2ff::AnalyseFile: Frequency " << m_freq.at(n) << " not found in FD data, general fallback to TD data..." << endl;
break;
}
}
}
if (fallBack_TD)
{
vector<complex<float>****> E_fd_data;
vector<complex<float>****> H_fd_data;
if (m_Verbose>1)
cerr << "nf2ff: calculate dft..." << endl;
unsigned int data_size[4];
if (E_file.CalcFDVectorData(m_freq,E_fd_data,data_size)==false)
{
for (int n=0;n<3;++n)
delete[] E_lines[n];
return false;
}
if ((data_size[0]!=E_numLines[0]) || (data_size[1]!=E_numLines[1]) || (data_size[2]!=E_numLines[2]) )
{
for (size_t fn=0;fn<m_nf2ff.size();++fn)
{
Delete_N_3DArray<complex<float> >(E_fd_data.at(fn),data_size);
}
for (int n=0;n<3;++n)
delete[] E_lines[n];
return false;
}
if (H_file.CalcFDVectorData(m_freq,H_fd_data,data_size)==false)
{
for (size_t fn=0;fn<m_nf2ff.size();++fn)
Delete_N_3DArray<complex<float> >(E_fd_data.at(fn),data_size);
for (int n=0;n<3;++n)
delete[] E_lines[n];
return false;
}
if ((data_size[0]!=E_numLines[0]) || (data_size[1]!=E_numLines[1]) || (data_size[2]!=E_numLines[2]) )
{
for (size_t fn=0;fn<m_nf2ff.size();++fn)
{
Delete_N_3DArray<complex<float> >(E_fd_data.at(fn),data_size);
Delete_N_3DArray<complex<float> >(H_fd_data.at(fn),data_size);
}
for (int n=0;n<3;++n)
delete[] E_lines[n];
return false;
}
if (m_Verbose>0)
cerr << "nf2ff: Analysing far-field for " << m_nf2ff.size() << " frequencies. " << endl;
for (size_t fn=0;fn<m_nf2ff.size();++fn)
{
if (m_Verbose>1)
cerr << "nf2ff: f = " << m_freq.at(fn) << "Hz (" << fn+1 << "/" << m_freq.size() << ") ...";
m_nf2ff.at(fn)->AddPlane(E_lines, E_numLines, E_fd_data.at(fn), H_fd_data.at(fn),E_meshType);
if (m_Verbose>1)
cerr << " done." << endl;
}
}
else
{
complex<float>**** E_fd_data;
complex<float>**** H_fd_data;
unsigned int data_size[4];
for (size_t n=0;n<m_freq.size();++n)
{
E_fd_data = E_file.GetFDVectorData(FD_index.at(n),data_size);
if ((data_size[0]!=E_numLines[0]) || (data_size[1]!=E_numLines[1]) || (data_size[2]!=E_numLines[2]) )
{
cerr << data_size[0] << "," << data_size[1] << "," << data_size[2] << endl;
cerr << "nf2ff::AnalyseFile: FD data size mismatch... " << endl;
Delete_N_3DArray<complex<float> >(E_fd_data,data_size);
for (int n=0;n<3;++n)
delete[] E_lines[n];
return false;
}
H_fd_data = H_file.GetFDVectorData(FD_index.at(n),data_size);
if ((data_size[0]!=E_numLines[0]) || (data_size[1]!=E_numLines[1]) || (data_size[2]!=E_numLines[2]) )
{
cerr << data_size[0] << "," << data_size[1] << "," << data_size[2] << endl;
cerr << "nf2ff::AnalyseFile: FD data size mismatch... " << endl;
Delete_N_3DArray<complex<float> >(H_fd_data,data_size);
Delete_N_3DArray<complex<float> >(E_fd_data,data_size);
for (int n=0;n<3;++n)
delete[] E_lines[n];
return false;
}
if ((E_fd_data==NULL) || (H_fd_data==NULL))
{
cerr << "nf2ff::AnalyseFile: Reaing FD data failed... " << endl;
Delete_N_3DArray<complex<float> >(E_fd_data,data_size);
Delete_N_3DArray<complex<float> >(H_fd_data,data_size);
for (int n=0;n<3;++n)
delete[] E_lines[n];
return false;
}
if (m_Verbose>1)
cerr << "nf2ff: f = " << m_freq.at(n) << "Hz (" << n+1 << "/" << m_freq.size() << ") ...";
m_nf2ff.at(n)->AddPlane(E_lines, E_numLines, E_fd_data, H_fd_data,E_meshType);
if (m_Verbose>1)
cerr << " done." << endl;
}
}
for (int n=0;n<3;++n)
delete[] E_lines[n];
return true;
}
bool nf2ff::Write2HDF5(string filename)
{
HDF5_File_Writer hdf_file(filename);
//write mesh information
hdf_file.SetCurrentGroup("/Mesh");
size_t meshsize[1]={m_numTheta};
if (hdf_file.WriteData(string("theta"),m_theta,1,meshsize)==false)
return false;
meshsize[0]=m_numPhi;
if (hdf_file.WriteData(string("phi"),m_phi,1,meshsize)==false)
return false;
meshsize[0]=1;
float rad[1]={m_radius};
if (hdf_file.WriteData(string("r"),rad,1,meshsize)==false)
return false;
float attr_value = 2;
hdf_file.WriteAtrribute("/Mesh", "MeshType", &attr_value, 1);
//write field data
size_t dim = 2;
size_t pos = 0;
size_t datasize[2]={m_numPhi,m_numTheta};
size_t size = datasize[0]*datasize[1];
float* buffer = new float[size];
complex<float>** field_data;
string field_names[2]={"E_theta", "E_phi"};
for (int n=0;n<2;++n)
{
hdf_file.SetCurrentGroup("/nf2ff/" + field_names[n] + "/FD");
for (size_t fn=0;fn<m_freq.size();++fn)
{
stringstream ss;
ss << "f" << fn;
pos = 0;
if (n==0)
field_data = GetETheta(fn);
else
field_data = GetEPhi(fn);
for (size_t j=0;j<m_numPhi;++j)
for (size_t i=0;i<m_numTheta;++i)
{
buffer[pos++]=real(field_data[i][j]);
}
if (hdf_file.WriteData(ss.str() + "_real",buffer,dim,datasize)==false)
{
delete[] buffer;
cerr << "nf2ff::Write2HDF5: Error writing field data" << endl;
return false;
}
pos = 0;
for (size_t j=0;j<m_numPhi;++j)
for (size_t i=0;i<m_numTheta;++i)
{
buffer[pos++]=imag(field_data[i][j]);
}
if (hdf_file.WriteData(ss.str() + "_imag",buffer,dim,datasize)==false)
{
delete[] buffer;
cerr << "nf2ff::Write2HDF5: Error writing field data" << endl;
return false;
}
}
}
//dump radiated power
hdf_file.SetCurrentGroup("/nf2ff/P_rad/FD");
for (size_t fn=0;fn<m_freq.size();++fn)
{
stringstream ss;
ss << "f" << fn;
pos = 0;
float** field_data = GetRadPower(fn);
for (size_t j=0;j<m_numPhi;++j)
for (size_t i=0;i<m_numTheta;++i)
{
buffer[pos++]=field_data[i][j];
}
if (hdf_file.WriteData(ss.str(),buffer,dim,datasize)==false)
{
delete[] buffer;
cerr << "nf2ff::Write2HDF5: Error writing field data" << endl;
return false;
}
}
delete[] buffer;
//write frequency attribute
hdf_file.WriteAtrribute("/nf2ff", "Frequency",m_freq);
buffer = new float[m_freq.size()];
//write radiated power attribute
for (size_t fn=0;fn<m_freq.size();++fn)
buffer[fn] = GetTotalRadPower(fn);
hdf_file.WriteAtrribute("/nf2ff", "Prad",buffer,m_freq.size());
//write max directivity attribute
for (size_t fn=0;fn<m_freq.size();++fn)
buffer[fn] = GetMaxDirectivity(fn);
hdf_file.WriteAtrribute("/nf2ff", "Dmax",buffer,m_freq.size());
delete[] buffer;
return true;
}