/* * 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 . */ #include "operator_ext_tfsf.h" #include "engine_ext_tfsf.h" #include Operator_Ext_TFST::Operator_Ext_TFST(Operator* op) : Operator_Extension(op) { Init(); } Operator_Ext_TFST::~Operator_Ext_TFST() { Reset(); } void Operator_Ext_TFST::Init() { for (int n=0;n<3;++n) for (int l=0;l<2;++l) for (int c=0;c<2;++c) { m_VoltDelay[n][l][c]=NULL; m_VoltDelayDelta[n][l][c]=NULL; m_VoltAmp[n][l][c]=NULL; m_CurrDelay[n][l][c]=NULL; m_CurrDelayDelta[n][l][c]=NULL; m_CurrAmp[n][l][c]=NULL; } m_Frequency = 0.0; m_PhVel = __C0__; Operator_Extension::Init(); } void Operator_Ext_TFST::Reset() { for (int n=0;n<3;++n) for (int l=0;l<2;++l) for (int c=0;c<2;++c) { delete[] m_VoltDelay[n][l][c]; m_VoltDelay[n][l][c]=NULL; delete[] m_VoltDelayDelta[n][l][c]; m_VoltDelayDelta[n][l][c]=NULL; delete[] m_VoltAmp[n][l][c]; m_VoltAmp[n][l][c]=NULL; delete[] m_CurrDelay[n][l][c]; m_CurrDelay[n][l][c]=NULL; delete[] m_CurrDelayDelta[n][l][c]; m_CurrDelayDelta[n][l][c]=NULL; delete[] m_CurrAmp[n][l][c]; m_CurrAmp[n][l][c]=NULL; } Operator_Extension::Reset(); } Operator_Extension* Operator_Ext_TFST::Clone(Operator* op) { UNUSED(op); return NULL; } bool Operator_Ext_TFST::BuildExtension() { m_Exc = m_Op->GetExcitationSignal(); double dT = m_Op->GetTimestep(); if (dT==0) return false; if (m_Exc==0) return false; Reset(); ContinuousStructure* CSX = m_Op->GetGeometryCSX(); vector vec_prop = CSX->GetPropertyByType(CSProperties::EXCITATION); if (vec_prop.size()==0) { cerr << "Operator_Ext_TFST::BuildExtension: Warning, no excitation properties found" << endl; SetActive(false); return false; } m_PhVel = __C0__; CSPropExcitation* elec=NULL; CSProperties* prop=NULL; CSPrimitives* prim=NULL; CSPrimBox* box=NULL; for (size_t p=0; pToExcitation(); if (elec->GetExcitType()!=10) continue; if (prop->GetQtyPrimitives()!=1) { cerr << "Operator_Ext_TFST::BuildExtension: Warning, plane wave excitation found with more (or less) than one primitive, skipping..." << endl; continue; } prim = prop->GetPrimitive(0); if (prim->GetType()!=CSPrimitives::BOX) { cerr << "Operator_Ext_TFST::BuildExtension: Warning, plane wave excitation found with false non-Box primitive, skipping..." << endl; continue; } box = prim->ToBox(); if (box==NULL) //sanity check, should not happen! { SetActive(false); return false; } // found a plane-wave excite with exactly one box for (int n=0;n<3;++n) m_PropDir[n] = elec->GetPropagationDir(n); double dir_norm = sqrt(m_PropDir[0]*m_PropDir[0]+m_PropDir[1]*m_PropDir[1]+m_PropDir[2]*m_PropDir[2]); if (dir_norm==0) { cerr << "Operator_Ext_TFST::BuildExtension: Warning, plane wave direction is zero, skipping..." << endl; SetActive(false); return false; } //make it a unit vector m_PropDir[0]/=dir_norm;m_PropDir[1]/=dir_norm;m_PropDir[2]/=dir_norm; if (m_Op->SnapBox2Mesh(box->GetStartCoord()->GetNativeCoords(), box->GetStopCoord()->GetNativeCoords(), m_Start, m_Stop)!=3) { cerr << "Operator_Ext_TFST::BuildExtension: Warning, plane wave box dimension is invalid, skipping..." << endl; SetActive(false); return false; } m_Frequency = elec->GetFrequency(); // if (m_Frequency<=0) // m_Frequency = m_Op->GetExcitationSignal()->GetFrequencyOfInterest(); if (m_Frequency<=0) m_PhVel=__C0__; else m_PhVel=m_Op->CalcNumericPhaseVelocity(m_Start,m_Stop,m_PropDir,m_Frequency); if ((m_PhVel<0) || (m_PhVel>__C0__) || isnan(m_PhVel)) { cerr << "Operator_Ext_TFST::BuildExtension: Warning, invalid phase velocity found, resetting to c0! " << endl; m_PhVel = __C0__; } double origin[3]; unsigned int ui_origin[3]; for (int n=0;n<3;++n) { m_E_Amp[n] = elec->GetExcitation(n); m_numLines[n] = m_Stop[n]-m_Start[n]+1; m_IncLow[n] = m_PropDir[n]>=0; if (m_Start[n]==0) m_ActiveDir[n][0]=false; else m_ActiveDir[n][0]=true; if (m_Stop[n]==m_Op->GetOriginalNumLines(n)-1) m_ActiveDir[n][1]=false; else m_ActiveDir[n][1]=true; if (m_IncLow[n]) { ui_origin[n] = m_Start[n]-1; } else { ui_origin[n] = m_Stop[n]+1; } origin[n] = m_Op->GetDiscLine(n,ui_origin[n]); } double dotEk = (m_E_Amp[0]*m_PropDir[0] + m_E_Amp[1]*m_PropDir[1] + m_E_Amp[2]*m_PropDir[2]); double angle = acos( dotEk / (m_E_Amp[0]*m_E_Amp[0] + m_E_Amp[1]*m_E_Amp[1] + m_E_Amp[2]*m_E_Amp[2]) ) / PI * 180; if (angle==0) { cerr << "Operator_Ext_TFST::BuildExtension: Warning, plane wave direction and polarization is identical, skipping..." << endl; SetActive(false); return false; } if (angle!=90) { cerr << "Operator_Ext_TFST::BuildExtension: Warning, angle between propagation direction and polarization is not 90deg, resetting E-polarization to : ("; for (int n=0;n<3;++n) m_E_Amp[n]-=m_PropDir[n]*dotEk; cerr << m_E_Amp[0] << "," << m_E_Amp[1] << "," << m_E_Amp[2] << ")" << endl; } int nP,nPP; for (int n=0;n<3;++n) { nP = (n+1)%3; nPP = (n+2)%3; m_H_Amp[n] = m_PropDir[nP]*m_E_Amp[nPP] - m_PropDir[nPP]*m_E_Amp[nP]; m_H_Amp[n] /= __Z0__; } double coord[3]; double unit = m_Op->GetGridDelta(); double delay; double dist; unsigned int pos[3]; unsigned int numP, ui_pos; m_maxDelay = 0; for (int n=0;n<3;++n) { nP = (n+1)%3; nPP = (n+2)%3; pos[n] = 0; //unused pos[nP] = m_Start[nP]; numP = m_numLines[nP]*m_numLines[nPP]; if (!m_ActiveDir[n][0] && !m_ActiveDir[n][1]) continue; for (int l=0;l<2;++l) for (int c=0;c<2;++c) { if (m_ActiveDir[n][l]) { m_VoltDelay[n][l][c]=new unsigned int[numP]; m_VoltDelayDelta[n][l][c]=new FDTD_FLOAT[numP]; m_VoltAmp[n][l][c]=new FDTD_FLOAT[numP]; m_CurrDelay[n][l][c]=new unsigned int[numP]; m_CurrDelayDelta[n][l][c]=new FDTD_FLOAT[numP]; m_CurrAmp[n][l][c]=new FDTD_FLOAT[numP]; } } ui_pos = 0; for (unsigned int i=0;iGetYeeCoords(nP,pos,coord,false); dist = fabs((coord[0]-origin[0])*m_PropDir[0])+fabs((coord[1]-origin[1])*m_PropDir[1])+fabs((coord[2]-origin[2])*m_PropDir[2]); delay = dist*unit/m_PhVel/dT; m_maxDelay = max((unsigned int)delay,m_maxDelay); m_CurrDelay[n][0][1][ui_pos] = floor(delay); m_CurrDelayDelta[n][0][1][ui_pos] = delay - floor(delay); m_CurrAmp[n][0][1][ui_pos] = m_E_Amp[nP]*m_Op->GetEdgeLength(nP,pos); m_Op->GetYeeCoords(nPP,pos,coord,false); dist = fabs((coord[0]-origin[0])*m_PropDir[0])+fabs((coord[1]-origin[1])*m_PropDir[1])+fabs((coord[2]-origin[2])*m_PropDir[2]); delay = dist*unit/m_PhVel/dT; m_maxDelay = max((unsigned int)delay,m_maxDelay); m_CurrDelay[n][0][0][ui_pos] = floor(delay); m_CurrDelayDelta[n][0][0][ui_pos] = delay - floor(delay); m_CurrAmp[n][0][0][ui_pos] = m_E_Amp[nPP]*m_Op->GetEdgeLength(nPP,pos); --pos[n]; m_CurrAmp[n][0][0][ui_pos]*=m_Op->GetIV(nP,pos); m_CurrAmp[n][0][1][ui_pos]*=m_Op->GetIV(nPP,pos); } if (m_ActiveDir[n][1]) { pos[n] = m_Stop[n]; m_Op->GetYeeCoords(nP,pos,coord,false); dist = fabs((coord[0]-origin[0])*m_PropDir[0])+fabs((coord[1]-origin[1])*m_PropDir[1])+fabs((coord[2]-origin[2])*m_PropDir[2]); delay = dist*unit/m_PhVel/dT; m_maxDelay = max((unsigned int)delay,m_maxDelay); m_CurrDelay[n][1][1][ui_pos] = floor(delay); m_CurrDelayDelta[n][1][1][ui_pos] = delay - floor(delay); m_CurrAmp[n][1][1][ui_pos] = m_E_Amp[nP]*m_Op->GetEdgeLength(nP,pos); m_Op->GetYeeCoords(nPP,pos,coord,false); dist = fabs((coord[0]-origin[0])*m_PropDir[0])+fabs((coord[1]-origin[1])*m_PropDir[1])+fabs((coord[2]-origin[2])*m_PropDir[2]); delay = dist*unit/m_PhVel/dT; m_maxDelay = max((unsigned int)delay,m_maxDelay); m_CurrDelay[n][1][0][ui_pos] = floor(delay); m_CurrDelayDelta[n][1][0][ui_pos] = delay - floor(delay); m_CurrAmp[n][1][0][ui_pos] = m_E_Amp[nPP]*m_Op->GetEdgeLength(nPP,pos); m_CurrAmp[n][1][0][ui_pos]*=m_Op->GetIV(nP,pos); m_CurrAmp[n][1][1][ui_pos]*=m_Op->GetIV(nPP,pos); } if (m_ActiveDir[n][0]) m_CurrAmp[n][0][0][ui_pos]*=-1; if (m_ActiveDir[n][1]) m_CurrAmp[n][1][1][ui_pos]*=-1; if (pos[nP]==m_Stop[nP]) { if (m_ActiveDir[n][0]) m_CurrAmp[n][0][1][ui_pos]=0; if (m_ActiveDir[n][1]) m_CurrAmp[n][1][1][ui_pos]=0; } if (pos[nPP]==m_Stop[nPP]) { if (m_ActiveDir[n][0]) m_CurrAmp[n][0][0][ui_pos]=0; if (m_ActiveDir[n][1]) m_CurrAmp[n][1][0][ui_pos]=0; } // voltage updates pos[n] = m_Start[n]-1; if (m_ActiveDir[n][0]) { m_Op->GetYeeCoords(nP,pos,coord,true); dist = fabs((coord[0]-origin[0])*m_PropDir[0])+fabs((coord[1]-origin[1])*m_PropDir[1])+fabs((coord[2]-origin[2])*m_PropDir[2]); delay = dist*unit/m_PhVel/dT + 1.0; m_maxDelay = max((unsigned int)delay,m_maxDelay); m_VoltDelay[n][0][1][ui_pos] = floor(delay); m_VoltDelayDelta[n][0][1][ui_pos] = delay - floor(delay); m_VoltAmp[n][0][1][ui_pos] = m_H_Amp[nP]*m_Op->GetEdgeLength(nP,pos,true); m_Op->GetYeeCoords(nPP,pos,coord,true); dist = fabs((coord[0]-origin[0])*m_PropDir[0])+fabs((coord[1]-origin[1])*m_PropDir[1])+fabs((coord[2]-origin[2])*m_PropDir[2]); delay = dist*unit/m_PhVel/dT + 1.0; m_maxDelay = max((unsigned int)delay,m_maxDelay); m_VoltDelay[n][0][0][ui_pos] = floor(delay); m_VoltDelayDelta[n][0][0][ui_pos] = delay - floor(delay); m_VoltAmp[n][0][0][ui_pos] = m_H_Amp[nPP]*m_Op->GetEdgeLength(nPP,pos,true); ++pos[n]; m_VoltAmp[n][0][0][ui_pos]*=m_Op->GetVI(nP,pos); m_VoltAmp[n][0][1][ui_pos]*=m_Op->GetVI(nPP,pos); } pos[n] = m_Stop[n]; if (m_ActiveDir[n][1]) { m_Op->GetYeeCoords(nP,pos,coord,true); dist = fabs((coord[0]-origin[0])*m_PropDir[0])+fabs((coord[1]-origin[1])*m_PropDir[1])+fabs((coord[2]-origin[2])*m_PropDir[2]); delay = dist*unit/m_PhVel/dT + 1.0; m_maxDelay = max((unsigned int)delay,m_maxDelay); m_VoltDelay[n][1][1][ui_pos] = floor(delay); m_VoltDelayDelta[n][1][1][ui_pos] = delay - floor(delay); m_VoltAmp[n][1][1][ui_pos] = m_H_Amp[nP]*m_Op->GetEdgeLength(nP,pos,true); m_Op->GetYeeCoords(nPP,pos,coord,true); dist = fabs((coord[0]-origin[0])*m_PropDir[0])+fabs((coord[1]-origin[1])*m_PropDir[1])+fabs((coord[2]-origin[2])*m_PropDir[2]); delay = dist*unit/m_PhVel/dT + 1.0; m_maxDelay = max((unsigned int)delay,m_maxDelay); m_VoltDelay[n][1][0][ui_pos] = floor(delay); m_VoltDelayDelta[n][1][0][ui_pos] = delay - floor(delay); m_VoltAmp[n][1][0][ui_pos] = m_H_Amp[nPP]*m_Op->GetEdgeLength(nPP,pos,true); m_VoltAmp[n][1][0][ui_pos]*=m_Op->GetVI(nP,pos); m_VoltAmp[n][1][1][ui_pos]*=m_Op->GetVI(nPP,pos); } if (m_ActiveDir[n][1]) m_VoltAmp[n][1][0][ui_pos]*=-1; if (m_ActiveDir[n][0]) m_VoltAmp[n][0][1][ui_pos]*=-1; if (pos[nP]==m_Stop[nP]) { if (m_ActiveDir[n][0]) m_VoltAmp[n][0][0][ui_pos]=0; if (m_ActiveDir[n][1]) m_VoltAmp[n][1][0][ui_pos]=0; } if (pos[nPP]==m_Stop[nPP]) { if (m_ActiveDir[n][0]) m_VoltAmp[n][0][1][ui_pos]=0; if (m_ActiveDir[n][1]) m_VoltAmp[n][1][1][ui_pos]=0; } ++pos[nPP]; ++ui_pos; } ++pos[nP]; } } ++m_maxDelay; return true; } SetActive(false); return false; } Engine_Extension* Operator_Ext_TFST::CreateEngineExtention() { return new Engine_Ext_TFSF(this); } void Operator_Ext_TFST::ShowStat(ostream &ostr) const { Operator_Extension::ShowStat(ostr); cout << "Active directions\t: " << "(" << m_ActiveDir[0][0] << "/" << m_ActiveDir[0][1] << ", " << m_ActiveDir[1][0] << "/" << m_ActiveDir[1][1] << ", " << m_ActiveDir[2][0] << "/" << m_ActiveDir[2][1] << ")" << endl; cout << "Propagation direction\t: " << "(" << m_PropDir[0] << ", " << m_PropDir[1] << ", " << m_PropDir[2] << ")" << endl; cout << "Rel. propagation speed\t: " << m_PhVel/__C0__ << "*c0 @ " << m_Frequency << " Hz" << endl; cout << "E-field amplitude\t: " << "(" << m_E_Amp[0] << ", " << m_E_Amp[1] << ", " << m_E_Amp[2] << ")" << endl; cout << "H-field amplitude\t: " << "(" << m_H_Amp[0]*__Z0__ << ", " << m_H_Amp[1]*__Z0__ << ", " << m_H_Amp[2]*__Z0__ << ")/Z0" << endl; cout << "Box Dimensions\t\t: " << m_numLines[0] << " x " << m_numLines[1] << " x " << m_numLines[2] << endl; cout << "Max. Delay (TS)\t\t: " << m_maxDelay << endl; int dirs = m_ActiveDir[0][0] + m_ActiveDir[0][1] + m_ActiveDir[1][0] + m_ActiveDir[1][1] + m_ActiveDir[2][0] + m_ActiveDir[2][1] ; cout << "Memory usage (est.)\t: ~" << m_numLines[0] * m_numLines[1] * m_numLines[2] * dirs * 4 * 4 / 1024 << " kiB" << endl; }