/*
* Copyright (C) 2010 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
#include "operator.h"
#include "engine.h"
#include "operator_extension.h"
#include "processfields.h"
#include "tools/array_ops.h"
#include "fparser.hh"
Operator* Operator::New()
{
cout << "Create FDTD operator" << endl;
Operator* op = new Operator();
op->Init();
return op;
}
Operator::Operator()
{
m_MeshType = ProcessFields::CARTESIAN_MESH;
Exc = 0;
}
Operator::~Operator()
{
for (size_t n=0;n2)) return 0.0;
int i_pos[] = {pos[0],pos[1],pos[2]};
return GetMeshDelta(n,i_pos,dualMesh);
}
double Operator::GetMeshDelta(int n, const int* pos, bool dualMesh) const
{
if ((n<0) || (n>2)) return 0.0;
if (dualMesh==false)
return fabs(MainOp->GetIndexDelta(n,pos[n]))*gridDelta;
else
return fabs(MainOp->GetIndexWidth(n,pos[n]))*gridDelta;
}
double Operator::GetDiscLine(int n, unsigned int pos, bool dualMesh) const
{
return GetDiscLine(n,(int)pos,dualMesh);
}
double Operator::GetDiscLine(int n, int pos, bool dualMesh) const
{
if ((n<0) || (n>2)) return 0.0;
if ((pos<0) || (pos>=(int)numLines[n])) return 0.0;
if (dualMesh==false)
return discLines[n][pos];
else
return (discLines[n][pos] + 0.5*fabs(MainOp->GetIndexDelta(n,pos)));
}
double Operator::GetNodeArea(int ny, const int pos[3], bool dualMesh) const
{
int nyP = (ny+1)%3;
int nyPP = (ny+2)%3;
return GetMeshDelta(nyP,pos,!dualMesh) * GetMeshDelta(nyPP,pos,!dualMesh);
}
bool Operator::SnapToMesh(double* dcoord, unsigned int* uicoord, bool lower, bool* inside)
{
bool ok=true;
unsigned int numLines[3];
for (int n=0;n<3;++n)
{
numLines[n] = GetNumberOfLines(n);
if (inside) //set defaults
inside[n] = true;
uicoord[n]=0;
if (dcoord[n]discLines[n][numLines[n]-1])
{
ok=false;
uicoord[n]=numLines[n]-1;
if (lower) uicoord[n]=numLines[n]-2;
if (inside) inside[n] = false;
}
else if (dcoord[n]==discLines[n][numLines[n]-1])
{
uicoord[n]=numLines[n]-1;
if (lower) uicoord[n]=numLines[n]-2;
}
else
for (unsigned int i=1;i=0)
{
P[n] = discLines[n][currPos[n]-1];
Point_Line_Distance(P,start,stop,foot,dist);
if ((foot>currFoot) && (distcurrFoot) && (distVolt_Count << "\t (" << Exc->Volt_Count_Dir[0] << ", " << Exc->Volt_Count_Dir[1] << ", " << Exc->Volt_Count_Dir[2] << ")" << endl;
cout << "Current excitations\t: " << Exc->Curr_Count << "\t (" << Exc->Curr_Count_Dir[0] << ", " << Exc->Curr_Count_Dir[1] << ", " << Exc->Curr_Count_Dir[2] << ")" << endl;
cout << "-----------------------------------" << endl;
cout << "Number of PEC edges\t: " << m_Nr_PEC[0]+m_Nr_PEC[1]+m_Nr_PEC[2] << endl;
cout << "in " << GetDirName(0) << " direction\t\t: " << m_Nr_PEC[0] << endl;
cout << "in " << GetDirName(1) << " direction\t\t: " << m_Nr_PEC[1] << endl;
cout << "in " << GetDirName(2) << " direction\t\t: " << m_Nr_PEC[2] << endl;
cout << "-----------------------------------" << endl;
cout << "Timestep (s)\t\t: " << dT << endl;
cout << "Timestep method name\t: " << m_Used_TS_Name << endl;
cout << "Nyquist criteria (TS)\t: " << Exc->GetNyquistNum() << endl;
cout << "Nyquist criteria (s)\t: " << Exc->GetNyquistNum()*dT << endl;
cout << "Excitation Length (TS)\t: " << Exc->Length << endl;
cout << "Excitation Length (s)\t: " << Exc->Length*dT << endl;
cout << "-----------------------------------" << endl;
}
void Operator::ShowExtStat() const
{
if (m_Op_exts.size()==0) return;
cout << "-----------------------------------" << endl;
for (size_t n=0;nShowStat(cout);
cout << "-----------------------------------" << endl;
}
void Operator::DumpOperator2File(string filename)
{
#ifdef OUTPUT_IN_DRAWINGUNITS
double discLines_scaling = 1;
#else
double discLines_scaling = GetGridDelta();
#endif
ofstream file(filename.c_str(),ios_base::out);
if (file.is_open()==false)
{
cerr << "Operator::DumpOperator2File: Can't open file: " << filename << endl;
return;
}
cout << "Dumping FDTD operator information to vtk file: " << filename << " ..." << flush ;
FDTD_FLOAT**** exc = Create_N_3DArray(numLines);
if (Exc) {
for (unsigned int n=0;nVolt_Count;++n)
exc[Exc->Volt_dir[n]][Exc->Volt_index[0][n]][Exc->Volt_index[1][n]][Exc->Volt_index[2][n]] = Exc->Volt_amp[n];
}
string names[] = {"vv", "vi", "iv" , "ii", "exc"};
FDTD_FLOAT**** array[] = {vv,vi,iv,ii,exc};
ProcessFields::DumpMultiVectorArray2VTK(file, names , array , 5, discLines, numLines, 6, "Operator dump" , (ProcessFields::MeshType)m_MeshType, discLines_scaling);
Delete_N_3DArray(exc,numLines);
file.close();
cout << " done!" << endl;
}
//! \brief dump PEC (perfect electric conductor) information (into VTK-file)
//! visualization via paraview
//! visualize only one component (x, y or z)
void Operator::DumpPEC2File( string filename )
{
ofstream file( filename.c_str() );
if (!file.is_open()) {
cerr << "Operator::DumpPEC2File: Can't open file: " << filename << endl;
return;
}
cout << "Dumping PEC information to vtk file: " << filename << " ..." << flush;
FDTD_FLOAT**** pec = Create_N_3DArray( numLines );
unsigned int pos[3];
for (pos[0]=0; pos[0]GetIndexDelta( 0, pos[0] ); // PEC-x found
if ((GetVV(1,pos[0],pos[1],pos[2]) == 0) && (GetVI(1,pos[0],pos[1],pos[2]) == 0))
pec[1][pos[0]][pos[1]][pos[2]] = MainOp->GetIndexDelta( 1, pos[1] ); // PEC-y found
if ((GetVV(2,pos[0],pos[1],pos[2]) == 0) && (GetVI(2,pos[0],pos[1],pos[2]) == 0))
pec[2][pos[0]][pos[1]][pos[2]] = MainOp->GetIndexDelta( 2, pos[2] ); // PEC-z found
}
}
}
#ifdef OUTPUT_IN_DRAWINGUNITS
double discLines_scaling = 1;
#else
double discLines_scaling = GetGridDelta();
#endif
ProcessFields::DumpVectorArray2VTK( file, "PEC", pec, discLines, numLines, 6, "PEC dump" , (ProcessFields::MeshType)m_MeshType, discLines_scaling );
file.close();
cout << " done!" << endl;
}
void Operator::DumpMaterial2File(string filename)
{
#ifdef OUTPUT_IN_DRAWINGUNITS
double discLines_scaling = 1;
#else
double discLines_scaling = GetGridDelta();
#endif
ofstream file(filename.c_str(),ios_base::out);
if (file.is_open()==false)
{
cerr << "Operator::DumpMaterial2File: Can't open file: " << filename << endl;
return;
}
cout << "Dumping material information to vtk file: " << filename << " ..." << flush;
FDTD_FLOAT*** epsilon;
FDTD_FLOAT*** mue;
FDTD_FLOAT*** kappa;
FDTD_FLOAT*** sigma;
unsigned int pos[3];
double inMat[4];
epsilon = Create3DArray( numLines);
mue = Create3DArray( numLines);
kappa = Create3DArray( numLines);
sigma = Create3DArray( numLines);
for (pos[0]=0;pos[0]GetGrid();
for (int n=0;n<3;++n)
{
discLines[n] = grid->GetLines(n,discLines[n],numLines[n],true);
if (n==1)
if (numLines[n]<3) {cerr << "CartOperator::SetGeometryCSX: you need at least 3 disc-lines in every direction (3D!)!!!" << endl; Reset(); return false;}
}
MainOp = new AdrOp(numLines[0],numLines[1],numLines[2]);
MainOp->SetGrid(discLines[0],discLines[1],discLines[2]);
if (grid->GetDeltaUnit()<=0) {cerr << "CartOperator::SetGeometryCSX: grid delta unit must not be <=0 !!!" << endl; Reset(); return false;}
else gridDelta=grid->GetDeltaUnit();
MainOp->SetGridDelta(1);
MainOp->AddCellAdrOp();
return true;
}
void Operator::InitOperator()
{
Delete_N_3DArray(vv,numLines);
Delete_N_3DArray(vi,numLines);
Delete_N_3DArray(iv,numLines);
Delete_N_3DArray(ii,numLines);
vv = Create_N_3DArray(numLines);
vi = Create_N_3DArray(numLines);
iv = Create_N_3DArray(numLines);
ii = Create_N_3DArray(numLines);
}
void Operator::InitExcitation()
{
delete Exc;
Exc = new Excitation( dT );
}
void Operator::Calc_ECOperatorPos(int n, unsigned int* pos)
{
unsigned int i = MainOp->SetPos(pos[0],pos[1],pos[2]);
if (EC_C[n][i]>0)
{
GetVV(n,pos[0],pos[1],pos[2]) = (1-dT*EC_G[n][i]/2/EC_C[n][i])/(1+dT*EC_G[n][i]/2/EC_C[n][i]);
GetVI(n,pos[0],pos[1],pos[2]) = (dT/EC_C[n][i])/(1+dT*EC_G[n][i]/2/EC_C[n][i]);
}
else
{
GetVV(n,pos[0],pos[1],pos[2]) = 0;
GetVI(n,pos[0],pos[1],pos[2]) = 0;
}
if (EC_L[n][i]>0)
{
GetII(n,pos[0],pos[1],pos[2]) = (1-dT*EC_R[n][i]/2/EC_L[n][i])/(1+dT*EC_R[n][i]/2/EC_L[n][i]);
GetIV(n,pos[0],pos[1],pos[2]) = (dT/EC_L[n][i])/(1+dT*EC_R[n][i]/2/EC_L[n][i]);
}
else
{
GetII(n,pos[0],pos[1],pos[2]) = 0;
GetIV(n,pos[0],pos[1],pos[2]) = 0;
}
}
int Operator::CalcECOperator()
{
Init_EC();
if (Calc_EC()==0)
return -1;
CalcTimestep();
InitOperator();
unsigned int pos[3];
for (int n=0;n<3;++n)
{
for (pos[0]=0;pos[0]BuildExtension();
//cleanup
for (int n=0;n<3;++n)
{
delete[] EC_C[n];EC_C[n]=NULL;
delete[] EC_G[n];EC_G[n]=NULL;
delete[] EC_L[n];EC_L[n]=NULL;
delete[] EC_R[n];EC_R[n]=NULL;
}
//Apply PEC to all boundary's
bool PEC[6]={1,1,1,1,1,1};
//exception for pml boundaries
for (int n=0;n<6;++n)
PEC[n] = m_BC[n]!=3;
ApplyElectricBC(PEC);
InitExcitation();
if (CalcFieldExcitation()==false) return -1;
CalcPEC();
bool PMC[6];
for (int n=0;n<6;++n)
PMC[n] = m_BC[n]==1;
ApplyMagneticBC(PMC);
return 0;
}
void Operator::ApplyElectricBC(bool* dirs)
{
if (dirs==NULL) return;
unsigned int pos[3];
for (int n=0;n<3;++n)
{
int nP = (n+1)%3;
int nPP = (n+2)%3;
for (pos[nP]=0;pos[nP]GetIndexDelta(n,pos[n]);
double deltaP=MainOp->GetIndexDelta(nP,pos[nP]);
double deltaPP=MainOp->GetIndexDelta(nPP,pos[nPP]);
double delta_M=MainOp->GetIndexDelta(n,pos[n]-1);
double deltaP_M=MainOp->GetIndexDelta(nP,pos[nP]-1);
double deltaPP_M=MainOp->GetIndexDelta(nPP,pos[nPP]-1);
//******************************* epsilon,kappa averaging *****************************//
//shift up-right
shiftCoord[n] = coord[n]+delta*0.5;
shiftCoord[nP] = coord[nP]+deltaP*0.25;
shiftCoord[nPP] = coord[nPP]+deltaPP*0.25;
CSProperties* prop = CSX->GetPropertyByCoordPriority(shiftCoord,CSProperties::MATERIAL);
if (prop)
{
CSPropMaterial* mat = prop->ToMaterial();
inEC[0] = mat->GetEpsilonWeighted(n,shiftCoord)*fabs(deltaP*deltaPP);
inEC[1] = mat->GetKappaWeighted(n,shiftCoord)*fabs(deltaP*deltaPP);
}
else
{
inEC[0] = 1*fabs(deltaP*deltaPP);
inEC[1] = 0;
}
//shift up-left
shiftCoord[n] = coord[n]+delta*0.5;
shiftCoord[nP] = coord[nP]-deltaP_M*0.25;
shiftCoord[nPP] = coord[nPP]+deltaPP*0.25;
prop = CSX->GetPropertyByCoordPriority(shiftCoord,CSProperties::MATERIAL);
if (prop)
{
CSPropMaterial* mat = prop->ToMaterial();
inEC[0] += mat->GetEpsilonWeighted(n,shiftCoord)*fabs(deltaP_M*deltaPP);
inEC[1] += mat->GetKappaWeighted(n,shiftCoord)*fabs(deltaP_M*deltaPP);
}
else
{
inEC[0] += 1*fabs(deltaP_M*deltaPP);
inEC[1] += 0;
}
//shift down-right
shiftCoord[n] = coord[n]+delta*0.5;
shiftCoord[nP] = coord[nP]+deltaP*0.25;
shiftCoord[nPP] = coord[nPP]-deltaPP_M*0.25;
prop = CSX->GetPropertyByCoordPriority(shiftCoord,CSProperties::MATERIAL);
if (prop)
{
CSPropMaterial* mat = prop->ToMaterial();
inEC[0] += mat->GetEpsilonWeighted(n,shiftCoord)*fabs(deltaP*deltaPP_M);
inEC[1] += mat->GetKappaWeighted(n,shiftCoord)*fabs(deltaP*deltaPP_M);
}
else
{
inEC[0] += 1*fabs(deltaP*deltaPP_M);
inEC[1] += 0;
}
//shift down-left
shiftCoord[n] = coord[n]+delta*0.5;
shiftCoord[nP] = coord[nP]-deltaP_M*0.25;
shiftCoord[nPP] = coord[nPP]-deltaPP_M*0.25;
prop = CSX->GetPropertyByCoordPriority(shiftCoord,CSProperties::MATERIAL);
if (prop)
{
CSPropMaterial* mat = prop->ToMaterial();
inEC[0] += mat->GetEpsilonWeighted(n,shiftCoord)*fabs(deltaP_M*deltaPP_M);
inEC[1] += mat->GetKappaWeighted(n,shiftCoord)*fabs(deltaP_M*deltaPP_M);
}
else
{
inEC[0] += 1*fabs(deltaP_M*deltaPP_M);
inEC[1] += 0;
}
inEC[0]*=gridDelta/fabs(delta)/4.0*__EPS0__;
inEC[1]*=gridDelta/fabs(delta)/4.0;
//******************************* mu,sigma averaging *****************************//
//shift down
shiftCoord[n] = coord[n]-delta_M*0.25;
shiftCoord[nP] = coord[nP]+deltaP*0.5;
shiftCoord[nPP] = coord[nPP]+deltaPP*0.5;
prop = CSX->GetPropertyByCoordPriority(shiftCoord,CSProperties::MATERIAL);
if (prop)
{
CSPropMaterial* mat = prop->ToMaterial();
inEC[2] = fabs(delta_M) / mat->GetMueWeighted(n,shiftCoord);
if (mat->GetSigma(n))
inEC[3] = fabs(delta_M) / mat->GetSigmaWeighted(n,shiftCoord);
else
inEC[3] = 0;
}
else
{
inEC[2] = fabs(delta_M);
inEC[3] = 0;
}
//shift up
shiftCoord[n] = coord[n]+delta*0.25;
shiftCoord[nP] = coord[nP]+deltaP*0.5;
shiftCoord[nPP] = coord[nPP]+deltaPP*0.5;
prop = CSX->GetPropertyByCoordPriority(shiftCoord,CSProperties::MATERIAL);
if (prop)
{
CSPropMaterial* mat = prop->ToMaterial();
inEC[2] += fabs(delta)/mat->GetMueWeighted(n,shiftCoord);
if (mat->GetSigmaWeighted(n,shiftCoord))
inEC[3] += fabs(delta)/mat->GetSigmaWeighted(n,shiftCoord);
else
inEC[3] = 0;
}
else
{
inEC[2] += fabs(delta);
inEC[3] = 0;
}
inEC[2] = gridDelta * fabs(deltaP*deltaPP) * 2.0 * __MUE0__ / inEC[2];
if (inEC[3]) inEC[3]=gridDelta*fabs(deltaP*deltaPP) * 2.0 / inEC[3];
return true;
}
bool Operator::Calc_EffMatPos(int n, const unsigned int* pos, double* inMat) const
{
this->Calc_ECPos(n,pos,inMat);
inMat[0] *= GetMeshDelta(n,pos)/GetNodeArea(n,pos);
inMat[1] *= GetMeshDelta(n,pos)/GetNodeArea(n,pos);
inMat[2] *= GetMeshDelta(n,pos,true)/GetNodeArea(n,pos,true);
inMat[3] *= GetMeshDelta(n,pos,true)/GetNodeArea(n,pos,true);
return true;
}
void Operator::Init_EC()
{
for (int n=0;n<3;++n)
{
//init x-cell-array
delete[] EC_C[n];
delete[] EC_G[n];
delete[] EC_L[n];
delete[] EC_R[n];
EC_C[n] = new double[MainOp->GetSize()];
EC_G[n] = new double[MainOp->GetSize()];
EC_L[n] = new double[MainOp->GetSize()];
EC_R[n] = new double[MainOp->GetSize()];
for (unsigned int i=0;iGetSize();i++) //init all
{
EC_C[n][i]=0;
EC_G[n][i]=0;
EC_L[n][i]=0;
EC_R[n][i]=0;
}
}
}
bool Operator::Calc_EC()
{
if (CSX==NULL) {cerr << "CartOperator::Calc_EC: CSX not given or invalid!!!" << endl; return false;}
unsigned int ipos;
unsigned int pos[3];
double inEC[4];
for (int n=0;n<3;++n)
{
for (pos[2]=0;pos[2]SetPos(pos[0],pos[1],pos[2]);
EC_C[n][ipos]=inEC[0];
EC_G[n][ipos]=inEC[1];
EC_L[n][ipos]=inEC[2];
EC_R[n][ipos]=inEC[3];
}
}
}
}
return true;
}
double Operator::CalcTimestep()
{
#if 1 //use the new timestep-calc (1) or the old one (0)
return CalcTimestep_Var3(); //the biggest one for cartesian meshes
#else
return CalcTimestep_Var1();
#endif
}
////Berechnung nach Andreas Rennings Dissertation 2008, Seite 66, Formel 4.52
double Operator::CalcTimestep_Var1()
{
m_Used_TS_Name = string("Rennings_1");
// cout << "Operator::CalcTimestep(): Using timestep algorithm by Andreas Rennings, Dissertation @ University Duisburg-Essen, 2008, pp. 66, eq. 4.52" << endl;
dT=1e200;
double newT;
unsigned int pos[3];
unsigned int ipos;
unsigned int ipos_PM;
unsigned int ipos_PPM;
MainOp->SetReflection2Cell();
for (int n=0;n<3;++n)
{
int nP = (n+1)%3;
int nPP = (n+2)%3;
for (pos[2]=0;pos[2]SetPos(pos[0],pos[1],pos[2]);
ipos_PM = MainOp->Shift(nP,-1);
MainOp->ResetShift();
ipos_PPM= MainOp->Shift(nPP,-1);
MainOp->ResetShift();
newT = 2/sqrt( ( 4/EC_L[nP][ipos] + 4/EC_L[nP][ipos_PPM] + 4/EC_L[nPP][ipos] + 4/EC_L[nPP][ipos_PM]) / EC_C[n][ipos] );
if ((newT0.0)) dT=newT;
}
}
}
}
if (dT==0)
{
cerr << "Operator::CalcTimestep: Timestep is zero... this is not supposed to happen!!! exit!" << endl;
exit(3);
}
// cerr << "Operator Timestep: " << dT << endl;
return 0;
}
double min(double* val, unsigned int count)
{
if (count==0)
return 0.0;
double min = val[0];
for (unsigned int n=1;nSetReflection2Cell();
for (int n=0;n<3;++n)
{
int nP = (n+1)%3;
int nPP = (n+2)%3;
for (pos[2]=0;pos[2]ResetShift();
ipos = MainOp->SetPos(pos[0],pos[1],pos[2]);
wqp = 1/(EC_L[nPP][ipos]*EC_C[n][MainOp->GetShiftedPos(nP ,1)]) + 1/(EC_L[nPP][ipos]*EC_C[n][ipos]);
wqp += 1/(EC_L[nP ][ipos]*EC_C[n][MainOp->GetShiftedPos(nPP,1)]) + 1/(EC_L[nP ][ipos]*EC_C[n][ipos]);
ipos = MainOp->Shift(nP,-1);
wqp += 1/(EC_L[nPP][ipos]*EC_C[n][MainOp->GetShiftedPos(nP ,1)]) + 1/(EC_L[nPP][ipos]*EC_C[n][ipos]);
ipos = MainOp->Shift(nPP,-1);
wqp += 1/(EC_L[nP ][ipos]*EC_C[n][MainOp->GetShiftedPos(nPP,1)]) + 1/(EC_L[nP ][ipos]*EC_C[n][ipos]);
MainOp->ResetShift();
ipos = MainOp->SetPos(pos[0],pos[1],pos[2]);
wt_4[0] = 1/(EC_L[nPP][ipos] *EC_C[nP ][ipos]);
wt_4[1] = 1/(EC_L[nPP][MainOp->GetShiftedPos(nP ,-1)] *EC_C[nP ][ipos]);
wt_4[2] = 1/(EC_L[nP ][ipos] *EC_C[nPP][ipos]);
wt_4[3] = 1/(EC_L[nP ][MainOp->GetShiftedPos(nPP,-1)] *EC_C[nPP][ipos]);
wt1 = wt_4[0]+wt_4[1]+wt_4[2]+wt_4[3] - 2*min(wt_4,4);
MainOp->ResetShift();
ipos = MainOp->SetPos(pos[0],pos[1],pos[2]);
wt_4[0] = 1/(EC_L[nPP][ipos] *EC_C[nP ][MainOp->GetShiftedPos(n,1)]);
wt_4[1] = 1/(EC_L[nPP][MainOp->GetShiftedPos(nP ,-1)] *EC_C[nP ][MainOp->GetShiftedPos(n,1)]);
wt_4[2] = 1/(EC_L[nP ][ipos] *EC_C[nPP][MainOp->GetShiftedPos(n,1)]);
wt_4[3] = 1/(EC_L[nP ][MainOp->GetShiftedPos(nPP,-1)] *EC_C[nPP][MainOp->GetShiftedPos(n,1)]);
wt2 = wt_4[0]+wt_4[1]+wt_4[2]+wt_4[3] - 2*min(wt_4,4);
w_total = wqp + wt1 + wt2;
newT = 2/sqrt( w_total );
if ((newT0.0))
dT=newT;
}
}
}
}
if (dT==0)
{
cerr << "Operator::CalcTimestep: Timestep is zero... this is not supposed to happen!!! exit!" << endl;
exit(3);
}
// cerr << "Operator Timestep: " << dT << endl;
return 0;
}
bool Operator::CalcFieldExcitation()
{
if (dT==0)
return false;
if (Exc==0)
return false;
unsigned int pos[3];
double delta[3];
double amp=0;
vector volt_vIndex[3];
vector volt_vExcit;
vector volt_vDelay;
vector volt_vDir;
double volt_coord[3];
vector curr_vIndex[3];
vector curr_vExcit;
vector curr_vDelay;
vector curr_vDir;
double curr_coord[3];
vector vec_prop = CSX->GetPropertyByType(CSProperties::ELECTRODE);
if (vec_prop.size()==0)
{
cerr << "Operator::CalcFieldExcitation: Warning, no excitation properties found" << endl;
return false;
}
CSPropElectrode* elec=NULL;
CSProperties* prop=NULL;
int priority=0;
for (pos[2]=0;pos[2]GetIndexDelta(2,pos[2]));
for (pos[1]=0;pos[1]GetIndexDelta(1,pos[1]));
for (pos[0]=0;pos[0]GetIndexDelta(0,pos[0]));
//electric field excite
for (int n=0;n<3;++n)
{
volt_coord[0] = discLines[0][pos[0]];
volt_coord[1] = discLines[1][pos[1]];
volt_coord[2] = discLines[2][pos[2]];
volt_coord[n]+=delta[n]*0.5;
for (size_t p=0;pToElectrode();
if (prop->CheckCoordInPrimitive(volt_coord,priority)==false)
elec=NULL;
if (elec!=NULL)
{
if ((elec->GetActiveDir(n)) && ( (elec->GetExcitType()==0) || (elec->GetExcitType()==1) ))//&& (pos[n]GetWeightedExcitation(n,volt_coord)*GetMeshDelta(n,pos);// delta[n]*gridDelta;
if (amp!=0)
{
volt_vExcit.push_back(amp);
volt_vDelay.push_back((unsigned int)(elec->GetDelay()/dT));
volt_vDir.push_back(n);
volt_vIndex[0].push_back(pos[0]);
volt_vIndex[1].push_back(pos[1]);
volt_vIndex[2].push_back(pos[2]);
}
if (elec->GetExcitType()==1) //hard excite
{
GetVV(n,pos[0],pos[1],pos[2]) = 0;
GetVI(n,pos[0],pos[1],pos[2]) = 0;
}
}
}
}
}
//magnetic field excite
for (int n=0;n<3;++n)
{
if ((pos[0]>=numLines[0]-1) || (pos[1]>=numLines[1]-1) || (pos[2]>=numLines[2]-1))
continue; //skip the last H-Line which is outside the FDTD-domain
int nP = (n+1)%3;
int nPP = (n+2)%3;
curr_coord[0] = discLines[0][pos[0]];
curr_coord[1] = discLines[1][pos[1]];
curr_coord[2] = discLines[2][pos[2]];
curr_coord[nP] +=delta[nP]*0.5;
curr_coord[nPP] +=delta[nPP]*0.5;
for (size_t p=0;pToElectrode();
if (prop->CheckCoordInPrimitive(curr_coord,priority)==false)
elec=NULL;
if (elec!=NULL)
{
if ((elec->GetActiveDir(n)) && ( (elec->GetExcitType()==2) || (elec->GetExcitType()==3) ))
{
amp = elec->GetWeightedExcitation(n,curr_coord)*GetMeshDelta(n,pos,true);// delta[n]*gridDelta;
if (amp!=0)
{
curr_vExcit.push_back(amp);
curr_vDelay.push_back((unsigned int)(elec->GetDelay()/dT));
curr_vDir.push_back(n);
curr_vIndex[0].push_back(pos[0]);
curr_vIndex[1].push_back(pos[1]);
curr_vIndex[2].push_back(pos[2]);
}
if (elec->GetExcitType()==3) //hard excite
{
GetII(n,pos[0],pos[1],pos[2]) = 0;
GetIV(n,pos[0],pos[1],pos[2]) = 0;
}
}
}
}
}
}
}
}
//special treatment for primitives of type curve (treated as wires) see also Calc_PEC
double p1[3];
double p2[3];
double deltaN=0.0;
struct Grid_Path path;
for (size_t p=0;pToElectrode();
for (size_t n=0;nGetQtyPrimitives();++n)
{
CSPrimitives* prim = prop->GetPrimitive(n);
CSPrimCurve* curv = prim->ToCurve();
if (curv)
{
for (size_t i=1;iGetNumberOfPoints();++i)
{
curv->GetPoint(i-1,p1);
curv->GetPoint(i,p2);
path = FindPath(p1,p2);
if (path.dir.size()>0)
prim->SetPrimitiveUsed(true);
for (size_t t=0;tSetPos(pos[0],pos[1],pos[2]);
deltaN=fabs(MainOp->GetIndexDelta(n,pos[n]));
volt_coord[0] = discLines[0][pos[0]];
volt_coord[1] = discLines[1][pos[1]];
volt_coord[2] = discLines[2][pos[2]];
volt_coord[n] += 0.5*deltaN;
// cerr << n << " " << coord[0] << " " << coord[1] << " " << coord[2] << endl;
if (elec!=NULL)
{
if ((elec->GetActiveDir(n)) && (pos[n]GetExcitType()==0) || (elec->GetExcitType()==1) ))
{
amp = elec->GetWeightedExcitation(n,volt_coord)*deltaN*gridDelta;
if (amp!=0)
{
volt_vExcit.push_back(amp);
volt_vDelay.push_back((unsigned int)(elec->GetDelay()/dT));
volt_vDir.push_back(n);
volt_vIndex[0].push_back(pos[0]);
volt_vIndex[1].push_back(pos[1]);
volt_vIndex[2].push_back(pos[2]);
}
if (elec->GetExcitType()==1) //hard excite
{
GetVV(n,pos[0],pos[1],pos[2]) = 0;
GetVI(n,pos[0],pos[1],pos[2]) = 0;
}
}
}
}
}
}
}
}
// set voltage excitations
Exc->setupVoltageExcitation( volt_vIndex, volt_vExcit, volt_vDelay, volt_vDir );
// set current excitations
Exc->setupCurrentExcitation( curr_vIndex, curr_vExcit, curr_vDelay, curr_vDir );
return true;
}
bool Operator::CalcPEC()
{
m_Nr_PEC[0]=0; m_Nr_PEC[1]=0; m_Nr_PEC[2]=0;
CalcPEC_Range(0,numLines[0]-1,m_Nr_PEC);
CalcPEC_Curves();
return true;
}
void Operator::CalcPEC_Range(unsigned int startX, unsigned int stopX, unsigned int* counter)
{
double coord[3];
double delta;
unsigned int pos[3];
for (pos[0]=startX;pos[0]<=stopX;++pos[0])
{
for (pos[1]=0;pos[1]GetIndexDelta(n,pos[n]);
coord[n]= discLines[n][pos[n]] + delta*0.5;
CSProperties* prop = CSX->GetPropertyByCoordPriority(coord, (CSProperties::PropertyType)(CSProperties::MATERIAL | CSProperties::METAL));
if (prop)
{
if (prop->GetType()==CSProperties::METAL) //set to PEC
{
GetVV(n,pos[0],pos[1],pos[2]) = 0;
GetVI(n,pos[0],pos[1],pos[2]) = 0;
++counter[n];
// cerr << "CartOperator::CalcPEC: PEC found at " << pos[0] << " ; " << pos[1] << " ; " << pos[2] << endl;
}
}
}
}
}
}
}
void Operator::CalcPEC_Curves()
{
//special treatment for primitives of type curve (treated as wires)
double p1[3];
double p2[3];
struct Grid_Path path;
vector vec_prop = CSX->GetPropertyByType(CSProperties::METAL);
for (size_t p=0;pGetQtyPrimitives();++n)
{
CSPrimitives* prim = prop->GetPrimitive(n);
CSPrimCurve* curv = prim->ToCurve();
if (curv)
{
for (size_t i=1;iGetNumberOfPoints();++i)
{
curv->GetPoint(i-1,p1);
curv->GetPoint(i,p2);
path = FindPath(p1,p2);
if (path.dir.size()>0)
prim->SetPrimitiveUsed(true);
for (size_t t=0;t