added Curve for excitation and dump excitation in operator-dump
Thorsten Liebig
parent
98f72a855e
commit
ea2823377d
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@ -106,7 +106,7 @@ bool Operator::SnapToMesh(double* dcoord, unsigned int* uicoord, bool lower)
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else if (dcoord[n]>discLines[n][numLines[n]-1]) {ok=false;uicoord[n]=numLines[n]-1; if (lower) uicoord[n]=numLines[n]-2;}
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else if (dcoord[n]==discLines[n][numLines[n]-1]) {uicoord[n]=numLines[n]-1; if (lower) uicoord[n]=numLines[n]-2;}
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else
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for (unsigned int i=1;i<numLines[n]-1;++i)
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for (unsigned int i=1;i<numLines[n];++i)
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{
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if (dcoord[n]<discLines[n][i])
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{
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@ -224,9 +224,9 @@ void Operator::ShowSize()
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cout << "-----------------------------" << endl;
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}
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void Operator::CalcGaussianPulsExcitation(double f0, double fc)
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bool Operator::CalcGaussianPulsExcitation(double f0, double fc)
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{
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if (dT==0) return;
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if (dT==0) return false;
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ExciteLength = (unsigned int)(2.0 * 9.0/(2.0*PI*fc) / dT);
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cerr << "Operator::CalcGaussianPulsExcitation: Length of the excite signal: " << ExciteLength << " timesteps" << endl;
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@ -238,14 +238,16 @@ void Operator::CalcGaussianPulsExcitation(double f0, double fc)
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ExciteSignal[n] = cos(2.0*PI*f0*(n*dT-9.0/(2.0*PI*fc)))*exp(-1*pow(2.0*PI*fc*n*dT/3.0-3,2));
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// cerr << ExciteSignal[n] << endl;
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}
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return true;
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}
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void Operator::CalcSinusExcitation(double f0, int nTS)
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bool Operator::CalcSinusExcitation(double f0, int nTS)
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{
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if (dT==0) return;
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if (nTS<=0) return;
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if (dT==0) return false;
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if (nTS<=0) return false;
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ExciteLength = (unsigned int)(nTS);
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cerr << "Operator::CalcSinusExcitation: Length of the excite signal: " << ExciteLength << " timesteps" << endl;
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delete[] ExciteSignal;
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ExciteSignal = new FDTD_FLOAT[ExciteLength+1];
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ExciteSignal[0]=0.0;
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@ -254,6 +256,7 @@ void Operator::CalcSinusExcitation(double f0, int nTS)
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ExciteSignal[n] = sin(2.0*PI*f0*n*dT);
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// cerr << ExciteSignal[n] << endl;
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}
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return true;
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}
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void Operator::DumpOperator2File(string filename)
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@ -266,10 +269,18 @@ void Operator::DumpOperator2File(string filename)
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return;
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}
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string names[] = {"vv", "vi", "iv" , "ii"};
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FDTD_FLOAT**** array[] = {vv,vi,iv,ii};
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FDTD_FLOAT**** exc = Create_N_3DArray(numLines);
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for (unsigned int n=0;n<E_Exc_Count;++n)
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{
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exc[E_Exc_dir[n]][E_Exc_index[0][n]][E_Exc_index[1][n]][E_Exc_index[2][n]] = E_Exc_amp[n];
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}
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ProcessFields::DumpMultiVectorArray2VTK(file, names , array , 4, discLines, numLines);
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string names[] = {"vv", "vi", "iv" , "ii", "exc"};
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FDTD_FLOAT**** array[] = {vv,vi,iv,ii,exc};
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ProcessFields::DumpMultiVectorArray2VTK(file, names , array , 5, discLines, numLines);
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Delete_N_3DArray(exc,numLines);
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file.close();
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}
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@ -774,6 +785,70 @@ bool Operator::CalcEFieldExcitation()
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}
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}
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//special treatment for primitives of type curve (treated as wires) see also Calc_PEC
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double p1[3];
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double p2[3];
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double deltaN=0.0;
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int n;
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struct Grid_Path path;
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CSPropElectrode* elec=NULL;
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CSProperties* prop=NULL;
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vector<CSProperties*> vec_prop = CSX->GetPropertyByType(CSProperties::ELECTRODE);
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for (size_t p=0;p<vec_prop.size();++p)
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{
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prop = vec_prop.at(p);
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elec = prop->ToElectrode();
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for (size_t n=0;n<prop->GetQtyPrimitives();++n)
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{
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CSPrimitives* prim = prop->GetPrimitive(n);
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CSPrimCurve* curv = prim->ToCurve();
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if (curv)
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{
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for (size_t i=1;i<curv->GetNumberOfPoints();++i)
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{
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curv->GetPoint(i-1,p1);
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curv->GetPoint(i,p2);
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path = FindPath(p1,p2);
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for (size_t t=0;t<path.dir.size();++t)
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{
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n = path.dir.at(t);
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pos[0] = path.posPath[0].at(t);
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pos[1] = path.posPath[1].at(t);
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pos[2] = path.posPath[2].at(t);
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MainOp->SetPos(pos[0],pos[1],pos[2]);
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deltaN=fabs(MainOp->GetIndexDelta(n,pos[n]));
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coord[0] = discLines[0][pos[0]];
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coord[1] = discLines[1][pos[1]];
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coord[2] = discLines[2][pos[2]];
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coord[n] += 0.5*deltaN;
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// cerr << n << " " << coord[0] << " " << coord[1] << " " << coord[2] << endl;
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if (elec!=NULL)
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{
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if ((elec->GetActiveDir(n)) && (pos[n]<(int)numLines[n]-1))
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{
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amp = elec->GetWeightedExcitation(n,coord)*deltaN*gridDelta;
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if (amp!=0)
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{
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vExcit.push_back(amp);
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vDelay.push_back((unsigned int)(elec->GetDelay()/dT));
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vDir.push_back(n);
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vIndex[0].push_back(pos[0]);
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vIndex[1].push_back(pos[1]);
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vIndex[2].push_back(pos[2]);
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}
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if (elec->GetExcitType()==1) //hard excite
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{
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vv[n][pos[0]][pos[1]][pos[2]] = 0;
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vi[n][pos[0]][pos[1]][pos[2]] = 0;
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}
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}
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}
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}
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}
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}
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}
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}
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E_Exc_Count = vExcit.size();
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cerr << "Operator::CalcEFieldExcitation: Found number of excitations points: " << E_Exc_Count << endl;
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if (E_Exc_Count==0)
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@ -38,9 +38,9 @@ public:
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virtual int CalcECOperator();
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//! Calculate an excitation with center of f0 and the half bandwidth fc
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virtual void CalcGaussianPulsExcitation(double f0, double fc);
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virtual bool CalcGaussianPulsExcitation(double f0, double fc);
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//! Calculate a sinusoidal excitation with frequency f0 and a duration of nTS number of timesteps
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virtual void CalcSinusExcitation(double f0, int nTS);
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virtual bool CalcSinusExcitation(double f0, int nTS);
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virtual void ApplyElectricBC(bool* dirs); //applied by default to all boundaries
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virtual void ApplyMagneticBC(bool* dirs);
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33
openems.cpp
33
openems.cpp
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@ -185,26 +185,39 @@ int openEMS::SetupFDTD(const char* file)
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FDTD_Op = new Operator();
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if (FDTD_Op->SetGeometryCSX(&CSX)==false) return(-1);
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if (DebugMat)
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{
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FDTD_Op->DumpMaterial2File("material_dump.vtk");
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}
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FDTD_Op->CalcECOperator();
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if (DebugOp)
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{
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FDTD_Op->DumpOperator2File("operator_dump.vtk");
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}
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if (Excit_Type==0)
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FDTD_Op->CalcGaussianPulsExcitation(f0,fc);
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{
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if (!FDTD_Op->CalcGaussianPulsExcitation(f0,fc))
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{
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cerr << "openEMS: excitation setup failed!!" << endl;
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exit(2);
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}
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}
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else if (Excit_Type==1)
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FDTD_Op->CalcSinusExcitation(f0,NrTS);
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{
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if (!FDTD_Op->CalcSinusExcitation(f0,NrTS))
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{
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cerr << "openEMS: excitation setup failed!!" << endl;
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exit(2);
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}
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}
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else
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{
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cerr << "openEMS: Excitation type is unknown" << endl;
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exit(-1);
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}
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if (DebugMat)
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{
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FDTD_Op->DumpMaterial2File("material_dump.vtk");
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}
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if (DebugOp)
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{
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FDTD_Op->DumpOperator2File("operator_dump.vtk");
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}
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time_t OpDoneTime=time(NULL);
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FDTD_Op->ShowSize();
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