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- /* This file is part of Lemma, a geophysical modelling and inversion API */
-
- /* This Source Code Form is subject to the terms of the Mozilla Public
- * License, v. 2.0. If a copy of the MPL was not distributed with this
- * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
-
- /**
- @file
- @author M. Andy Kass, Edited Trevor Irons 02/28/2014
- @date 02/10/2011
- @version $Id: instrumenttem.cpp 266 2015-04-01 03:24:00Z tirons $
- **/
- #include "instrumenttem.h"
-
- namespace Lemma {
-
- std::ostream &operator<<(std::ostream &stream,
- const InstrumentTem &ob) {
- stream << *(LemmaObject*)(&ob);
- return stream;
- }
-
- // ======================= Lifecycle ==================================
-
- InstrumentTem::InstrumentTem(const std::string &name) : Instrument(name),
- Antenna(NULL), Receiver(NULL), EarthMod(NULL), Dipole(NULL), bipolarWaveform(true),
- NPreviousPulse(0), RefTime(0.0), PulseT(.06), TxFreq(0.30), RType(INDUCTIVE) {
- }
-
- InstrumentTem::~InstrumentTem() {
- if (NumberOfReferences != 0) {
- throw DeleteObjectWithReferences(this);
- }
-
- if (this->Antenna != NULL) {
- this->Antenna->DetachFrom(this);
- }
-
- if (this->Dipole != NULL) {
- this->Dipole->DetachFrom(this);
- }
-
- if (this->EarthMod != NULL) {
- this->EarthMod->DetachFrom(this);
- }
-
- if (this->Receiver != NULL) {
- this->Receiver->DetachFrom(this);
- }
-
- }
-
- InstrumentTem* InstrumentTem::New() {
- InstrumentTem* Obj = new InstrumentTem("InstrumentTem");
- Obj->AttachTo(Obj);
- return Obj;
- }
-
- void InstrumentTem::Delete() {
- this->DetachFrom(this);
- }
-
- void InstrumentTem::Release() {
- delete this;
- }
-
- // ======================= Operations =================================
- void InstrumentTem::MakeDirectCalculation( const HANKELTRANSFORMTYPE& hType) {
-
- //int temp;
- int NumTimes;
- Real answer;
- EMEarth1D *EMEarthLocal=EMEarth1D::New();
- EMEarthLocal->AttachLayeredEarthEM(this->EarthMod);
-
- //DigitalFilterCosTrans *DFIntegrate=DigitalFilterCosTrans::New();
- DigitalFilterSinTrans *DFIntegrate=DigitalFilterSinTrans::New();
-
- TemIntegrationKernel *TEMIntKern=TemIntegrationKernel::New();
- TEMIntKern->SetEMEarth1D(EMEarthLocal);
- //TEMIntKern->SetTransmitter(this->Antenna);
- TEMIntKern->SetReceiver(this->Receiver);
- DFIntegrate->AttachKernel(TEMIntKern);
-
- if (this->Dipole != NULL) { //AND this->Antenna == NULL
- EMEarthLocal->AttachDipoleSource(this->Dipole);
- TEMIntKern->SetDipole(this->Dipole);
- }
- if (this->Antenna != NULL) { //AND this->Dipole == NULL
- EMEarthLocal->AttachWireAntenna(this->Antenna);
- TEMIntKern->SetTransmitter(this->Antenna);
- }
- EMEarthLocal->SetFieldsToCalculate(H);
- //EMEarthLocal->SetHankelTransformMethod(DIGITALFILTERING);
- //EMEarthLocal->SetHankelTransformMethod(FHTKEY201);
- EMEarthLocal->SetHankelTransformMethod(hType);
- //EMEarthLocal->SetHankelTransformMethod(GAUSSIANQUADRATURE);
-
- //EMEarthLocal->AttachReceiverPoints(this->Receiver);
- // For testing with one time only
- //DFIntegrate->Compute(1,1,1e-16);
- //std::cout<<DFIntegrate->GetAnswer()<<std::endl;
- //
- NumTimes = this->TimeGates.size();
- //Testing
- //std::cout << "NumTimes: " << NumTimes << std::endl;
- this->ModelledData.resize(NumTimes,2);
- for (int ii=0;ii<NumTimes;ii++) {
- //TESTING!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
- //RELAXING THE VALUE!
- DFIntegrate->Compute(this->TimeGates(ii), 1, 1e-7);
- //Testing
- //std::cout << "DFIntegrate done computing" << std::endl;
- answer = DFIntegrate->GetAnswer()(0);
- answer = (2./PI)*answer;
- this->ModelledData(ii,0) = this->TimeGates(ii);
- this->ModelledData(ii,1) = answer;
- //std::cout << " " << TimeGates(ii) << " " <<
- // answer << std::endl;
- //std::cout << " " << this->ModelledData(ii,0) << " " <<
- // this->ModelledData(ii,1) << std::endl;
- // Call cosine transform which calls argument
- }
- //
- TEMIntKern->Delete();
- EMEarthLocal->Delete();
- DFIntegrate->Delete();
-
- }
-
- void InstrumentTem::MakeLaggedCalculation(const HANKELTRANSFORMTYPE& hType) {
-
- EMEarth1D *EMEarthLocal=EMEarth1D::New();
- EMEarthLocal->AttachLayeredEarthEM(this->EarthMod);
- EMEarthLocal->SetFieldsToCalculate(H);
- EMEarthLocal->SetHankelTransformMethod(hType);
- EMEarthLocal->AttachReceiverPoints(this->Receiver);
-
- TemIntegrationKernel *TEMIntKern=TemIntegrationKernel::New();
-
- TEMIntKern->SetReceiver(this->Receiver);
- TEMIntKern->SetEMEarth1D(EMEarthLocal);
-
-
- if (this->Dipole != NULL) { //AND this->Antenna == NULL
- EMEarthLocal->AttachDipoleSource(this->Dipole);
- TEMIntKern->SetDipole(this->Dipole);
- Dipole->SetNumberOfFrequencies(1);
- }
- if (this->Antenna != NULL) { //AND this->Dipole == NULL
- EMEarthLocal->AttachWireAntenna(this->Antenna);
- Antenna->SetCurrent(1);
- TEMIntKern->SetTransmitter(this->Antenna);
- Antenna->SetNumberOfFrequencies(1);
- }
-
-
- // TODO IMPORTANT!!
- // Compute number of lagged convolutions to do, TODO, need to make sure we do these
- // TO THE LATEST time needed for multiple pulse subtraction!!!
- int ilag = 1;
- Real sub = 2.1*PulseT + 2.*NPreviousPulse*PulseT;
- if (!bipolarWaveform) sub = NPreviousPulse*PulseT;
-
- //TimeGates.array() += RefTime;
- //RefTime = 0;
-
- // This is a critical line, for reasons I don't understand, it's important to calculate past the
- // theoretical GateWidths(0)/2.
- while ( (TimeGates.tail(1)(0)+sub)*std::pow(1./exp(.1), ilag-1) > TimeGates(0)-GateWidths(0) ) ++ ilag;
-
- //DigitalFilterSinTrans *DFIntegrate=DigitalFilterSinTrans::New(); // use with step response kernel
- DigitalFilterCosTrans *DFIntegrate=DigitalFilterCosTrans::New(); // use with impulse response kernel
- DFIntegrate->AttachKernel(TEMIntKern);
- DFIntegrate->SetNumConv(ilag);
- DFIntegrate->Compute( this->TimeGates.tail(1)(0)+sub, 1, 1e-7 ); // rho ntol, tol=1e-7 to 1e-13
-
- CubicSplineInterpolator *Spline = CubicSplineInterpolator::New();
- //Spline->SetKnots( DFIntegrate->GetAbscissaArguments().array(), (2./PI) * DFIntegrate->GetAnswer().col(0).array() );
- Spline->SetKnots( DFIntegrate->GetAbscissaArguments().array(), (.25/PI) * DFIntegrate->GetAnswer().col(0).array() );
-
-
- this->ModelledData.resize(TimeGates.size(), 2);
- this->ModelledData.col(0) = TimeGates;
- this->ModelledData.col(1).setZero();
-
- // This is non-extrapolated times and values
- //this->ModelledData.resize(ilag, 2);
- // this->ModelledData.col(0) = DFIntegrate->GetAbscissaArguments(); // this->TimeGates(ii);
- // this->ModelledData.col(1) = (2./PI)*DFIntegrate->GetAnswer();
- //std::cout << (2./PI)*DFIntegrate->GetAnswer().transpose() << std::endl;
-
- // Take into account receiver gate integration and tx waveform
- FoldAndConvolve(Spline);
-
- // Direct caclulation, step response to use need re reset temintegrationkernel back to step!
- // this->ModelledData.col(1) = (2./PI)*Spline->InterpolateOrderedSet( TimeGates );
-
- Spline->Delete();
- TEMIntKern->Delete();
- EMEarthLocal->Delete();
- DFIntegrate->Delete();
-
- }
-
- // ======================= Access =====================================
-
- void InstrumentTem::SetPulse( const VectorXr& Amp, const VectorXr& times, bool bipolar ) {
-
- bipolarWaveform = bipolar;
- assert(Amp.size() == times.size());
-
- TxAmp = Amp;
- TxAbs = times;
-
- TxDiff = VectorXr::Zero(TxAmp.size());
- TxDelta = VectorXr::Zero(TxAmp.size());
-
- for (int ip=1; ip<TxAmp.size(); ++ ip) {
- TxDiff(ip) = (TxAmp(ip-1)-TxAmp(ip )) /
- (TxAbs(ip )-TxAbs(ip-1)) ;
- TxDelta(ip) = (TxAmp(ip-1)-TxAmp(ip )) ;
- }
-
- /*
- std::cout << "diff " << TxDiff.transpose() << std::endl;
- std::cout << "delta " << TxDelta.transpose() << std::endl;
- std::cout << "amp " << TxAmp.transpose() << std::endl;
- std::cout << "abs " << TxAbs.transpose() << std::endl;
- */
- }
-
- void InstrumentTem::EMEarthModel(LayeredEarthEM* Earth) {
- if (this->EarthMod != NULL) {
- this->EarthMod->DetachFrom(this);
- }
- //std::cout << "InstrumentTem: EarthMod null test" << std::endl;
- Earth->AttachTo(this);
- //std::cout << "InstrumentTem: EarthMod attached" << std::endl;
- this->EarthMod = Earth;
- //std::cout << "InstrumentTem: EMEarthModel Attached" << std::endl;
-
- }
-
- void InstrumentTem::SetTransmitLoop(WireAntenna *antennae) {
- if (this->Antenna != NULL) {
- this->Antenna->DetachFrom(this);
- }
- antennae->AttachTo(this);
- this->Antenna = antennae;
- if (this->Dipole != NULL) {
- this->Dipole->DetachFrom(this);
- }
- //std::cout << "InstrumentTem: TransmitLoop Attached" << std::endl;
-
- }
-
- void InstrumentTem::SetDipoleSource(DipoleSource* dipolesource) {
- if (this->Dipole != NULL) {
- this->Dipole->DetachFrom(this);
- }
- dipolesource->AttachTo(this);
- this->Dipole = dipolesource;
- if (this->Antenna != NULL) {
- this->Antenna->DetachFrom(this);
- }
- }
-
- void InstrumentTem::SetReceiver(ReceiverPoints* Receivers) {
- if (this->Receiver != NULL) {
- this->Receiver->DetachFrom(this);
- }
- Receivers->AttachTo(this);
- this->Receiver = Receivers;
- //std::cout << "InstrumentTem: Receivers Attached" << std::endl;
-
- }
-
- void InstrumentTem::SetTimes(const VectorXr ×) {
- this->TimeGates = times;
- }
-
-
- //--------------------------------------------------------------------------------------
- // Class: InstrumentTem
- // Method: SetReceiverType
- //--------------------------------------------------------------------------------------
- void InstrumentTem::SetReceiverType ( const ReceiverType& rt ) {
- RType = rt;
- return ;
- } // ----- end of method InstrumentTem::SetReceiverType -----
-
-
- //--------------------------------------------------------------------------------------
- // Class: InstrumentTEM
- // Method: SetTimeGates
- //--------------------------------------------------------------------------------------
- void InstrumentTem::SetTimeGates ( const VectorXr ¢res, const VectorXr& widths ) {
- assert (centres.size() == widths.size());
- TimeGates = centres;
- GateWidths = widths;
- return ;
- } // ----- end of method InstrumentTEM::SetTimeGates -----
-
-
-
-
- int InstrumentTem::GetNumberOfTimes() {
-
- return this->TimeGates.size();
- }
-
- MatrixXr InstrumentTem::GetMeasurements() {
-
- return this->ModelledData;
- }
-
-
-
- //--------------------------------------------------------------------------------------
- // Class: InstrumentTem
- // Method: SetReferenceTime
- //--------------------------------------------------------------------------------------
- void InstrumentTem::SetReferenceTime ( const Real& rtime ) {
- RefTime = rtime;
- return ;
- } // ----- end of method InstrumentTem::SetReferenceTime -----
-
-
-
- //--------------------------------------------------------------------------------------
- // Class: InstrumentTem
- // Method: FoldAndConvolve
- //--------------------------------------------------------------------------------------
- void InstrumentTem::FoldAndConvolve ( CubicSplineInterpolator* Spline ) {
-
- const static Real GLW[3] = {.5555556, .8888889, .5555556};
- const static Real GLX[3] = {-.7745967, 0., .7745967};
-
- // TODO BUG check against LEROI!!!
- //SubtractPrevious(Spline);
-
-
- switch (RType) {
- case INDUCTIVE:
- // Differentiate to compute impulse response for step input
- // Iterate over time gate
- for (int ig=0; ig<TimeGates.size(); ++ig) {
- this->ModelledData.col(1)[ig] =
- ( ( ConvolveWaveform(Spline, RefTime + TimeGates[ig] - GateWidths[ig]/2.) -
- ConvolveWaveform(Spline, RefTime + TimeGates[ig] + GateWidths[ig]/2.) ) / GateWidths[ig]);
- }
- break;
-
- case MAGNETOMETER:
- for (int ig=0; ig<TimeGates.size(); ++ig) {
- /*
- TC(2) = (TCLS(JT) + TOPN(JT)) / 2.
- TC(1) = TC(2) + HWIDTH * GLX(1)
- TC(3) = TC(2) + HWIDTH * GLX(3)
- */
- this->ModelledData.col(1)[ig] = 0;
- for (int ii=0; ii<3; ++ii) {
- //Real tt = RefTime + TimeGates[ig] + GLX[ii]*(GateWidths[ig]/2.);
- Real tt = RefTime + TimeGates[ig] + GLX[ii]*(GateWidths[ig]/2.);
- this->ModelledData.col(1)[ig] += ConvolveWaveform(Spline, tt) * GLW[ii]/2.;
- }
- }
- break;
-
- case ELECTRIC:
- throw std::runtime_error("InstrumentTEM->FoldAndConvolve with Electic Receivers is not implimented");
- break;
- }
-
- return ;
- } // ----- end of method InstrumentTem::FoldAndConvolve -----
-
-
- //--------------------------------------------------------------------------------------
- // Class: InstrumentTem
- // Method: ConvolveWaveform
- //--------------------------------------------------------------------------------------
- Real InstrumentTem::ConvolveWaveform ( CubicSplineInterpolator* Spline, const Real& t ) {
- static const Real T0MIN = 1e-7;
- Real cnv(0);
- Real tf = t - Spline->GetKnotAbscissa()[0];
- bool der = false;
- Real tend(0);
- for (int ip=1; ip<TxAmp.size(); ++ip) {
- if (TxAbs(ip) < T0MIN) continue;
- if (TxAbs(ip-1) > tf) break;
-
- Real tb = t - std::min(tf, TxAbs(ip));
- Real delt = TxAbs(ip) - TxAbs(ip-1);
-
- der = false;
- if (delt > T0MIN) {
- tend = t - TxAbs(ip-1);
- der = true;
- }
-
- if (der) {
- //std::cout.precision(16);
- // TODO Integrate seems to be kind of screwy!! Affecting early/on times
- cnv += TxDiff(ip) * Spline->Integrate(tb, tend, 41200); //CUBINT (TRP,YPLS,NTYPLS,TB,TEND)
- // TODO bug in direct spline integration, works sometimes
- //cnv += TxDiff(ip) * Spline->Integrate(tb, tend);
- //cnv += Spline->Integrate(tb, tend, 6264); //CUBINT (TRP,YPLS,NTYPLS,TB,TEND)
- //Real temp = Spline->Integrate(tb, tend, 10036); //CUBINT (TRP,YPLS,NTYPLS,TB,TEND)
- //Real temp2 = Spline->Integrate(tb, tend); //CUBINT (TRP,YPLS,NTYPLS,TB,TEND)
- //std::cout << "der " << TxDiff(ip) << "\t" << std::scientific << tb << "\t" << tend << "\t" << MU0*temp2 << "\t" << MU0*temp << "\n";
- //cnv += temp;
- } else {
- cnv += TxDelta(ip) * Spline->Interpolate(tb); //CUBVAL (TRP,YPLS,NTYPLS,TB)
- }
- }
- return cnv;
-
- } // ----- end of method InstrumentTem::ConvolveWaveform -----
-
-
- //--------------------------------------------------------------------------------------
- // Class: InstrumentTem
- // Method: SubtractPrevious
- //--------------------------------------------------------------------------------------
- void InstrumentTem::SubtractPrevious ( CubicSplineInterpolator *Spline ) {
- // Start by calculating impulse response of this pulse plus any arbitrary number of previous pulses at this
- // repetition frequency
- VectorXr aTimeGates = Spline->GetKnotAbscissa();
- Real pol (1.);
- if (bipolarWaveform) pol = -1.;
- VectorXr PrevPulse = aTimeGates.array() + PulseT;
- // TODO, if not bipolar what does convention say, is this added or should this be zero and handled only by nPreviousPulse?
- VectorXr Fold = Spline->GetKnotOrdinate( ); // +
- //VectorXr Fold = pol*Spline->InterpolateOrderedSet( PrevPulse ) ;
- VectorXr PrevPulse1; // = PrevPulse.array(); // + PulseT;
- for (int ip=0; ip<NPreviousPulse; ++ip) {
- PrevPulse1.array() += PrevPulse.array() + PulseT;
- PrevPulse.array() += PrevPulse1.array() + PulseT;
- Fold += Spline->InterpolateOrderedSet( PrevPulse1 ) + pol*Spline->InterpolateOrderedSet( PrevPulse ) ;
- }
- Spline->ResetKnotOrdinate(Fold);
- return ;
- } // ----- end of method InstrumentTem::SubtractPrevious -----
-
-
-
- } // namespace Lemma
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