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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 Trevor Irons
- @date 12/02/2009
- @version $Id: emearth1d.cpp 270 2015-08-24 15:45:41Z tirons $
- **/
-
- #include "emearth1d.h"
-
- #ifdef LEMMAUSEOMP
- #include "omp.h"
- #endif
-
- namespace Lemma {
-
- #ifdef HAVE_YAMLCPP
- std::ostream &operator << (std::ostream &stream, const EMEarth1D &ob) {
- stream << ob.Serialize() << "\n---\n"; // End of doc --- as a direct stream should encapulste thingy
- return stream;
- }
- #else
- std::ostream &operator<<(std::ostream &stream, const
- EMEarth1D &ob) {
-
- stream << *(LemmaObject*)(&ob);
- stream << "Dipole source address: " << ob.Dipole << std::endl;
- stream << "Wire antenna address: " << ob.Antenna << std::endl;
- stream << *ob.Earth << std::endl;
- stream << *ob.Receivers;
- return stream;
- }
- #endif
-
- #ifdef KIHALEE_EM1D
- // Wrapper function for Fortran subroutine Em1D bi kihand
- // Returns E or H fields (SLOW)
- extern "C" { void em1dcall_(int &itype, // source
- int &ipol, // source
- int &nlay, // Earth
- int &nfreq, // source
- int &nfield, // Calculator
- int &nres, // Receivers
- int &jtype, // N/A
- int &jgamma, // Controller
- double &acc, // Controller
- double *dep, // Earth
- std::complex<double> *sig, // Earth
- double *susl, // Earth
- double *sush, // Earth
- double *sustau, // Earth
- double *susalp, // Earth
- double *eprl, // Earth
- double *eprh, // Earth
- double *eprtau, // Earth
- double *epralp, // Earth
- double &finit, // N/A
- double &flimit, // N/A
- double &dlimit, // N/A
- double &lfinc, // N/A
- double &tx, // Source
- double &ty, // Source
- double &tz, // Source
- double *rxx, // Receivers
- double *rxy, // Receivers
- double *rxz, // Receivers
- std::complex<double> *ex, // Receivers
- std::complex<double> *ey, // |
- std::complex<double> *ez, // |
- std::complex<double> *hx, // |
- std::complex<double> *hy, // V
- std::complex<double> *hz ); // ___
- }
- #endif
-
- // ==================== LIFECYCLE ===================================
-
- // TODO init large arrays here.
- EMEarth1D::EMEarth1D(const std::string& name) : LemmaObject(name),
- Dipole(nullptr), Earth(nullptr), Receivers(nullptr), Antenna(nullptr),
- FieldsToCalculate(BOTH), HankelType(ANDERSON801), icalcinner(0), icalc(0)
- //#ifdef HAVEBOOSTPROGRESS
- // , disp(0)
- //#endif
- {
- }
-
- EMEarth1D::~EMEarth1D() {
- if (this->NumberOfReferences > 0)
- throw DeleteObjectWithReferences( this );
- DetachAll();
- }
-
- EMEarth1D* EMEarth1D::New() {
- EMEarth1D * Obj = new EMEarth1D("EmEarth1D");
- Obj->AttachTo(Obj);
- return Obj;
- }
-
- void EMEarth1D::Delete() {
- this->DetachFrom(this);
- }
-
- void EMEarth1D::Release() {
- DetachAll();
- delete this;
- }
-
- #ifdef HAVE_YAMLCPP
- YAML::Node EMEarth1D::Serialize() const {
- YAML::Node node = LemmaObject::Serialize();
-
- node["FieldsToCalculate"] = enum2String(FieldsToCalculate);
- node["HankelType"] = enum2String(HankelType);
-
- //if (Dipole != NULL) node["Dipole"] = Dipole->Serialize();
- if (Earth != NULL) node["Earth"] = Earth->Serialize();
- //if (Receivers != NULL) node["Receivers"] = Receivers->Serialize(); Can be huge?
- if (Antenna != NULL) node["Antenna"] = Antenna->Serialize();
-
- node.SetTag( this->Name );
-
- return node;
- }
- #endif
-
- // ==================== ACCESS ===================================
- void EMEarth1D::AttachDipoleSource(DipoleSource *dipoleptr) {
- if (this->Dipole != NULL) {
- this->Dipole->DetachFrom(this);
- }
- dipoleptr->AttachTo(this);
- this->Dipole = dipoleptr;
- }
-
- void EMEarth1D::AttachLayeredEarthEM(LayeredEarthEM *earthptr) {
- if (this->Earth != NULL)
- this->Earth->DetachFrom(this);
- earthptr->AttachTo(this);
- this->Earth = earthptr;
- }
-
- void EMEarth1D::AttachReceiverPoints(ReceiverPoints *recptr) {
- if (this->Receivers != NULL) {
- this->Receivers->DetachFrom(this);
- }
-
- recptr->AttachTo(this);
- this->Receivers = recptr;
-
- if (Receivers == NULL) {
- std::cout << "NULL Receivers in emearth1d.cpp " << std::endl;
- return;
- }
-
- if (Dipole != NULL) {
- switch (FieldsToCalculate) {
- case E:
- Receivers->SetNumberOfBinsE(Dipole->GetNumberOfFrequencies());
- break;
- case H:
- Receivers->SetNumberOfBinsH(Dipole->GetNumberOfFrequencies());
- break;
- case BOTH:
- Receivers->SetNumberOfBinsE(Dipole->GetNumberOfFrequencies());
- Receivers->SetNumberOfBinsH(Dipole->GetNumberOfFrequencies());
- break;
- }
- } else if (Antenna != NULL) {
- switch (FieldsToCalculate) {
- case E:
- Receivers->SetNumberOfBinsE(Antenna->GetNumberOfFrequencies());
- break;
- case H:
- Receivers->SetNumberOfBinsH(Antenna->GetNumberOfFrequencies());
- break;
- case BOTH:
- Receivers->SetNumberOfBinsE(Antenna->GetNumberOfFrequencies());
- Receivers->SetNumberOfBinsH(Antenna->GetNumberOfFrequencies());
- break;
- }
-
- }
-
- }
-
- void EMEarth1D::AttachWireAntenna(WireAntenna *antennae) {
- if (this->Antenna != NULL) {
- this->Antenna->DetachFrom(this);
- }
- antennae->AttachTo(this);
- this->Antenna = antennae;
- }
-
- void EMEarth1D::SetFieldsToCalculate(const FIELDCALCULATIONS &calc) {
- FieldsToCalculate = calc;
- }
-
- void EMEarth1D::SetHankelTransformMethod( const HANKELTRANSFORMTYPE &type) {
- HankelType = type;
- }
-
- void EMEarth1D::Query() {
- std::cout << "EmEarth1D::Query()" << std::endl;
-
- std::cout << "Dipole " << Dipole;
- if (Dipole) std::cout << *Dipole << std::endl;
-
- std::cout << "Earth " << Earth;
- if (Earth) std::cout << *Earth << std::endl;
-
- std::cout << "Receivers " << Earth;
- if (Earth) std::cout << *Receivers << std::endl;
-
- std::cout << "Antenna " << Earth;
- if (Antenna) std::cout << *Antenna << std::endl;
-
- std::cout << "icalc " << icalc << std::endl;
-
- std::cout << "icalcinner " << icalcinner << std::endl;
- }
-
- // ==================== OPERATIONS ===================================
- void EMEarth1D::DetachAll() {
-
- if (this->Dipole != NULL){
- this->Dipole->DetachFrom(this);
- }
- Dipole = NULL;
-
- if (this->Receivers != NULL){
- this->Receivers->DetachFrom(this);
- }
- Receivers = NULL;
-
- if (this->Earth != NULL){
- this->Earth->DetachFrom(this);
- }
- Earth = NULL;
-
- if (this->Antenna != NULL){
- this->Antenna->DetachFrom(this);
- }
- Antenna = NULL;
- }
-
- void EMEarth1D::CalculateWireAntennaFields(bool progressbar) {
-
- #ifdef HAVEBOOSTPROGRESS
- boost::progress_display *disp;
- #endif
-
- if (Earth == NULL) {
- throw NullEarth();
- }
- if (Receivers == NULL) {
- throw NullReceivers();
- }
- if (Antenna == NULL) {
- throw NullAntenna();
- }
- if (Dipole != NULL) {
- throw DipoleSourceSpecifiedForWireAntennaCalc();
- }
-
- Receivers->ClearFields();
-
- // Check to make sure Receivers are set up for all calculations
- switch(FieldsToCalculate) {
- case E:
- if (Receivers->NumberOfBinsE != Antenna->GetNumberOfFrequencies())
- Receivers->SetNumberOfBinsE(Antenna->GetNumberOfFrequencies());
- break;
- case H:
- if (Receivers->NumberOfBinsH != Antenna->GetNumberOfFrequencies())
- Receivers->SetNumberOfBinsH(Antenna->GetNumberOfFrequencies());
- break;
- case BOTH:
- if (Receivers->NumberOfBinsH != Antenna->GetNumberOfFrequencies())
- Receivers->SetNumberOfBinsH(Antenna->GetNumberOfFrequencies());
- if (Receivers->NumberOfBinsE != Antenna->GetNumberOfFrequencies())
- Receivers->SetNumberOfBinsE(Antenna->GetNumberOfFrequencies());
- break;
- }
-
- if (Antenna->GetName() == std::string("PolygonalWireAntenna") || Antenna->GetName() == std::string("TEMTransmitter") ) {
-
- icalc += 1;
-
- // Check to see if they are all on a plane? If so we can do this fast
- /* TODO FIX THIS ISSUES */
- if (Antenna->IsHorizontallyPlanar() && HankelType == ANDERSON801) {
- //std::cout << "Lag baby lag" << std::endl;
- for (int ifreq=0; ifreq<Antenna->GetNumberOfFrequencies();++ifreq) {
- //std::cout << "Num Recs" << Receivers->GetNumberOfReceivers() << std::endl;
- Real wavef = 2.*PI* Antenna->GetFrequency(ifreq);
- #ifdef LEMMAUSEOMP
- #pragma omp parallel
- {
- #endif
- Hankel2* Hankel = Hankel2::New();
- #ifdef LEMMAUSEOMP
- #pragma omp for schedule(static, 1)
- #endif
- for (int irec=0; irec<Receivers->GetNumberOfReceivers(); ++irec) {
- //for (int irec=0; irec<2; ++irec) { // TODO FIXME BELO
- PolygonalWireAntenna *AntCopy = static_cast<PolygonalWireAntenna*>(this->Antenna)->Clone();
- SolveLaggedTxRxPair(irec, Hankel, wavef, ifreq, AntCopy);
- AntCopy->Delete();
- //exit(0);
- }
- //Receivers->ClearFields(); // FIXME DEBUG TODO
- Hankel->Delete();
- #ifdef LEMMAUSEOMP
- }
- #endif
- }
- } else
- if (Receivers->GetNumberOfReceivers() > Antenna->GetNumberOfFrequencies()) {
-
- //std::cout << "freq parallel #1" << std::endl;
- //** Progress display bar for long calculations */
- #ifdef HAVEBOOSTPROGRESS
- if (progressbar) {
- disp = new boost::progress_display( Receivers->GetNumberOfReceivers()*Antenna->GetNumberOfFrequencies() );
- }
- #endif
-
- // parallelise across receivers
- #ifdef LEMMAUSEOMP
- #pragma omp parallel
- #endif
- { // OpenMP Parallel Block
- // Since these antennas change we need a local copy for each
- // thread.
- PolygonalWireAntenna *AntCopy =
- static_cast<PolygonalWireAntenna*>(this->Antenna)->Clone();
-
- HankelTransform* Hankel;
- switch (HankelType) {
- case ANDERSON801:
- Hankel = Hankel2::New();
- break;
- case CHAVE:
- Hankel = HankelTransformGaussianQuadrature::New();
- break;
- case FHTKEY201:
- Hankel = FHTKey::New();
- break;
- case FHTKEY101:
- Hankel = FHTKey101::New();
- break;
- case FHTKEY51:
- Hankel = FHTKey51::New();
- break;
- case QWEKEY:
- Hankel = QWEKey::New();
- break;
- default:
- std::cerr << "Hankel transform cannot be created\n";
- exit(EXIT_FAILURE);
- }
-
- //for (int irec=tid; irec<Receivers->GetNumberOfReceivers(); irec+=nthreads) {
- #ifdef LEMMAUSEOMP
- #pragma omp for schedule(static, 1) //nowait
- #endif
- for (int irec=0; irec<Receivers->GetNumberOfReceivers(); ++irec) {
- if (!Receivers->GetMask(irec)) {
- AntCopy->ApproximateWithElectricDipoles(Receivers->GetLocation(irec));
- for (int idip=0; idip<AntCopy->GetNumberOfDipoles(); ++idip) {
- DipoleSource* tDipole = AntCopy->GetDipoleSource(idip);
- //#ifdef LEMMAUSEOMP
- //#pragma omp for schedule(static, 1)
- //#endif
- for (int ifreq=0; ifreq<tDipole->GetNumberOfFrequencies();
- ++ifreq) {
- // Propogation constant in free space
- Real wavef = tDipole->GetAngularFrequency(ifreq) *
- std::sqrt(MU0*EPSILON0);
- SolveSingleTxRxPair(irec, Hankel, wavef, ifreq, tDipole);
- } // freq loop
- } // dipole loop
- } // mask
- //std::cout << "Normal Path\n";
- //std::cout << Receivers->GetHfield(0, irec) << std::endl;
- //if (irec == 1) exit(0);
- #ifdef HAVEBOOSTPROGRESS
- if (progressbar) ++(*disp);
- #endif
- } // receiver loop
- Hankel->Delete();
- AntCopy->Delete();
- } // OMP_PARALLEL BLOCK
- } else if (Antenna->GetNumberOfFrequencies() > 8) {
- // parallel across frequencies
- //std::cout << "freq parallel #2" << std::endl;
- for (int irec=0; irec<Receivers->GetNumberOfReceivers(); ++irec) {
- if (!Receivers->GetMask(irec)) {
- static_cast<PolygonalWireAntenna*>(Antenna)->
- ApproximateWithElectricDipoles(Receivers->GetLocation(irec));
- #ifdef LEMMAUSEOMP
- #pragma omp parallel
- #endif
- { // OpenMP Parallel Block
-
- HankelTransform* Hankel;
- switch (HankelType) {
- case ANDERSON801:
- Hankel = Hankel2::New();
- break;
- case CHAVE:
- Hankel = HankelTransformGaussianQuadrature::New();
- break;
- case FHTKEY201:
- Hankel = FHTKey::New();
- break;
- case FHTKEY101:
- Hankel = FHTKey101::New();
- break;
- case FHTKEY51:
- Hankel = FHTKey51::New();
- break;
- case QWEKEY:
- Hankel = QWEKey::New();
- break;
- default:
- std::cerr << "Hankel transform cannot be created\n";
- exit(EXIT_FAILURE);
- }
- #ifdef LEMMAUSEOMP
- #pragma omp for schedule(static, 1)
- #endif
- for (int ifreq=0; ifreq<Antenna->GetNumberOfFrequencies(); ++ifreq) {
- for (int idip=0; idip<Antenna->GetNumberOfDipoles(); ++idip) {
- DipoleSource* tDipole = Antenna->GetDipoleSource(idip);
- // Propogation constant in free space
- Real wavef = tDipole->GetAngularFrequency(ifreq) *
- std::sqrt(MU0*EPSILON0);
- SolveSingleTxRxPair(irec, Hankel, wavef,
- ifreq, tDipole);
- } // dipole loop
- } // frequency loop
- Hankel->Delete();
- } // OMP_PARALLEL BLOCK
- } // mask loop
- #ifdef HAVEBOOSTPROGRESS
- //if (Receivers->GetNumberOfReceivers() > 100) {
- // ++ disp;
- //}
- #endif
- } // receiver loop
- //std::cout << "End freq parallel " << std::endl;
- } // Frequency Parallel
- else {
- //std::cout << "parallel across #3 " << std::endl;
- for (int irec=0; irec<Receivers->GetNumberOfReceivers(); ++irec) {
- if (!Receivers->GetMask(irec)) {
-
- static_cast<PolygonalWireAntenna*>(Antenna)->
- ApproximateWithElectricDipoles(Receivers->GetLocation(irec));
- // std::cout << "Not Masked " << std::endl;
- // std::cout << "n Freqs " << Antenna->GetNumberOfFrequencies() << std::endl;
- // std::cout << "n Dipoles " << Antenna->GetNumberOfDipoles() << std::endl;
- // if ( !Antenna->GetNumberOfDipoles() ) {
- // std::cout << "NO DIPOLES!!!!!!!!!!!!!!!!!!!!!!!!!!\n";
- // // std::cout << "rec location " << Receivers->GetLocation(irec) << std::endl;
- // // }
-
- #ifdef LEMMAUSEOMP
- #pragma omp parallel
- #endif
- { // OpenMP Parallel Block
- HankelTransform* Hankel;
- switch (HankelType) {
- case ANDERSON801:
- Hankel = Hankel2::New();
- break;
- case CHAVE:
- Hankel = HankelTransformGaussianQuadrature::New();
- break;
- case FHTKEY201:
- Hankel = FHTKey::New();
- break;
- case FHTKEY101:
- Hankel = FHTKey101::New();
- break;
- case FHTKEY51:
- Hankel = FHTKey51::New();
- break;
- case QWEKEY:
- Hankel = QWEKey::New();
- break;
- default:
- std::cerr << "Hankel transform cannot be created\n";
- exit(EXIT_FAILURE);
- }
- for (int ifreq=0; ifreq<Antenna->GetNumberOfFrequencies(); ++ifreq) {
- #ifdef LEMMAUSEOMP
- #pragma omp for schedule(static, 1)
- #endif
- for (int idip=0; idip<Antenna->GetNumberOfDipoles(); ++idip) {
- //#pragma omp critical
- //{
- //cout << "idip=" << idip << "\tthread num=" << omp_get_thread_num() << '\n';
- //}
- DipoleSource* tDipole = Antenna->GetDipoleSource(idip);
- // Propogation constant in free space
- Real wavef = tDipole->GetAngularFrequency(ifreq) *
- std::sqrt(MU0*EPSILON0);
- SolveSingleTxRxPair(irec, Hankel, wavef, ifreq, tDipole);
- } // dipole loop
- } // frequency loop
- Hankel->Delete();
- } // OMP_PARALLEL BLOCK
- } // mask loop
- #ifdef HAVEBOOSTPROGRESS
- //if (Receivers->GetNumberOfReceivers() > 100) {
- // ++ disp;
- //}
- #endif
- } // receiver loop
- } // Polygonal parallel logic
- } else {
- std::cerr << "Lemma with WireAntenna class is currently broken"
- << " fix or use PolygonalWireAntenna\n" << std::endl;
- exit(EXIT_FAILURE);
- // TODO, getting wrong answer, curiously worKernel->GetKs() with MakeCalc, maybe
- // a threading issue, use SolveSingleTxRxPair maype instead of call
- // to MakeCalc3? !!!
- for (int idip=0; idip<Antenna->GetNumberOfDipoles(); ++idip) {
- this->Dipole = Antenna->GetDipoleSource(idip);
- MakeCalc3();
- //++disp;
- }
- this->Dipole = NULL;
- }
-
- #ifdef HAVEBOOSTPROGRESS
- if (progressbar) {
- delete disp;
- }
- #endif
- }
-
- #ifdef KIHALEE_EM1D
- void EMEarth1D::MakeCalc() {
-
- int itype; // 1 = elec, 2 = mag
- switch (this->Dipole->GetDipoleSourceType()) {
- case (GROUNDEDELECTRICDIPOLE) :
- itype = 1;
- break;
- case (MAGNETICDIPOLE) :
- itype = 2;
- break;
- case (UNGROUNDEDELECTRICDIPOLE) :
- std::cerr << "Fortran routine cannot calculate ungrounded"
- "electric dipole\n";
- default:
- throw NonValidDipoleType();
- }
-
- int ipol ;
- Vector3r Pol = this->Dipole->GetPolarisation();
- if (std::abs(Pol[0]-1) < 1e-5) {
- ipol = 1;
- } else if (std::abs(Pol[1]-1) < 1e-5) {
- ipol = 2;
- } else if (std::abs(Pol[2]-1) < 1e-5) {
- ipol = 3;
- } else {
- std::cerr << "Fortran routine cannot calculate arbitrary "
- "dipole polarisation, set to x, y, or z\n";
- }
-
- int nlay = Earth->GetNumberOfNonAirLayers();
-
- if (nlay > MAXLAYERS) {
- std::cerr << "FORTRAN CODE CAN ONLY HANDLE " << MAXLAYERS
- << " LAYERS\n";
- throw EarthModelWithMoreThanMaxLayers();
- }
-
- int nfreq = 1; // number of freqs
-
- int nfield; // field output 1 = elec, 2 = mag, 3 = both
- switch (FieldsToCalculate) {
- case E:
- nfield = 1;
- break;
- case H:
- nfield = 2;
- break;
- case BOTH:
- nfield = 3;
- break;
- default:
- throw 7;
- }
-
- int nres = Receivers->GetNumberOfReceivers();
- int jtype = 3; // form ouf output,
- // 1 = horizontal,
- // 2 = down hole,
- // 3 = freq sounding
- // 4 = down hole logging
-
- int jgamma = 0; // Units 0 = MKS (H->A/m and E->V/m)
- // 1 = h->Gammas E->V/m
-
- double acc = 0.; // Tolerance
-
- // TODO, fix FORTRAN calls so these arrays can be nlay long, not
- // MAXLAYERS.
-
- // Model Parameters
- double *dep = new double[MAXLAYERS];
- dep[0] = 0.; // We always say air starts at 0
- for (int ilay=1; ilay<Earth->GetNumberOfLayers(); ++ilay) {
- dep[ilay] = dep[ilay-1] + Earth->GetLayerThickness(ilay);
- //std::cout << "Depth " << dep[ilay] << std::endl;
- }
-
- std::complex<double> *sig = new std::complex<double> [MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- sig[ilay-1] = (std::complex<double>)(Earth->GetLayerConductivity(ilay));
- }
-
- // TODO, pass these into Fortran call, and return Cole-Cole model
- // parameters. Right now this does nothing
- //std::complex<double> *sus = new std::complex<double>[MAXLAYERS];
- //std::complex<double> *epr = new std::complex<double>[MAXLAYERS];
-
- // Cole-Cole model stuff
- double *susl = new double[MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- susl[ilay-1] = Earth->GetLayerLowFreqSusceptibility(ilay);
- }
-
- double *sush = new double[MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- sush[ilay-1] = Earth->GetLayerHighFreqSusceptibility(ilay);
- }
-
- double *sustau = new double[MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- sustau[ilay-1] = Earth->GetLayerTauSusceptibility(ilay);
- }
-
- double *susalp = new double[MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- susalp[ilay-1] = Earth->GetLayerBreathSusceptibility(ilay);
- }
-
- double *eprl = new double[MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- eprl[ilay-1] = Earth->GetLayerLowFreqPermitivity(ilay);
- }
-
- double *eprh = new double[MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- eprh[ilay-1] = Earth->GetLayerHighFreqPermitivity(ilay);
- }
-
- double *eprtau = new double[MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- eprtau[ilay-1] = Earth->GetLayerTauPermitivity(ilay);
- }
-
- double *epralp = new double[MAXLAYERS];
- for (int ilay=1; ilay<=nlay; ++ilay) {
- epralp[ilay-1] = Earth->GetLayerBreathPermitivity(ilay);
- }
-
- // Freq stuff
- double finit = Dipole->GetFrequency(0); //(1000); // Starting freq
- double flimit = Dipole->GetFrequency(0); //(1000); // max freq
- double dlimit = Dipole->GetFrequency(0); //(1000); // difusion limit
- double lfinc(1); // no. freq per decade
-
- // tx location jtype != 4
- double txx = Dipole->GetLocation(0); // (0.);
- double txy = Dipole->GetLocation(1); // (0.);
- double txz = Dipole->GetLocation(2); // (0.);
-
- // rx position
- // TODO, fix Fortran program to not waste this memory
- // maybe
- const int MAXREC = 15;
- double *rxx = new double [MAXREC];
- double *rxy = new double [MAXREC];
- double *rxz = new double [MAXREC];
-
- std::complex<double> *ex = new std::complex<double>[MAXREC];
- std::complex<double> *ey = new std::complex<double>[MAXREC];
- std::complex<double> *ez = new std::complex<double>[MAXREC];
-
- std::complex<double> *hx = new std::complex<double>[MAXREC];
- std::complex<double> *hy = new std::complex<double>[MAXREC];
- std::complex<double> *hz = new std::complex<double>[MAXREC];
-
- int nres2 = MAXREC;
- int ii=0;
-
- for (ii=0; ii<nres-MAXREC; ii+=MAXREC) {
-
- for (int ir=0; ir<MAXREC; ++ir) {
- //Vector3r pos = Receivers->GetLocation(ii+ir);
- rxx[ir] = Receivers->GetLocation(ii+ir)[0];
- rxy[ir] = Receivers->GetLocation(ii+ir)[1];
- rxz[ir] = Receivers->GetLocation(ii+ir)[2];
- }
-
- em1dcall_(itype, ipol, nlay, nfreq, nfield, nres2, jtype,
- jgamma, acc, dep, sig, susl, sush, sustau, susalp,
- eprl, eprh, eprtau, epralp, finit, flimit, dlimit,
- lfinc, txx, txy, txz, rxx, rxy, rxz, ex, ey, ez,
- hx, hy, hz);
-
- // Scale By Moment
- for (int ir=0; ir<MAXREC; ++ir) {
-
- ex[ir] *= Dipole->GetMoment();
- ey[ir] *= Dipole->GetMoment();
- ez[ir] *= Dipole->GetMoment();
-
- hx[ir] *= Dipole->GetMoment();
- hy[ir] *= Dipole->GetMoment();
- hz[ir] *= Dipole->GetMoment();
-
- // Append values instead of setting them
- this->Receivers->AppendEfield(0, ii+ir, (Complex)(ex[ir]),
- (Complex)(ey[ir]),
- (Complex)(ez[ir]) );
- this->Receivers->AppendHfield(0, ii+ir, (Complex)(hx[ir]),
- (Complex)(hy[ir]),
- (Complex)(hz[ir]) );
- }
- }
-
- //ii += MAXREC;
- nres2 = 0;
- // Perform last positions
- for (int ir=0; ir<nres-ii; ++ir) {
- rxx[ir] = Receivers->GetLocation(ii+ir)[0];
- rxy[ir] = Receivers->GetLocation(ii+ir)[1];
- rxz[ir] = Receivers->GetLocation(ii+ir)[2];
- ++nres2;
- }
-
- em1dcall_(itype, ipol, nlay, nfreq, nfield, nres2, jtype,
- jgamma, acc, dep, sig, susl, sush, sustau, susalp,
- eprl, eprh, eprtau, epralp, finit, flimit, dlimit,
- lfinc, txx, txy, txz, rxx, rxy, rxz, ex, ey, ez,
- hx, hy, hz);
-
- // Scale By Moment
- for (int ir=0; ir<nres-ii; ++ir) {
-
- ex[ir] *= Dipole->GetMoment();
- ey[ir] *= Dipole->GetMoment();
- ez[ir] *= Dipole->GetMoment();
-
- hx[ir] *= Dipole->GetMoment();
- hy[ir] *= Dipole->GetMoment();
- hz[ir] *= Dipole->GetMoment();
-
- // Append values instead of setting them
- this->Receivers->AppendEfield(0, ii+ir, (Complex)(ex[ir]),
- (Complex)(ey[ir]),
- (Complex)(ez[ir]) );
- this->Receivers->AppendHfield(0, ii+ir, (Complex)(hx[ir]),
- (Complex)(hy[ir]),
- (Complex)(hz[ir]) );
-
- }
-
- delete [] sig;
- delete [] dep;
-
- //delete [] sus;
- //delete [] epr;
-
- delete [] susl;
- delete [] sush;
- delete [] susalp;
- delete [] sustau;
-
- delete [] eprl;
- delete [] eprh;
- delete [] epralp;
- delete [] eprtau;
-
- delete [] rxx;
- delete [] rxy;
- delete [] rxz;
-
- delete [] ex;
- delete [] ey;
- delete [] ez;
-
- delete [] hx;
- delete [] hy;
- delete [] hz;
-
- }
- #endif
-
-
- void EMEarth1D::SolveSingleTxRxPair (const int &irec,
- HankelTransform *Hankel, const Real &wavef, const int &ifreq,
- DipoleSource *tDipole) {
- ++icalcinner;
-
- Real rho = (Receivers->GetLocation(irec).head<2>() - tDipole->GetLocation().head<2>()).norm();
-
- tDipole->SetKernels(ifreq, FieldsToCalculate, Receivers, irec, Earth);
- Hankel->ComputeRelated( rho, tDipole->GetKernelManager() );
- tDipole->UpdateFields( ifreq, Hankel, wavef );
- }
-
- void EMEarth1D::SolveLaggedTxRxPair(const int &irec, Hankel2* Hankel,
- const Real &wavef, const int &ifreq, PolygonalWireAntenna* antenna) {
-
- antenna->ApproximateWithElectricDipoles(Receivers->GetLocation(irec));
-
- // Determine the min and max arguments
- Real rhomin = 1e9;
- Real rhomax = 1e-9;
- for (int idip=0; idip<antenna->GetNumberOfDipoles(); ++idip) {
- DipoleSource* tDipole = antenna->GetDipoleSource(idip);
- Real rho = (Receivers->GetLocation(irec).head<2>() - tDipole->GetLocation().head<2>()).norm();
- rhomin = std::min(rhomin, rho);
- rhomax = std::max(rhomax, rho);
- }
- //std::cout << "rhomin\t" << rhomin << "\trhomax" << rhomax << std::endl;
-
- // Determine number of lagged convolutions to do
- // TODO, can Hankel2 adjust the lagg spacing safely?
- int nlag = 1; // We need an extra for some reason for stability
- Real lrho ( 1.01* rhomax );
- while ( lrho > rhomin ) {
- nlag += 1;
- lrho *= Hankel->GetABSER();
- }
-
- //int nlag = rhomin
- DipoleSource* tDipole = antenna->GetDipoleSource(0);
- tDipole->SetKernels(ifreq, FieldsToCalculate, Receivers, irec, Earth);
-
- // Instead we should pass the antenna into this so that Hankel hass all the rho arguments...
- Hankel->ComputeLaggedRelated( 1.01* rhomax, nlag, tDipole->GetKernelManager() );
-
- //std::cout << Hankel->GetAnswer() << std::endl;
- //std::cout << Hankel->GetArg() << std::endl;
-
-
- // Sort the dipoles by rho
-
- for (int idip=0; idip<antenna->GetNumberOfDipoles(); ++idip) {
- //for (int idip=0; idip<1; ++idip) {
- DipoleSource* tDipole = antenna->GetDipoleSource(idip);
- tDipole->SetKernels(ifreq, FieldsToCalculate, Receivers, irec, Earth);
- // Pass Hankel2 a message here so it knows which one to return in Zgauss!
- Real rho = (Receivers->GetLocation(irec).head<2>() - tDipole->GetLocation().head<2>()).norm();
- //std::cout << " in Lagged " << rho << "\t" << rhomin << "\t" << rhomax << std::endl;
- Hankel->SetLaggedArg( rho );
- //std::cout << "out Lagged" << std::endl;
- tDipole->UpdateFields( ifreq, Hankel, wavef );
- }
- //std::cout << "Spline\n";
- //std::cout << Receivers->GetHfield(0, irec) << std::endl;
- }
-
- //////////////////////////////////////////////////////////
- // Thread safe OO Reimplimentation of KiHand's
- // EM1DNEW.for programme
- void EMEarth1D::MakeCalc3() {
-
- if ( Dipole == NULL ) throw NullDipoleSource();
-
- if (Earth == NULL) throw NullEarth();
-
- if (Receivers == NULL) throw NullReceivers();
-
- #ifdef LEMMAUSEOMP
- #pragma omp parallel
- #endif
- { // OpenMP Parallel Block
-
- #ifdef LEMMAUSEOMP
- int tid = omp_get_thread_num();
- int nthreads = omp_get_num_threads();
- #else
- int tid=0;
- int nthreads=1;
- #endif
-
- DipoleSource* tDipole = Dipole->Clone();
-
- HankelTransform* Hankel;
- switch (HankelType) {
- case ANDERSON801:
- Hankel = Hankel2::New();
- break;
- case CHAVE:
- Hankel = HankelTransformGaussianQuadrature::New();
- break;
- case FHTKEY201:
- Hankel = FHTKey::New();
- break;
- case FHTKEY101:
- Hankel = FHTKey101::New();
- break;
- case FHTKEY51:
- Hankel = FHTKey51::New();
- break;
- case QWEKEY:
- Hankel = QWEKey::New();
- break;
- default:
- std::cerr << "Hankel transform cannot be created\n";
- exit(EXIT_FAILURE);
- }
-
- if ( tDipole->GetNumberOfFrequencies() < Receivers->GetNumberOfReceivers() ) {
- for (int ifreq=0; ifreq<tDipole->GetNumberOfFrequencies(); ++ifreq) {
- // Propogation constant in free space being input to Hankel
- Real wavef = tDipole->GetAngularFrequency(ifreq) * std::sqrt(MU0*EPSILON0);
- for (int irec=tid; irec<Receivers->GetNumberOfReceivers(); irec+=nthreads) {
- SolveSingleTxRxPair(irec, Hankel, wavef, ifreq, tDipole);
- }
- }
- } else {
- for (int irec=0; irec<Receivers->GetNumberOfReceivers(); ++irec) {
- for (int ifreq=tid; ifreq<tDipole->GetNumberOfFrequencies(); ifreq+=nthreads) {
- // Propogation constant in free space being input to Hankel
- Real wavef = tDipole->GetAngularFrequency(ifreq) * std::sqrt(MU0*EPSILON0);
- SolveSingleTxRxPair(irec, Hankel, wavef, ifreq, tDipole);
- }
- }
- }
-
- tDipole->Delete();
- Hankel->Delete();
-
- } // OpenMP Parallel Block
- }
-
- NullReceivers::NullReceivers() :
- runtime_error("NULL RECEIVERS") {}
-
- NullAntenna::NullAntenna() :
- runtime_error("NULL ANTENNA") {}
-
- NullInstrument::NullInstrument(LemmaObject* ptr) :
- runtime_error("NULL INSTRUMENT") {
- std::cout << "Thrown by instance of "
- << ptr->GetName() << std::endl;
- }
-
- DipoleSourceSpecifiedForWireAntennaCalc::
- DipoleSourceSpecifiedForWireAntennaCalc() :
- runtime_error("DIPOLE SOURCE SPECIFIED FOR WIRE ANTENNA CALC"){}
-
- } // end of Lemma Namespace
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