Пример #1
0
   void Firehose::getParameters(){
      Project::getParameters();
      typedef Readparameters RP;
      RP::get("Firehose.Bx", this->Bx);
      RP::get("Firehose.By", this->By);
      RP::get("Firehose.Bz", this->Bz);
      RP::get("Firehose.lambda", this->lambda);
      RP::get("Firehose.amp", this->amp);

      // Per-population parameters
      for(uint i=0; i< getObjectWrapper().particleSpecies.size(); i++) {
         const std::string& pop = getObjectWrapper().particleSpecies[i].name;
         FirehoseSpeciesParameters sP;
         RP::get(pop + "_Firehose.rho1", sP.rho[1]);
         RP::get(pop + "_Firehose.rho2", sP.rho[2]);
         RP::get(pop + "_Firehose.Tx1", sP.Tx[1]);
         RP::get(pop + "_Firehose.Tx2", sP.Tx[2]);
         RP::get(pop + "_Firehose.Ty1", sP.Ty[1]);
         RP::get(pop + "_Firehose.Ty2", sP.Ty[2]);
         RP::get(pop + "_Firehose.Tz1", sP.Tz[1]);
         RP::get(pop + "_Firehose.Tz2", sP.Tz[2]);
         RP::get(pop + "_Firehose.Vx1", sP.Vx[1]);
         RP::get(pop + "_Firehose.Vx2", sP.Vx[2]);
         RP::get(pop + "_Firehose.Vy1", sP.Vy[1]);
         RP::get(pop + "_Firehose.Vy2", sP.Vy[2]);
         RP::get(pop + "_Firehose.Vz1", sP.Vz[1]);
         RP::get(pop + "_Firehose.Vz2", sP.Vz[2]);
         RP::get(pop + "_Firehose.nSpaceSamples", sP.nSpaceSamples);
         RP::get(pop + "_Firehose.nVelocitySamples", sP.nVelocitySamples);

         speciesParams.push_back(sP);
      }
   }
Пример #2
0
   void MultiPeak::addParameters(){
      typedef Readparameters RP;

      RP::add("MultiPeak.Bx", "Magnetic field x component (T)", 0.0);
      RP::add("MultiPeak.By", "Magnetic field y component (T)", 0.0);
      RP::add("MultiPeak.Bz", "Magnetic field z component (T)", 0.0);
      RP::add("MultiPeak.dBx", "Magnetic field x component cosine perturbation amplitude (T)", 0.0);
      RP::add("MultiPeak.dBy", "Magnetic field y component cosine perturbation amplitude (T)", 0.0);
      RP::add("MultiPeak.dBz", "Magnetic field z component cosine perturbation amplitude (T)", 0.0);
      RP::add("MultiPeak.magXPertAbsAmp", "Absolute amplitude of the random magnetic perturbation along x (T)", 1.0e-9);
      RP::add("MultiPeak.magYPertAbsAmp", "Absolute amplitude of the random magnetic perturbation along y (T)", 1.0e-9);
      RP::add("MultiPeak.magZPertAbsAmp", "Absolute amplitude of the random magnetic perturbation along z (T)", 1.0e-9);
      RP::add("MultiPeak.lambda", "B cosine perturbation wavelength (m)", 1.0);
      RP::add("MultiPeak.nVelocitySamples", "Number of sampling points per velocity dimension", 2);
      RP::add("MultiPeak.densityModel","Which spatial density model is used?",string("uniform"));

      // Per-population parameters
      for(uint i=0; i< getObjectWrapper().particleSpecies.size(); i++) {
         const std::string& pop = getObjectWrapper().particleSpecies[i].name;
         RP::add(pop+"_MultiPeak.n", "Number of peaks to create", 0);
         RP::addComposing(pop+"_MultiPeak.rho", "Number density (m^-3)");
         RP::addComposing(pop+"_MultiPeak.Tx", "Temperature (K)");
         RP::addComposing(pop+"_MultiPeak.Ty", "Temperature");
         RP::addComposing(pop+"_MultiPeak.Tz", "Temperature");
         RP::addComposing(pop+"_MultiPeak.Vx", "Bulk velocity x component (m/s)");
         RP::addComposing(pop+"_MultiPeak.Vy", "Bulk velocity y component (m/s)");
         RP::addComposing(pop+"_MultiPeak.Vz", "Bulk velocity z component (m/s)");
         RP::addComposing(pop+"_MultiPeak.rhoPertAbsAmp", "Absolute amplitude of the density perturbation");
      }
   }
Пример #3
0
   void Firehose::addParameters(){
      typedef Readparameters RP;

      RP::add("Firehose.Bx", "Magnetic field x component (T)", 0.0);
      RP::add("Firehose.By", "Magnetic field y component (T)", 0.0);
      RP::add("Firehose.Bz", "Magnetic field z component (T)", 0.0);
      RP::add("Firehose.lambda", "Initial perturbation wavelength (m)", 0.0);
      RP::add("Firehose.amp", "Initial perturbation amplitude (m)", 0.0);

      // Per-population parameters
      for(uint i=0; i< getObjectWrapper().particleSpecies.size(); i++) {
         const std::string& pop = getObjectWrapper().particleSpecies[i].name;
         RP::add(pop + "_Firehose.rho1", "Number density, first peak (m^-3)", 0.0);
         RP::add(pop + "_Firehose.rho2", "Number density, second peak (m^-3)", 0.0);
         RP::add(pop + "_Firehose.Tx1", "Temperature x, first peak (K)", 0.0);
         RP::add(pop + "_Firehose.Tx2", "Temperature x, second peak (K)", 0.0);
         RP::add(pop + "_Firehose.Ty1", "Temperature y, first peak (K)", 0.0);
         RP::add(pop + "_Firehose.Ty2", "Temperature y, second peak (K)", 0.0);
         RP::add(pop + "_Firehose.Tz1", "Temperature z, first peak (K)", 0.0);
         RP::add(pop + "_Firehose.Tz2", "Temperature z, second peak (K)", 0.0);
         RP::add(pop + "_Firehose.Vx1", "Bulk velocity x component, first peak (m/s)", 0.0);
         RP::add(pop + "_Firehose.Vx2", "Bulk velocity x component, second peak (m/s)", 0.0);
         RP::add(pop + "_Firehose.Vy1", "Bulk velocity y component, first peak (m/s)", 0.0);
         RP::add(pop + "_Firehose.Vy2", "Bulk velocity y component, second peak (m/s)", 0.0);
         RP::add(pop + "_Firehose.Vz1", "Bulk velocity z component, first peak (m/s)", 0.0);
         RP::add(pop + "_Firehose.Vz2", "Bulk velocity z component, second peak (m/s)", 0.0);
         RP::add(pop + "_Firehose.nSpaceSamples", "Number of sampling points per spatial dimension", 2);
         RP::add(pop + "_Firehose.nVelocitySamples", "Number of sampling points per velocity dimension", 5);
      }
   }
Пример #4
0
 Real Larmor::getDistribValue(creal& x, creal& y, creal& z, creal& vx, creal& vy, creal& vz, const uint popID) const {
   creal kb = physicalconstants::K_B;
   creal mass = getObjectWrapper().particleSpecies[popID].mass;
   
   return exp(- mass * ((vx-this->VX0)*(vx-this->VX0) + (vy-this->VY0)*(vy-this->VY0)+ (vz-this->VZ0)*(vz-this->VZ0)) / (2.0 * kb * this->TEMPERATURE))*
   exp(-pow(x-Parameters::xmax/2.5, 2.0)/pow(this->SCA_X, 2.0))*exp(-pow(y-Parameters::ymax/2.0, 2.0)/pow(this->SCA_Y, 2.0));
 }
Пример #5
0
   void Harris::addParameters(){
      typedef Readparameters RP;
      RP::add("Harris.Scale_size", "Harris sheet scale size (m)", 150000.0);
      RP::add("Harris.BX0", "Magnetic field at infinity (T)", 8.33061003094e-8);
      RP::add("Harris.BY0", "Magnetic field at infinity (T)", 8.33061003094e-8);
      RP::add("Harris.BZ0", "Magnetic field at infinity (T)", 8.33061003094e-8);

      // Per-population parameters
      for(uint i=0; i< getObjectWrapper().particleSpecies.size(); i++) {
         const std::string& pop = getObjectWrapper().particleSpecies[i].name;

         RP::add(pop + "_Harris.Temperature", "Temperature (K)", 2.0e6);
         RP::add(pop + "_Harris.rho", "Number density at infinity (m^-3)", 1.0e7);
         RP::add(pop + "_Harris.nSpaceSamples", "Number of sampling points per spatial dimension.", 2);
         RP::add(pop + "_Harris.nVelocitySamples", "Number of sampling points per velocity dimension.", 2);
      }
   }
Пример #6
0
   void MultiPeak::getParameters(){

      typedef Readparameters RP;
      Project::getParameters();
      RP::get("MultiPeak.Bx", this->Bx);
      RP::get("MultiPeak.By", this->By);
      RP::get("MultiPeak.Bz", this->Bz);
      RP::get("MultiPeak.magXPertAbsAmp", this->magXPertAbsAmp);
      RP::get("MultiPeak.magYPertAbsAmp", this->magYPertAbsAmp);
      RP::get("MultiPeak.magZPertAbsAmp", this->magZPertAbsAmp);
      RP::get("MultiPeak.dBx", this->dBx);
      RP::get("MultiPeak.dBy", this->dBy);
      RP::get("MultiPeak.dBz", this->dBz);
      RP::get("MultiPeak.lambda", this->lambda);
      RP::get("MultiPeak.nVelocitySamples", this->nVelocitySamples);

      // Per-population parameters
      for(uint i=0; i< getObjectWrapper().particleSpecies.size(); i++) {
         const std::string& pop = getObjectWrapper().particleSpecies[i].name;

         MultiPeakSpeciesParameters sP;
         RP::get(pop + "_MultiPeak.n", sP.numberOfPeaks);
         RP::get(pop + "_MultiPeak.rho",sP.rho);
         RP::get(pop + "_MultiPeak.Tx", sP.Tx);
         RP::get(pop + "_MultiPeak.Ty", sP.Ty);
         RP::get(pop + "_MultiPeak.Tz", sP.Tz);
         RP::get(pop + "_MultiPeak.Vx", sP.Vx);
         RP::get(pop + "_MultiPeak.Vy", sP.Vy);
         RP::get(pop + "_MultiPeak.Vz", sP.Vz);

         RP::get(pop + "_MultiPeak.rhoPertAbsAmp", sP.rhoPertAbsAmp);
         if(!sP.isConsistent()) {
            cerr << "You should define all parameters (MultiPeak.rho, MultiPeak.Tx, MultiPeak.Ty, MultiPeak.Tz, MultiPeak.Vx, MultiPeak.Vy, MultiPeak.Vz, MultiPeak.rhoPertAbsAmp) for all " << sP.numberOfPeaks << " peaks of population " << pop << "." << endl;
            abort();
         }

         speciesParams.push_back(sP);
      }
      
      string densModelString;
      RP::get("MultiPeak.densityModel",densModelString);
      
      if (densModelString == "uniform") densityModel = Uniform;
      else if (densModelString == "testcase") densityModel = TestCase;
   }
Пример #7
0
    Real Larmor::calcPhaseSpaceDensity(creal& x, creal& y, creal& z, creal& dx, creal& dy, creal& dz, 
            creal& vx, creal& vy, creal& vz, creal& dvx, creal& dvy, creal& dvz,const uint popID) const {
       const size_t meshID = getObjectWrapper().particleSpecies[popID].velocityMesh;
      vmesh::MeshParameters& meshParams = getObjectWrapper().velocityMeshes[meshID];
      if (vx < meshParams.meshMinLimits[0] + 0.5*dvx ||
          vy < meshParams.meshMinLimits[1] + 0.5*dvy ||
          vz < meshParams.meshMinLimits[2] + 0.5*dvz ||
          vx > meshParams.meshMaxLimits[0] - 1.5*dvx ||
          vy > meshParams.meshMaxLimits[1] - 1.5*dvy ||
          vz > meshParams.meshMaxLimits[2] - 1.5*dvz) {
         return 0.0;
      }

      creal mass = getObjectWrapper().particleSpecies[popID].mass;
      creal kb = physicalconstants::K_B;

      creal d_x = dx / (this->nSpaceSamples-1);
      creal d_y = dy / (this->nSpaceSamples-1);
      creal d_z = dz / (this->nSpaceSamples-1);
      creal d_vx = dvx / (this->nVelocitySamples-1);
      creal d_vy = dvy / (this->nVelocitySamples-1);
      creal d_vz = dvz / (this->nVelocitySamples-1);
      Real avg = 0.0;
      
      for (uint i=0; i<this->nSpaceSamples; ++i)
         for (uint j=0; j<this->nSpaceSamples; ++j)
            for (uint k=0; k<this->nSpaceSamples; ++k)
               for (uint vi=0; vi<this->nVelocitySamples; ++vi)
                  for (uint vj=0; vj<this->nVelocitySamples; ++vj)
                     for (uint vk=0; vk<this->nVelocitySamples; ++vk)
                     {
                        avg += getDistribValue(x+i*d_x, y+j*d_y, z+k*d_z, vx+vi*d_vx, vy+vj*d_vy, vz+vk*d_vz, popID);
                     }
      
      creal result = avg *this->DENSITY * pow(mass / (2.0 * M_PI * kb * this->TEMPERATURE), 1.5) /
                     (this->nSpaceSamples*this->nSpaceSamples*this->nSpaceSamples) / 
                     (this->nVelocitySamples*this->nVelocitySamples*this->nVelocitySamples);
      
      if(result < this->maxwCutoff) {
         return 0.0;
      } else {
         return result;
      }
   }
Пример #8
0
   void Harris::getParameters(){
      Project::getParameters();
      typedef Readparameters RP;
      RP::get("Harris.Scale_size", this->SCA_LAMBDA);
      RP::get("Harris.BX0", this->BX0);
      RP::get("Harris.BY0", this->BY0);
      RP::get("Harris.BZ0", this->BZ0);


      // Per-population parameters
      for(uint i=0; i< getObjectWrapper().particleSpecies.size(); i++) {
         const std::string& pop = getObjectWrapper().particleSpecies[i].name;
         HarrisSpeciesParameters sP;

         RP::get(pop + "_Harris.Temperature", sP.TEMPERATURE);
         RP::get(pop + "_Harris.rho", sP.DENSITY);
         RP::get(pop + "_Harris.nSpaceSamples", sP.nSpaceSamples);
         RP::get(pop + "_Harris.nVelocitySamples", sP.nVelocitySamples);

         speciesParams.push_back(sP);
      }
   }
Пример #9
0
    std::vector<string> RepositoryXL::callerKey(const std::vector<string> &objectList) {

        std::vector<string> ret;

        for (std::vector<string>::const_iterator i = objectList.begin();
            i != objectList.end(); ++i) {
                string idStrip = CallingRange::getStub(*i);
                const shared_ptr<ObjectWrapperXL>& objectWrapperXL = boost::static_pointer_cast<ObjectWrapperXL>(
                    getObjectWrapper(idStrip));
                ret.push_back(objectWrapperXL->callerKey());
        }

        return ret;
    }
Пример #10
0
   Real Harris::getDistribValue(
      creal& x,creal& y, creal& z,
      creal& vx, creal& vy, creal& vz,
      creal& dvx, creal& dvy, creal& dvz,
      const uint popID
   ) const {

      const HarrisSpeciesParameters& sP = speciesParams[popID];
      Real mass = getObjectWrapper().particleSpecies[popID].mass;

      return sP.DENSITY * pow(mass / (2.0 * M_PI * physicalconstants::K_B * sP.TEMPERATURE), 1.5) * (
         5.0 / pow(cosh(x / (this->SCA_LAMBDA)), 2.0) * exp(- mass * (pow(vx, 2.0) + pow(vy, 2.0) + pow(vz, 2.0)) / (2.0 * physicalconstants::K_B * sP.TEMPERATURE))
         +
         exp(- mass * (pow(vx, 2.0) + pow(vy, 2.0) + pow(vz, 2.0)) / (2.0 * physicalconstants::K_B * sP.TEMPERATURE)));
   }
Пример #11
0
   Real MultiPeak::getDistribValue(creal& vx, creal& vy, creal& vz, creal& dvx, creal& dvy, creal& dvz,const uint popID) const {
      const MultiPeakSpeciesParameters& sP = speciesParams[popID];
      creal mass = getObjectWrapper().particleSpecies[popID].mass;
      creal kb = physicalconstants::K_B;

      Real value = 0.0;

      for (uint i=0; i<sP.numberOfPeaks; ++i) {
         value += (sP.rho[i] + sP.rhoPertAbsAmp[i] * rhoRnd)
               * pow(mass / (2.0 * M_PI * kb ), 1.5) * 1.0
               / sqrt(sP.Tx[i]*sP.Ty[i]*sP.Tz[i]) 
               * exp(- mass * (pow(vx - sP.Vx[i], 2.0) / (2.0 * kb * sP.Tx[i]) 
                             + pow(vy - sP.Vy[i], 2.0) / (2.0 * kb * sP.Ty[i]) 
                             + pow(vz - sP.Vz[i], 2.0) / (2.0 * kb * sP.Tz[i])));
      }
      return value;
   }
Пример #12
0
 Real Firehose::getDistribValue(
    creal& x, creal& y,
    creal& vx, creal& vy, creal& vz,
    creal& dvx, creal& dvy, creal& dvz,
    const uint popID) const  {
    const FirehoseSpeciesParameters& sP = speciesParams[popID];
    creal mass = getObjectWrapper().particleSpecies[popID].mass;
    creal kb = physicalconstants::K_B;
    
    Real Vx = profile(sP.Vx[1],sP.Vx[1], x);
    
    return
    sP.rho[1] * pow(mass / (2.0 * M_PI * kb * sP.Tx[1]), 1.5) *
    exp(- mass * (pow(vx - Vx, 2.0) / (2.0 * kb * sP.Tx[1]) +
                pow(vy - sP.Vy[1], 2.0) / (2.0 * kb * sP.Ty[1]) +
             pow(vz - sP.Vz[1], 2.0) / (2.0 * kb * sP.Tz[1])));
 //   this->rho[2] * pow(mass / (2.0 * M_PI * kb * this->Tx[2]), 1.5) *
 //   exp(- mass * (pow(vx - this->Vx[2], 2.0) / (2.0 * kb * this->Tx[2]) + 
 //                 pow(vy - this->Vy[2], 2.0) / (2.0 * kb * this->Ty[2]) + 
 //           pow(vz - this->Vz[2], 2.0) / (2.0 * kb * this->Tz[2]))); 
 }
Пример #13
0
    void Larmor::getParameters() {
       Project::getParameters();
      typedef Readparameters RP;

      if(getObjectWrapper().particleSpecies.size() > 1) {
         std::cerr << "The selected project does not support multiple particle populations! Aborting in " << __FILE__ << " line " << __LINE__ << std::endl;
         abort();
      }

      RP::get("Larmor.BX0", this->BX0);
      RP::get("Larmor.BY0", this->BY0);
      RP::get("Larmor.BZ0", this->BZ0);
      RP::get("Larmor.VX0", this->VX0);
      RP::get("Larmor.VY0", this->VY0);
      RP::get("Larmor.VZ0", this->VZ0);
      RP::get("Larmor.rho", this->DENSITY);
      RP::get("Larmor.Temperature", this->TEMPERATURE);
      RP::get("Larmor.nSpaceSamples", this->nSpaceSamples);
      RP::get("Larmor.nVelocitySamples", this->nVelocitySamples);
      RP::get("Larmor.maxwCutoff", this->maxwCutoff);
      RP::get("Larmor.Scale_x", this->SCA_X);
      RP::get("Larmor.Scale_y", this->SCA_Y);
    }
Пример #14
0
   /*!
    * WARNING This assumes that the velocity space is isotropic (same resolution in vx, vy, vz).
    */
   std::vector<vmesh::GlobalID> TriAxisSearch::findBlocksToInitialize(SpatialCell* cell,const uint popID) const {
      set<vmesh::GlobalID> blocksToInitialize;
      bool search;
      unsigned int counter;
      
      creal x = cell->parameters[CellParams::XCRD];
      creal y = cell->parameters[CellParams::YCRD];
      creal z = cell->parameters[CellParams::ZCRD];
      creal dx = cell->parameters[CellParams::DX];
      creal dy = cell->parameters[CellParams::DY];
      creal dz = cell->parameters[CellParams::DZ];
      
      const uint8_t refLevel = 0;
      creal dvxCell = cell->get_velocity_grid_cell_size(popID,refLevel)[0];
      creal dvyCell = cell->get_velocity_grid_cell_size(popID,refLevel)[1];
      creal dvzCell = cell->get_velocity_grid_cell_size(popID,refLevel)[2];
      creal dvxBlock = cell->get_velocity_grid_block_size(popID,refLevel)[0];
      creal dvyBlock = cell->get_velocity_grid_block_size(popID,refLevel)[1];
      creal dvzBlock = cell->get_velocity_grid_block_size(popID,refLevel)[2];
      
      const size_t vxblocks_ini = cell->get_velocity_grid_length(popID,refLevel)[0];
      const size_t vyblocks_ini = cell->get_velocity_grid_length(popID,refLevel)[1];
      const size_t vzblocks_ini = cell->get_velocity_grid_length(popID,refLevel)[2];

      const vector<std::array<Real, 3>> V0 = this->getV0(x+0.5*dx, y+0.5*dy, z+0.5*dz, popID);
      for (vector<std::array<Real, 3>>::const_iterator it = V0.begin(); it != V0.end(); it++) {
         // VX search
         search = true;
         counter = 0;
         #warning TODO: add SpatialCell::getVelocityBlockMinValue() in place of sparseMinValue
         while (search) {
            if (0.1 * getObjectWrapper().particleSpecies[popID].sparseMinValue >
                calcPhaseSpaceDensity(x,
                                      y,
                                      z,
                                      dx,
                                      dy,
                                      dz,
                                      it->at(0) + counter*dvxBlock, it->at(1), it->at(2),
                                      dvxCell, dvyCell, dvzCell, popID
                                     )
               ) {
               search = false;
            }
            ++counter;
            if (counter >= cell->get_velocity_grid_length(popID,refLevel)[0]) search = false;
         }
         counter+=2;
         Real vRadiusSquared = (Real)counter*(Real)counter*dvxBlock*dvxBlock;

         // VY search
         search = true;
         counter = 0;
         while(search) {
            if (0.1 * getObjectWrapper().particleSpecies[popID].sparseMinValue >
               calcPhaseSpaceDensity(
                                     x,
                                     y,
                                     z,
                                     dx,
                                     dy,
                                     dz,
                                     it->at(0), it->at(1) + counter*dvyBlock, it->at(2),
                                     dvxCell, dvyCell, dvzCell, popID
                                    )
               ||
               counter > vxblocks_ini
              ) {
               search = false;
            }
            ++counter;
            if (counter >= cell->get_velocity_grid_length(popID,refLevel)[1]) search = false;
         }
         counter+=2;
         vRadiusSquared = max(vRadiusSquared, (Real)counter*(Real)counter*dvyBlock*dvyBlock);

         // VZ search
         search = true;
         counter = 0;
         while(search) {
            if (0.1 * getObjectWrapper().particleSpecies[popID].sparseMinValue >
               calcPhaseSpaceDensity(
                                     x,
                                     y,
                                     z,
                                     dx,
                                     dy,
                                     dz,
                                     it->at(0), it->at(1), it->at(2) + counter*dvzBlock,
                                     dvxCell, dvyCell, dvzCell, popID
                                    )
               ||
               counter > vxblocks_ini
              ) {
               search = false;
            }
            ++counter;
            if (counter >= cell->get_velocity_grid_length(popID,refLevel)[2]) search = false;
         }
         counter+=2;
         vRadiusSquared = max(vRadiusSquared, (Real)counter*(Real)counter*dvzBlock*dvzBlock);

         // Block listing
         for (uint kv=0; kv<vzblocks_ini; ++kv) 
            for (uint jv=0; jv<vyblocks_ini; ++jv)
               for (uint iv=0; iv<vxblocks_ini; ++iv) {
                  vmesh::GlobalID blockIndices[3];
                  blockIndices[0] = iv;
                  blockIndices[1] = jv;
                  blockIndices[2] = kv;
                  const vmesh::GlobalID blockGID = cell->get_velocity_block(popID,blockIndices,refLevel);
                  
                  Real V_crds[3];
                  cell->get_velocity_block_coordinates(popID,blockGID,V_crds);
                  Real dV[3];
                  cell->get_velocity_block_size(popID,blockGID,dV);
                  V_crds[0] += 0.5*dV[0];
                  V_crds[1] += 0.5*dV[1];
                  V_crds[2] += 0.5*dV[2];
                  Real R2 = ((V_crds[0]-it->at(0))*(V_crds[0]-it->at(0))
                          + (V_crds[1]-it->at(1))*(V_crds[1]-it->at(1))
                          + (V_crds[2]-it->at(2))*(V_crds[2]-it->at(2)));
                  
                  if (R2 < vRadiusSquared) {
                     cell->add_velocity_block(blockGID,popID);
                     blocksToInitialize.insert(blockGID);
                  }
               }
      }

      vector<vmesh::GlobalID> returnVector;
      for (set<vmesh::GlobalID>::const_iterator it=blocksToInitialize.begin(); it!=blocksToInitialize.end(); ++it) {
         returnVector.push_back(*it);
      }

      return returnVector;
   }
Пример #15
0
   Real MultiPeak::calcPhaseSpaceDensity(creal& x, creal& y, creal& z, creal& dx, creal& dy, creal& dz, 
                                         creal& vx, creal& vy, creal& vz, creal& dvx, creal& dvy, creal& dvz,
                                         const uint popID) const {
      // Iterative sampling of the distribution function. Keep track of the 
      // accumulated volume average over the iterations. When the next 
      // iteration improves the average by less than 1%, return the value.
      Real avgTotal = 0.0;
      bool ok = false;
      uint N = nVelocitySamples; // Start by using nVelocitySamples
      int N3_sum = 0;           // Sum of sampling points used so far

      const MultiPeakSpeciesParameters& sP = speciesParams[popID];
                                            
      #warning TODO: Replace getObjectWrapper().particleSpecies[popID].sparseMinValue with SpatialCell::getVelocityBlockMinValue(popID)
      const Real avgLimit = 0.01*getObjectWrapper().particleSpecies[popID].sparseMinValue;
      do {
         Real avg = 0.0;        // Volume average obtained during this sampling
         creal DVX = dvx / N; 
         creal DVY = dvy / N;
         creal DVZ = dvz / N;

         Real rhoFactor = 1.0;
         switch (densityModel) {
            case Uniform:
               rhoFactor = 1.0;
               break;
            case TestCase:
               rhoFactor = 1.0;
               if ((x >= 3.9e5 && x <= 6.1e5) && (y >= 3.9e5 && y <= 6.1e5)) {
                  rhoFactor = 1.5;
               }
               break;
            default:
               rhoFactor = 1.0;
               break;
         }
         
         // Sample the distribution using N*N*N points
         for (uint vi=0; vi<N; ++vi) {
            for (uint vj=0; vj<N; ++vj) {
               for (uint vk=0; vk<N; ++vk) {
                  creal VX = vx + 0.5*DVX + vi*DVX;
                  creal VY = vy + 0.5*DVY + vj*DVY;
                  creal VZ = vz + 0.5*DVZ + vk*DVZ;
                  avg += getDistribValue(VX,VY,VZ,DVX,DVY,DVZ,popID);
               }
            }
         }
         avg *= rhoFactor;
         
         // Compare the current and accumulated volume averages:
         Real eps = max(numeric_limits<creal>::min(),avg * static_cast<Real>(1e-6));
         Real avgAccum   = avgTotal / (avg + N3_sum);
         Real avgCurrent = avg / (N*N*N);
         if (fabs(avgCurrent-avgAccum)/(avgAccum+eps) < 0.01) ok = true;
         else if (avg < avgLimit) ok = true;
         else if (N > 10) {
            ok = true;
         }

         avgTotal += avg;
         N3_sum += N*N*N;
         ++N;
      } while (ok == false);

      return avgTotal / N3_sum;
   }