vertical_EAS.cc

/*
 * (c) Copyright 2018 CORSIKA Project, corsika-project@lists.kit.edu
 *
 * See file AUTHORS for a list of contributors.
 *
 * This software is distributed under the terms of the GNU General Public
 * Licence version 3 (GPL Version 3). See file LICENSE for a full version of
 * the license.
 */

#include <corsika/cascade/Cascade.h>
#include <corsika/process/ProcessSequence.h>
#include <corsika/process/energy_loss/EnergyLoss.h>
#include <corsika/process/hadronic_elastic_model/HadronicElasticModel.h>
#include <corsika/process/stack_inspector/StackInspector.h>
#include <corsika/process/tracking_line/TrackingLine.h>

#include <corsika/setup/SetupStack.h>
#include <corsika/setup/SetupTrajectory.h>

#include <corsika/environment/Environment.h>
#include <corsika/environment/HomogeneousMedium.h>
#include <corsika/environment/NuclearComposition.h>

#include <corsika/geometry/Sphere.h>

#include <corsika/process/sibyll/Decay.h>
#include <corsika/process/sibyll/Interaction.h>
#include <corsika/process/sibyll/NuclearInteraction.h>

#include <corsika/process/particle_cut/ParticleCut.h>
#include <corsika/process/track_writer/TrackWriter.h>

#include <corsika/units/PhysicalUnits.h>

#include <corsika/random/RNGManager.h>

#include <corsika/utl/CorsikaFenv.h>

#include <boost/type_index.hpp>
using boost::typeindex::type_id_with_cvr;

#include <iostream>
#include <limits>
#include <typeinfo>

using namespace corsika;
using namespace corsika::process;
using namespace corsika::units;
using namespace corsika::particles;
using namespace corsika::random;
using namespace corsika::setup;
using namespace corsika::geometry;
using namespace corsika::environment;

using namespace std;
using namespace corsika::units::si;

//
// The example main program for a particle cascade
//
int main() {
  feenableexcept(FE_INVALID);
  // initialize random number sequence(s)
  random::RNGManager::GetInstance().RegisterRandomStream("cascade");

  // setup environment, geometry
  using EnvType = Environment<setup::IEnvironmentModel>;
  EnvType env;
  auto& universe = *(env.GetUniverse());

  auto theMedium =
      EnvType::CreateNode<Sphere>(Point{env.GetCoordinateSystem(), 0_m, 0_m, 0_m},
                                  1_km * std::numeric_limits<double>::infinity());

  // fraction of oxygen
  const float fox = 0.20946;
  using MyHomogeneousModel = HomogeneousMedium<environment::IMediumModel>;
  theMedium->SetModelProperties<MyHomogeneousModel>(
      1_kg / (1_m * 1_m * 1_m),
      environment::NuclearComposition(
          std::vector<particles::Code>{particles::Code::Nitrogen,
                                       particles::Code::Oxygen},
          std::vector<float>{(float)1. - fox, fox}));

  universe.AddChild(std::move(theMedium));

  const CoordinateSystem& rootCS = env.GetCoordinateSystem();

  // setup particle stack, and add primary particle
  setup::Stack stack;
  stack.Clear();
  const Code beamCode = Code::Nucleus;
  const int nuclA = 4;
  const int nuclZ = int(nuclA / 2.15 + 0.7);
  const HEPMassType mass = GetNucleusMass(nuclA, nuclZ);
  const HEPEnergyType E0 = nuclA * 10_TeV;
  double theta = 0.;
  double phi = 0.;

  {
    auto elab2plab = [](HEPEnergyType Elab, HEPMassType m) {
      return sqrt((Elab - m) * (Elab + m));
    };
    HEPMomentumType P0 = elab2plab(E0, mass);
    auto momentumComponents = [](double theta, double phi, HEPMomentumType ptot) {
      return std::make_tuple(ptot * sin(theta) * cos(phi), ptot * sin(theta) * sin(phi),
                             -ptot * cos(theta));
    };
    auto const [px, py, pz] =
        momentumComponents(theta / 180. * M_PI, phi / 180. * M_PI, P0);
    auto plab = corsika::stack::MomentumVector(rootCS, {px, py, pz});
    cout << "input particle: " << beamCode << endl;
    cout << "input angles: theta=" << theta << " phi=" << phi << endl;
    cout << "input momentum: " << plab.GetComponents() / 1_GeV << endl;
    Point pos(rootCS, 0_m, 0_m,
              112.8_km); // this is the CORSIKA 7 start of atmosphere/universe
    stack.AddParticle(std::tuple<particles::Code, units::si::HEPEnergyType,
                                 corsika::stack::MomentumVector, geometry::Point,
                                 units::si::TimeType, unsigned short, unsigned short>{
        beamCode, E0, plab, pos, 0_ns, nuclA, nuclZ});
  }

  // setup processes, decays and interactions
  tracking_line::TrackingLine tracking;
  stack_inspector::StackInspector<setup::Stack> stackInspect(1, true, E0);

  random::RNGManager::GetInstance().RegisterRandomStream("s_rndm");
  process::sibyll::Interaction sibyll;
  process::sibyll::NuclearInteraction sibyllNuc(sibyll, env);
  process::sibyll::Decay decay;
  process::particle_cut::ParticleCut cut(20_GeV);

  process::track_writer::TrackWriter trackWriter("tracks.dat");
  process::energy_loss::EnergyLoss eLoss;

  // assemble all processes into an ordered process list
  auto sequence = sibyll << sibyllNuc << decay << eLoss << cut << stackInspect;

  // define air shower object, run simulation
  cascade::Cascade EAS(env, tracking, sequence, stack);
  EAS.Init();
  EAS.Run();

  eLoss.PrintProfile(); // print longitudinal profile

  cut.ShowResults();
  const HEPEnergyType Efinal =
      cut.GetCutEnergy() + cut.GetInvEnergy() + cut.GetEmEnergy();
  cout << "total cut energy (GeV): " << Efinal / 1_GeV << endl
       << "relative difference (%): " << (Efinal / E0 - 1) * 100 << endl;
  cout << "total dEdX energy (GeV): " << eLoss.GetTotal() / 1_GeV << endl
       << "relative difference (%): " << eLoss.GetTotal() / E0 * 100 << endl;
}