#include <CosmicMuonGenerator.h>

Public Member Functions
	CosmicMuonGenerator ()

double	getRate ()

void	initialize (CLHEP::HepRandomEngine *rng=nullptr)

void	nextEvent ()

bool	nextMultiEvent ()

void	runCMG ()

void	setAcptAllMu (bool AllMu)

void	setClayWidth (double ClayLaeyrWidth)

void	setElossScaleFactor (double ElossScaleFact)

void	setMaxEnu (double MaxEn)

void	setMaxP (double P)

void	setMaxPhi (double Phi)

void	setMaxT0 (double T0)

void	setMaxTheta (double Theta)

void	setMinEnu (double MinEn)

void	setMinP (double P)

void	setMinP_CMS (double P)

void	setMinPhi (double Phi)

void	setMinT0 (double T0)

void	setMinTheta (double Theta)

void	setMTCCHalf (bool MTCC)

void	setMultiMuon (bool MultiMu)

void	setMultiMuonFileFirstEvent (int MultiMuFile1stEvt)

void	setMultiMuonFileName (std::string MultiMuonFileName)

void	setMultiMuonNmin (int MultiMuNmin)

void	setNumberOfEvents (unsigned int N)

void	setNuProdAlt (double NuPrdAlt)

void	setPlugVx (double PlugVtx)

void	setPlugVz (double PlugVtz)

void	setRadiusOfTarget (double R)

void	setRandomEngine (CLHEP::HepRandomEngine *v)

void	setRanSeed (int N)

void	setRhoAir (double VarRhoAir)

void	setRhoClay (double VarRhoClay)

void	setRhoPlug (double VarRhoPlug)

void	setRhoRock (double VarRhoRock)

void	setRhoWall (double VarRhoSWall)

void	setTIFOnly_constant (bool TIF)

void	setTIFOnly_linear (bool TIF)

void	setTrackerOnly (bool Tracker)

void	setZCentrOfTarget (double Z)

void	setZDistOfTarget (double Z)

void	terminate ()

	~CosmicMuonGenerator ()

Public Attributes
double	E_at

std::vector< double >	E_sf

std::vector< double >	E_ug

double	EventWeight

int	Id_at

std::vector< int >	Id_sf

std::vector< int >	Id_ug

SingleParticleEvent	OneMuoEvt

std::vector< double >	P_mu

double	Px_at

std::vector< double >	Px_mu

std::vector< double >	Px_sf

std::vector< double >	Px_ug

double	Py_at

std::vector< double >	Py_mu

std::vector< double >	Py_sf

std::vector< double >	Py_ug

double	Pz_at

std::vector< double >	Pz_mu

std::vector< double >	Pz_sf

std::vector< double >	Pz_ug

double	T0_at

std::vector< double >	T0_sf

std::vector< double >	T0_ug

double	Theta_at

std::vector< double >	Theta_mu

double	Trials

double	Vx_at

std::vector< double >	Vx_mu

std::vector< double >	Vx_sf

std::vector< double >	Vx_ug

double	Vxz_mu

double	Vy_at

std::vector< double >	Vy_mu

std::vector< double >	Vy_sf

std::vector< double >	Vy_ug

double	Vz_at

std::vector< double >	Vz_mu

std::vector< double >	Vz_sf

std::vector< double >	Vz_ug

Private Member Functions
void	checkIn ()

void	displayEv ()

bool	goodOrientation ()

void	initEvDis ()

Private Attributes
bool	AcptAllMu

double	ClayWidth

CMSCGEN *	Cosmics

bool	delRanGen

double	ElossScaleFactor

double	EventRate

double	MaxEnu

double	MaxP

double	MaxPhi

double	MaxT0

double	MaxTheta

double	MinEnu

double	MinP

double	MinP_CMS

double	MinPhi

double	MinT0

double	MinTheta

bool	MTCCHalf

TFile *	MultiIn

bool	MultiMuon

int	MultiMuonFileFirstEvent

std::string	MultiMuonFileName

int	MultiMuonNmin

TTree *	MultiTree

int	NcloseMultiMuonEvents

double	Ndiced

double	Ngen

CMSCGENnorm *	Norm

bool	NotInitialized

double	Nsel

int	NskippedMultiMuonEvents

unsigned int	NumberOfEvents

double	NuProdAlt

double	PlugVx

double	PlugVz

double	RadiusOfTarget

CLHEP::HepRandomEngine *	RanGen

int	RanSeed

double	rateErr_stat

double	rateErr_syst

double	RhoAir

double	RhoClay

double	RhoPlug

double	RhoRock

double	RhoWall

sim *	SimTree

ULong64_t	SimTree_jentry

ULong64_t	SimTreeEntries

double	SumIntegrals

double	SurfaceRadius

double	Target3dRadius

bool	TIFOnly_constant

bool	TIFOnly_linear

bool	TrackerOnly

double	ZCentrOfTarget

double	ZDistOfTarget

Detailed Description

Definition at line 31 of file CosmicMuonGenerator.h.

Constructor & Destructor Documentation

◆ CosmicMuonGenerator()

CosmicMuonGenerator::CosmicMuonGenerator ( )

inline

Definition at line 34 of file CosmicMuonGenerator.h.

References ClayWidth, Cosmics, gather_cfg::cout, Deg2Rad, ElossScaleFactor, EventRate, MaxP, MaxPhi, MaxT0, MaxTheta, MinP, MinP_CMS, MinPhi, MinT0, MinTheta, MTCCHalf, MultiMuon, MultiMuonFileFirstEvent, MultiMuonFileName, MultiMuonNmin, Ndiced, Ngen, Norm, NotInitialized, Nsel, NumberOfEvents, PlugOnShaftVx, PlugOnShaftVz, PlugVx, PlugVz, RadiusOfTarget, RanSeed, rateErr_stat, rateErr_syst, RhoAir, RhoClay, RhoPlug, RhoRock, RhoWall, SumIntegrals, SurfaceRadius, Target3dRadius, TIFOnly_constant, TIFOnly_linear, TrackerOnly, ZCentrOfTarget, and ZDistOfTarget.

                         : delRanGen(false) {
     //initialize class which normalizes flux (added by P.Biallass 29.3.2006)
     Norm = new CMSCGENnorm();
     //initialize class which produces the cosmic muons  (modified by P.Biallass 29.3.2006)
     Cosmics = new CMSCGEN();
     // set default control parameters
     NumberOfEvents = 100;
     RanSeed = 135799468;
     MinP = 3.;
     MinP_CMS = MinP;
     MaxP = 3000.;
     MinTheta = 0. * Deg2Rad;
     //MaxTheta = 84.26*Deg2Rad;
     MaxTheta = 89.0 * Deg2Rad;
     MinPhi = 0. * Deg2Rad;
     MaxPhi = 360. * Deg2Rad;
     MinT0 = -12.5;
     MaxT0 = 12.5;
     ElossScaleFactor = 1.0;
     RadiusOfTarget = 8000.;
     ZDistOfTarget = 15000.;
     ZCentrOfTarget = 0.;
     TrackerOnly = false;
     MultiMuon = false;
     MultiMuonFileName = "dummy.root";
     MultiMuonFileFirstEvent = 0;
     MultiMuonNmin = 2;
     TIFOnly_constant = false;
     TIFOnly_linear = false;
     MTCCHalf = false;
     EventRate = 0.;
     rateErr_stat = 0.;
     rateErr_syst = 0.;
 
     SumIntegrals = 0.;
     Ngen = 0.;
     Nsel = 0.;
     Ndiced = 0.;
     NotInitialized = true;
     Target3dRadius = 0.;
     SurfaceRadius = 0.;
     //set plug as default onto PX56 shaft
     PlugVx = PlugOnShaftVx;
     PlugVz = PlugOnShaftVz;
     //material densities in g/cm^3
     RhoAir = 0.001214;
     RhoWall = 2.5;
     RhoRock = 2.5;
     RhoClay = 2.3;
     RhoPlug = 2.5;
     ClayWidth = 50000;  //[mm]
 
     std::cout << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << "***                                                   ***" << std::endl;
     std::cout << "***  C O S M I C  M U O N  G E N E R A T O R  (vC++)  ***" << std::endl;
     std::cout << "***                                                   ***" << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << std::endl;
   }

◆ ~CosmicMuonGenerator()

CosmicMuonGenerator::~CosmicMuonGenerator ( )

inline

Definition at line 98 of file CosmicMuonGenerator.h.

References Cosmics, delRanGen, Norm, and RanGen.

                          {
     if (delRanGen)
       delete RanGen;
     delete Norm;
     delete Cosmics;
   }

Member Function Documentation

◆ checkIn()

void CosmicMuonGenerator::checkIn ( )

private

Definition at line 925 of file CosmicMuonGenerator.cc.

References gather_cfg::cout, ElossScaleFactor, MaxEnu, MaxP, MaxPhi, MaxT0, MaxTheta, MinEnu, MinP, MinPhi, MinT0, MinTheta, and NumberOfEvents.

Referenced by initialize().

                                   {
   if (MinP < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: min.energy is out of range (0 GeV ... inf]" << std::endl << std::endl;
   }
   if (MaxP < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.energy is out of range (0 GeV ... inf]" << std::endl << std::endl;
   }
   if (MaxP <= MinP) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.energy is not greater than min.energy" << std::endl << std::endl;
   }
   if (MinTheta < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: min.theta is out of range [0 deg ... 90 deg)" << std::endl << std::endl;
   }
   if (MaxTheta < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.theta is out of range [0 deg ... 90 deg)" << std::endl << std::endl;
   }
   if (MaxTheta <= MinTheta) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.theta is not greater than min.theta" << std::endl << std::endl;
   }
   if (MinPhi < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: min.phi is out of range [0 deg ... 360 deg]" << std::endl << std::endl;
   }
   if (MaxPhi < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.phi is out of range [0 deg ... 360 deg]" << std::endl << std::endl;
   }
   if (MaxPhi <= MinPhi) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.phi is not greater than min.phi" << std::endl << std::endl;
   }
   if (MaxT0 <= MinT0) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.t0 is not greater than min.t0" << std::endl << std::endl;
   }
   if (ElossScaleFactor < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: E-loss scale factor is out of range [0 ... inf)" << std::endl << std::endl;
   }
   if (MinEnu < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: min.Enu is out of range [0 GeV ... inf]" << std::endl << std::endl;
   }
   if (MaxEnu < 0.) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.Enu is out of range [0 GeV ... inf]" << std::endl << std::endl;
   }
   if (MaxEnu <= MinEnu) {
     NumberOfEvents = 0;
     std::cout << "  CMG-ERR: max.Enu is not greater than min.Enu" << std::endl << std::endl;
   }
 }

◆ displayEv()

void CosmicMuonGenerator::displayEv ( )

private

Definition at line 1072 of file CosmicMuonGenerator.cc.

References SingleParticleEvent::e(), hcalRecHitTable_cff::energy, nano_mu_digi_cff::float, ALPAKA_ACCELERATOR_NAMESPACE::ecal::reconstruction::internal::endcap::iy(), OneMuoEvt, SingleParticleEvent::px(), SingleParticleEvent::py(), SingleParticleEvent::pz(), RadiusCMS, RadiusTracker, mathSSE::sqrt(), TrackerOnly, SingleParticleEvent::vx(), SingleParticleEvent::vy(), SingleParticleEvent::vz(), beampixel_dqm_sourceclient-live_cfg::yStep, Z_DistCMS, and Z_DistTracker.

Referenced by nextEvent().

                                     {
 #if ROOT_INTERACTIVE
   double RadiusDet = RadiusCMS;
   double Z_DistDet = Z_DistCMS;
   if (TrackerOnly == true) {
     RadiusDet = RadiusTracker;
     Z_DistDet = Z_DistTracker;
   }
   disXY->Reset();
   disZY->Reset();
   TMarker* InteractionPoint = new TMarker(0., 0., 2);
   TArc* r8m = new TArc(0., 0., (RadiusDet / 1000.));
   TLatex* logEaxis = new TLatex();
   logEaxis->SetTextSize(0.05);
   float energy = float(OneMuoEvt.e());
   float verX = float(OneMuoEvt.vx() / 1000.);  // [m]
   float verY = float(OneMuoEvt.vy() / 1000.);  // [m]
   float verZ = float(OneMuoEvt.vz() / 1000.);  // [m]
   float dirX = float(OneMuoEvt.px()) / std::fabs(OneMuoEvt.py());
   float dirY = float(OneMuoEvt.py()) / std::fabs(OneMuoEvt.py());
   float dirZ = float(OneMuoEvt.pz()) / std::fabs(OneMuoEvt.py());
   float yStep = disXY->GetYaxis()->GetBinWidth(1);
   int NbinY = disXY->GetYaxis()->GetNbins();
   for (int iy = 0; iy < NbinY; ++iy) {
     verX += dirX * yStep;
     verY += dirY * yStep;
     verZ += dirZ * yStep;
     float rXY = sqrt(verX * verX + verY * verY) * 1000.;  // [mm]
     float absZ = std::fabs(verZ) * 1000.;                 // [mm]
     if (rXY < RadiusDet && absZ < Z_DistDet) {
       disXY->Fill(verX, verY, log10(energy));
       disZY->Fill(verZ, verY, log10(energy));
       disC->cd(1);
       disXY->Draw("COLZ");
       InteractionPoint->Draw("SAME");
       r8m->Draw("SAME");
       logEaxis->DrawLatex((0.65 * RadiusDet / 1000.), (1.08 * RadiusDet / 1000.), "log_{10}E(#mu^{#pm})");
       disC->cd(2);
       disZY->Draw("COL");
       InteractionPoint->Draw("SAME");
       gPad->Update();
     }
   }
 #endif
 }

◆ getRate()

double CosmicMuonGenerator::getRate ( )

Definition at line 1275 of file CosmicMuonGenerator.cc.

References EventRate.

1275 { return EventRate; }

CosmicMuonGenerator::EventRate

double EventRate

Definition: CosmicMuonGenerator.h:195

◆ goodOrientation()

bool CosmicMuonGenerator::goodOrientation ( )

private

Definition at line 984 of file CosmicMuonGenerator.cc.

References gather_cfg::cout, Deg2Rad, HLT_2024v14_cff::dPhi, MinTheta, OneMuoEvt, VtxSmearedParameters_cfi::Phi, SingleParticleEvent::phi(), Pi, PlugWidth, RadiusCMS, mathSSE::sqrt(), SurfaceOfEarth, Target3dRadius, SingleParticleEvent::theta(), TwoPi, SingleParticleEvent::vx(), and SingleParticleEvent::vz().

Referenced by nextEvent(), and nextMultiEvent().

                                           {
   // check angular range (for a sphere with Target3dRadius around the target)
   bool goodAngles = false;
   bool phiaccepted = false;
   bool thetaaccepted = false;
   double RxzV = sqrt(OneMuoEvt.vx() * OneMuoEvt.vx() + OneMuoEvt.vz() * OneMuoEvt.vz());
 
   double rVY;
   if (MinTheta > 90. * Deg2Rad)  //upgoing muons from neutrinos
     rVY = -sqrt(RxzV * RxzV + RadiusCMS * RadiusCMS);
   else
     rVY = sqrt(RxzV * RxzV + (SurfaceOfEarth + PlugWidth) * (SurfaceOfEarth + PlugWidth));
 
   double Phi = OneMuoEvt.phi();
   double PhiV = atan2(OneMuoEvt.vx(), OneMuoEvt.vz()) + Pi;
   if (PhiV > TwoPi)
     PhiV -= TwoPi;
   double disPhi = std::fabs(PhiV - Phi);
   if (disPhi > Pi)
     disPhi = TwoPi - disPhi;
   double dPhi = Pi;
   if (RxzV > Target3dRadius)
     dPhi = asin(Target3dRadius / RxzV);
   if (disPhi < dPhi)
     phiaccepted = true;
   double Theta = OneMuoEvt.theta();
   double ThetaV = asin(RxzV / rVY);
   double dTheta = Pi;
   if (std::fabs(rVY) > Target3dRadius)
     dTheta = asin(Target3dRadius / std::fabs(rVY));
   //std::cout << "    dPhi = " <<   dPhi << "  (" <<   Phi << " <p|V> " <<   PhiV << ")" << std::endl;
   //std::cout << "  dTheta = " << dTheta << "  (" << Theta << " <p|V> " << ThetaV << ")" << std::endl;
 
   if (!phiaccepted && RxzV < Target3dRadius)
     //if (RxzV < Target3dRadius)
     std::cout << "Rejected phi=" << Phi << "  PhiV=" << PhiV << "  dPhi=" << dPhi << "  disPhi=" << disPhi
               << "  RxzV=" << RxzV << "  Target3dRadius=" << Target3dRadius << "  Theta=" << Theta << std::endl;
 
   if (std::fabs(Theta - ThetaV) < dTheta)
     thetaaccepted = true;
   if (phiaccepted && thetaaccepted)
     goodAngles = true;
   return goodAngles;
 }

◆ initEvDis()

void CosmicMuonGenerator::initEvDis ( )

private

Definition at line 1029 of file CosmicMuonGenerator.cc.

References MaxP, MinP, RadiusCMS, RadiusTracker, TrackerOnly, Z_DistCMS, and Z_DistTracker.

Referenced by initialize().

                                     {
 #if ROOT_INTERACTIVE
   float rCMS = RadiusCMS / 1000.;
   float zCMS = Z_DistCMS / 1000.;
   if (TrackerOnly == true) {
     rCMS = RadiusTracker / 1000.;
     zCMS = Z_DistTracker / 1000.;
   }
   TH2F* disXY = new TH2F("disXY", "X-Y view", 160, -rCMS, rCMS, 160, -rCMS, rCMS);
   TH2F* disZY = new TH2F("disZY", "Z-Y view", 150, -zCMS, zCMS, 160, -rCMS, rCMS);
   gStyle->SetPalette(1, 0);
   gStyle->SetMarkerColor(1);
   gStyle->SetMarkerSize(1.5);
   TCanvas* disC = new TCanvas("disC", "Cosmic Muon Event Display", 0, 0, 800, 410);
   disC->Divide(2, 1);
   disC->cd(1);
   gPad->SetTicks(1, 1);
   disXY->SetMinimum(log10(MinP));
   disXY->SetMaximum(log10(MaxP));
   disXY->GetXaxis()->SetLabelSize(0.05);
   disXY->GetXaxis()->SetTitleSize(0.05);
   disXY->GetXaxis()->SetTitleOffset(1.0);
   disXY->GetXaxis()->SetTitle("X [m]");
   disXY->GetYaxis()->SetLabelSize(0.05);
   disXY->GetYaxis()->SetTitleSize(0.05);
   disXY->GetYaxis()->SetTitleOffset(0.8);
   disXY->GetYaxis()->SetTitle("Y [m]");
   disC->cd(2);
   gPad->SetGrid(1, 1);
   gPad->SetTicks(1, 1);
   disZY->SetMinimum(log10(MinP));
   disZY->SetMaximum(log10(MaxP));
   disZY->GetXaxis()->SetLabelSize(0.05);
   disZY->GetXaxis()->SetTitleSize(0.05);
   disZY->GetXaxis()->SetTitleOffset(1.0);
   disZY->GetXaxis()->SetTitle("Z [m]");
   disZY->GetYaxis()->SetLabelSize(0.05);
   disZY->GetYaxis()->SetTitleSize(0.05);
   disZY->GetYaxis()->SetTitleOffset(0.8);
   disZY->GetYaxis()->SetTitle("Y [m]");
 #endif
 }

◆ initialize()

void CosmicMuonGenerator::initialize ( CLHEP::HepRandomEngine * rng = nullptr )

Definition at line 26 of file CosmicMuonGenerator.cc.

References checkIn(), Cosmics, gather_cfg::cout, Debug, Deg2Rad, delRanGen, EventDisplay, sim::fChain, sim::Init(), initEvDis(), CMSCGEN::initialize(), CMSCGEN::initializeNuMu(), MaxEnu, MaxP, MaxPhi, MaxTheta, MinEnu, MinP, MinPhi, MinStepSize, MinTheta, MultiIn, MultiMuon, MultiMuonFileFirstEvent, MultiMuonFileName, MultiTree, NcloseMultiMuonEvents, NotInitialized, NskippedMultiMuonEvents, NumberOfEvents, NuProdAlt, OneMuoEvt, phi, SingleParticleEvent::PlugVx, PlugVx, SingleParticleEvent::PlugVz, PlugVz, PlugWidth, RadiusCMS, RadiusOfTarget, RadiusTracker, RanGen, RanSeed, SingleParticleEvent::RhoAir, RhoAir, SingleParticleEvent::RhoClay, RhoClay, SingleParticleEvent::RhoPlug, RhoPlug, SingleParticleEvent::RhoRock, RhoRock, SingleParticleEvent::RhoWall, RhoWall, MultiTrackValidator_cfi::sim, SimTree, SimTree_jentry, SimTreeEntries, mathSSE::sqrt(), SurfaceOfEarth, SurfaceRadius, funct::tan(), Target3dRadius, TIFOnly_constant, TIFOnly_linear, TrackerOnly, Z_DistTracker, and ZDistOfTarget.

Referenced by runCMG().

                                                               {
   if (delRanGen)
     delete RanGen;
   if (!rng) {
     RanGen = new CLHEP::HepJamesRandom;
     RanGen->setSeed(RanSeed, 0);  //set seed for Random Generator (seed can be controled by config-file)
     delRanGen = true;
   } else {
     RanGen = rng;
     delRanGen = false;
   }
   checkIn();
   if (NumberOfEvents > 0) {
     // set up "surface geometry" dimensions
     double RadiusTargetEff = RadiusOfTarget;  //get this from cfg-file
     double Z_DistTargetEff = ZDistOfTarget;   //get this from cfg-file
     //double Z_CentrTargetEff = ZCentrOfTarget;  //get this from cfg-file
     if (TrackerOnly == true) {
       RadiusTargetEff = RadiusTracker;
       Z_DistTargetEff = Z_DistTracker;
     }
     Target3dRadius = sqrt(RadiusTargetEff * RadiusTargetEff + Z_DistTargetEff * Z_DistTargetEff) + MinStepSize;
     if (Debug)
       std::cout << "  radius of sphere  around  target = " << Target3dRadius << " mm" << std::endl;
 
     if (MinTheta > 90. * Deg2Rad)  //upgoing muons from neutrinos
       SurfaceRadius = (RadiusCMS) * (-tan(MinTheta)) + MinStepSize;
     else
       SurfaceRadius = (SurfaceOfEarth + PlugWidth + RadiusTargetEff) * tan(MaxTheta) + Target3dRadius;
     if (Debug)
       std::cout << "  starting point radius at Surface + PlugWidth = " << SurfaceRadius << " mm" << std::endl;
 
     OneMuoEvt.PlugVx = PlugVx;
     OneMuoEvt.PlugVz = PlugVz;
     OneMuoEvt.RhoAir = RhoAir;
     OneMuoEvt.RhoWall = RhoWall;
     OneMuoEvt.RhoRock = RhoRock;
     OneMuoEvt.RhoClay = RhoClay;
     OneMuoEvt.RhoPlug = RhoPlug;
     //set energy and angle limits for CMSCGEN, give same seed as above
     if (MinTheta >= 90. * Deg2Rad)  //upgoing muons from neutrinos
       Cosmics->initializeNuMu(MinP, MaxP, MinTheta, MaxTheta, MinEnu, MaxEnu, MinPhi, MaxPhi, NuProdAlt, RanGen);
     else
       Cosmics->initialize(MinP, MaxP, MinTheta, MaxTheta, RanGen, TIFOnly_constant, TIFOnly_linear);
 
 #if ROOT_INTERACTIVE
     // book histos
     TH1D* ene = new TH1D("ene", "generated energy", 210, 0., 1050.);
     TH1D* the = new TH1D("the", "generated theta", 90, 0., 90.);
     TH1D* phi = new TH1D("phi", "generated phi", 120, 0., 360.);
     TH3F* ver = new TH3F("ver", "Z-X-Y coordinates", 100, -25., 25., 20, -10., 10., 40, -10., 10.);
 #endif
     if (EventDisplay)
       initEvDis();
     std::cout << std::endl;
 
     if (MultiMuon) {
       MultiIn = nullptr;
 
       std::cout << "MultiMuonFileName.c_str()=" << MultiMuonFileName.c_str() << std::endl;
       MultiIn = new TFile(MultiMuonFileName.c_str());
 
       if (!MultiIn)
         std::cout << "MultiMuon=True: MultiMuonFileName='" << MultiMuonFileName.c_str() << "' does not exist"
                   << std::endl;
       else
         std::cout << "MultiMuonFile: " << MultiMuonFileName.c_str() << " opened!" << std::endl;
       //MultiTree = (TTree*) gDirectory->Get("sim");
       MultiTree = (TTree*)MultiIn->Get("sim");
       SimTree = new sim(MultiTree);
       SimTree->Init(MultiTree);
       SimTreeEntries = SimTree->fChain->GetEntriesFast();
       std::cout << "SimTreeEntries=" << SimTreeEntries << std::endl;
 
       if (MultiMuonFileFirstEvent <= 0)
         SimTree_jentry = 0;
       else
         SimTree_jentry = MultiMuonFileFirstEvent - 1;  //1=1st evt (SimTree_jentry=0)
 
       NcloseMultiMuonEvents = 0;
       NskippedMultiMuonEvents = 0;
     }
 
     if (!MultiMuon || (MultiMuon && MultiIn))
       NotInitialized = false;
   }
 }

◆ nextEvent()

void CosmicMuonGenerator::nextEvent ( )

Definition at line 114 of file CosmicMuonGenerator.cc.

Referenced by runCMG().

                                     {
   double E = 0.;
   double Theta = 0.;
   double Phi = 0.;
   double RxzV = 0.;
   double PhiV = 0.;
   if (int(Nsel) % 100 == 0)
     std::cout << "    generated " << int(Nsel) << " events" << std::endl;
   // generate cosmic (E,theta,phi)
   bool notSelected = true;
   while (notSelected) {
     bool badMomentumGenerated = true;
     while (badMomentumGenerated) {
       if (MinTheta > 90. * Deg2Rad)  //upgoing muons from neutrinos
         Cosmics->generateNuMu();
       else
         Cosmics->generate();  //dice one event now
 
       E = sqrt(Cosmics->momentum_times_charge() * Cosmics->momentum_times_charge() + MuonMass * MuonMass);
       Theta = TMath::ACos(Cosmics->cos_theta());  //angle has to be in RAD here
       Ngen += 1.;  //count number of initial cosmic events (in surface area), vertices will be added later
       badMomentumGenerated = false;
       Phi = RanGen->flat() * (MaxPhi - MinPhi) + MinPhi;
     }
     Norm->events_n100cos(E, Theta);  //test if this muon is in normalization range
     Ndiced += 1;                     //one more cosmic is diced
 
     // generate vertex
     double Nver = 0.;
     bool badVertexGenerated = true;
     while (badVertexGenerated) {
       RxzV = sqrt(RanGen->flat()) * SurfaceRadius;
       PhiV = RanGen->flat() * TwoPi;
       // check phi range (for a sphere with Target3dRadius around the target)
       double dPhi = Pi;
       if (RxzV > Target3dRadius)
         dPhi = asin(Target3dRadius / RxzV);
       double rotPhi = PhiV + Pi;
       if (rotPhi > TwoPi)
         rotPhi -= TwoPi;
       double disPhi = std::fabs(rotPhi - Phi);
       if (disPhi > Pi)
         disPhi = TwoPi - disPhi;
       if (disPhi < dPhi || AcptAllMu)
         badVertexGenerated = false;
       Nver += 1.;
     }
     Ngen += (Nver - 1.);  //add number of generated vertices to initial cosmic events
 
     // complete event at surface
     int id = 13;  // mu-
     if (Cosmics->momentum_times_charge() > 0.)
       id = -13;  // mu+
     double absMom = sqrt(E * E - MuonMass * MuonMass);
     double verMom = absMom * cos(Theta);
     double horMom = absMom * sin(Theta);
     double Px = horMom * sin(Phi);  // [GeV/c]
     double Py = -verMom;            // [GeV/c]
     double Pz = horMom * cos(Phi);  // [GeV/c]
     double Vx = RxzV * sin(PhiV);   // [mm]
 
     double Vy;
     if (MinTheta > 90. * Deg2Rad)  //upgoing muons from neutrinos
       Vy = -RadiusCMS;
     else
       Vy = SurfaceOfEarth + PlugWidth;  // [mm]
 
     double Vz = RxzV * cos(PhiV);                                           // [mm]
     double T0 = (RanGen->flat() * (MaxT0 - MinT0) + MinT0) * SpeedOfLight;  // [mm/c];
 
     Id_at = id;
     Px_at = Px;
     Py_at = Py;
     Pz_at = Pz;
     E_at = E;  //M_at = MuonMass;
     Vx_at = Vx;
     Vy_at = Vy;
     Vz_at = Vz;
     T0_at = T0;
 
     OneMuoEvt.create(id, Px, Py, Pz, E, MuonMass, Vx, Vy, Vz, T0);
     // if angles are ok, propagate to target
     if (goodOrientation()) {
       if (MinTheta > 90. * Deg2Rad)  //upgoing muons from neutrinos
         OneMuoEvt.propagate(0., RadiusOfTarget, ZDistOfTarget, ZCentrOfTarget, TrackerOnly, MTCCHalf);
       else
         OneMuoEvt.propagate(ElossScaleFactor, RadiusOfTarget, ZDistOfTarget, ZCentrOfTarget, TrackerOnly, MTCCHalf);
     }
 
     if ((OneMuoEvt.hitTarget() && sqrt(OneMuoEvt.e() * OneMuoEvt.e() - MuonMass * MuonMass) > MinP_CMS) ||
         AcptAllMu == true) {
       Nsel += 1.;  //count number of generated and accepted events
       notSelected = false;
     }
   }
 
   EventWeight = 1.;
 
   //just one outgoing particle at SurFace
   Id_sf.resize(1);
   Px_sf.resize(1);
   Py_sf.resize(1);
   Pz_sf.resize(1);
   E_sf.resize(1);
   //M_sf.resize(1);
   Vx_sf.resize(1);
   Vy_sf.resize(1);
   Vz_sf.resize(1);
   T0_sf.resize(1);
 
   Id_sf[0] = Id_at;
   Px_sf[0] = Px_at;
   Py_sf[0] = Py_at;
   Pz_sf[0] = Pz_at;
   E_sf[0] = E_at;  //M_fs[0] = MuonMass;
   Vx_sf[0] = Vx_at;
   Vy_sf[0] = Vy_at;
   Vz_sf[0] = Vz_at;
   T0_sf[0] = T0_at;
 
   //just one particle at UnderGround
   Id_ug.resize(1);
   Px_ug.resize(1);
   Py_ug.resize(1);
   Pz_ug.resize(1);
   E_ug.resize(1);
   //M_ug.resize(1);
   Vx_ug.resize(1);
   Vy_ug.resize(1);
   Vz_ug.resize(1);
   T0_ug.resize(1);
 
   Id_ug[0] = OneMuoEvt.id();
   Px_ug[0] = OneMuoEvt.px();
   Py_ug[0] = OneMuoEvt.py();
   Pz_ug[0] = OneMuoEvt.pz();
   E_ug[0] = OneMuoEvt.e();
   //M_ug[0] = OneMuoEvt.m();
   Vx_ug[0] = OneMuoEvt.vx();
   Vy_ug[0] = OneMuoEvt.vy();
   Vz_ug[0] = OneMuoEvt.vz();
   T0_ug[0] = OneMuoEvt.t0();
 
   // plot variables of selected events
 #if ROOT_INTERACTIVE
   ene->Fill(OneMuoEvt.e());
   the->Fill((OneMuoEvt.theta() * Rad2Deg));
   phi->Fill((OneMuoEvt.phi() * Rad2Deg));
   ver->Fill((OneMuoEvt.vz() / 1000.), (OneMuoEvt.vx() / 1000.), (OneMuoEvt.vy() / 1000.));
 #endif
   if (Debug) {
     std::cout << "new event" << std::endl;
     std::cout << "  Px,Py,Pz,E,m = " << OneMuoEvt.px() << ", " << OneMuoEvt.py() << ", " << OneMuoEvt.pz() << ", "
               << OneMuoEvt.e() << ", " << OneMuoEvt.m() << " GeV" << std::endl;
     std::cout << "  Vx,Vy,Vz,t0  = " << OneMuoEvt.vx() << ", " << OneMuoEvt.vy() << ", " << OneMuoEvt.vz() << ", "
               << OneMuoEvt.t0() << " mm" << std::endl;
   }
   if (EventDisplay)
     displayEv();
 }

◆ nextMultiEvent()

bool CosmicMuonGenerator::nextMultiEvent ( )

Definition at line 275 of file CosmicMuonGenerator.cc.

                                          {
   if (Debug)
     std::cout << "\nEntered CosmicMuonGenerator::nextMultiEvent()" << std::endl;
   bool EvtRejected = true;
   bool MuInMaxDist = false;
   double MinDist;  //[mm]
 
   while (EvtRejected) {
     //read in event from SimTree
     //ULong64_t ientry = SimTree->LoadTree(SimTree_jentry);
     Long64_t ientry = SimTree->GetEntry(SimTree_jentry);
     std::cout << "CosmicMuonGenerator::nextMultiEvent(): SimTree_jentry="
               << SimTree_jentry
               //<< " ientry=" << ientry
               << " SimTreeEntries=" << SimTreeEntries << std::endl;
     if (ientry < 0)
       return false;  //stop run
     if (SimTree_jentry < SimTreeEntries) {
       SimTree_jentry++;
     } else {
       std::cout << "CosmicMuonGenerator.cc::nextMultiEvent: No more events in file!" << std::endl;
       return false;  //stop run
     }
 
     int nmuons = SimTree->shower_nParticlesWritten;
     if (nmuons < MultiMuonNmin) {
       std::cout << "CosmicMuonGenerator.cc: Warning!  Less than " << MultiMuonNmin << " muons in event!" << std::endl;
       std::cout << "trying next event from file" << std::endl;
       NskippedMultiMuonEvents++;
       continue;  //EvtRejected while loop: get next event from file
     }
 
     Px_mu.resize(nmuons);
     Py_mu.resize(nmuons);
     Pz_mu.resize(nmuons);
     P_mu.resize(nmuons);
 
     MinDist = 99999.e9;  //[mm]
     double MuMuDist;
     MuInMaxDist = false;
     //check if at least one muon pair closer than 30m at surface
     int NmuPmin = 0;
     for (int imu = 0; imu < nmuons; ++imu) {
       Px_mu[imu] =
           -SimTree->particle__Px[imu] * sin(NorthCMSzDeltaPhi) + SimTree->particle__Py[imu] * cos(NorthCMSzDeltaPhi);
       Pz_mu[imu] =
           SimTree->particle__Px[imu] * cos(NorthCMSzDeltaPhi) + SimTree->particle__Py[imu] * sin(NorthCMSzDeltaPhi);
       Py_mu[imu] = -SimTree->particle__Pz[imu];  //Corsika down going particles defined in -z direction!
       P_mu[imu] = sqrt(Px_mu[imu] * Px_mu[imu] + Py_mu[imu] * Py_mu[imu] + Pz_mu[imu] * Pz_mu[imu]);
 
       if (P_mu[imu] < MinP_CMS && AcptAllMu == false)
         continue;
       else if (SimTree->particle__ParticleID[imu] != 5 && SimTree->particle__ParticleID[imu] != 6)
         continue;
       else
         NmuPmin++;
 
       for (int jmu = 0; jmu < imu; ++jmu) {
         if (P_mu[jmu] < MinP_CMS && AcptAllMu == false)
           continue;
         if (SimTree->particle__ParticleID[imu] != 5 && SimTree->particle__ParticleID[imu] != 6)
           continue;
         MuMuDist = sqrt((SimTree->particle__x[imu] - SimTree->particle__x[jmu]) *
                             (SimTree->particle__x[imu] - SimTree->particle__x[jmu]) +
                         (SimTree->particle__y[imu] - SimTree->particle__y[jmu]) *
                             (SimTree->particle__y[imu] - SimTree->particle__y[jmu])) *
                    10.;  //CORSIKA [cm] to CMSCGEN [mm]
         if (MuMuDist < MinDist)
           MinDist = MuMuDist;
         if (MuMuDist < 2. * Target3dRadius)
           MuInMaxDist = true;
       }
     }
     if (MultiMuonNmin >= 2) {
       if (MuInMaxDist) {
         NcloseMultiMuonEvents++;
       } else {
         std::cout << "CosmicMuonGenerator.cc: Warning! No muon pair closer than " << 2. * Target3dRadius / 1000.
                   << "m   MinDist=" << MinDist / 1000. << "m at surface" << std::endl;
         std::cout << "Fraction of too wide opening angle multi muon events: "
                   << 1 - double(NcloseMultiMuonEvents) / SimTree_jentry << std::endl;
         std::cout << "NcloseMultiMuonEvents=" << NcloseMultiMuonEvents << std::endl;
         std::cout << "trying next event from file" << std::endl;
         NskippedMultiMuonEvents++;
         continue;  //EvtRejected while loop: get next event from file
       }
     }
 
     if (NmuPmin < MultiMuonNmin && AcptAllMu == false) {  //take single muon events consistently into account
       NskippedMultiMuonEvents++;
       continue;  //EvtRejected while loop: get next event from file
     }
 
     if (Debug)
       if (MultiMuonNmin >= 2)
         std::cout << "start trial do loop: MuMuDist=" << MinDist / 1000. << "[m]   Nmuons=" << nmuons
                   << "  NcloseMultiMuonEvents=" << NcloseMultiMuonEvents
                   << "  NskippedMultiMuonEvents=" << NskippedMultiMuonEvents << std::endl;
 
     //int primary_id = SimTree->run_ParticleID;
     Id_at = SimTree->shower_EventID;
 
     double M_at = 0.;
     //if (Id_at == 13) {
     Id_at = 2212;       //convert from Corsika to HepPDT
     M_at = 938.272e-3;  //[GeV] mass
     //}
 
     E_at = SimTree->shower_Energy;
     Theta_at = SimTree->shower_Theta;
     double phi_at = SimTree->shower_Phi - NorthCMSzDeltaPhi;  //rotate by almost 90 degrees
     if (phi_at < -Pi)
       phi_at += TwoPi;  //bring into interval (-Pi,Pi]
     else if (phi_at > Pi)
       phi_at -= TwoPi;
     double P_at = sqrt(E_at * E_at - M_at * M_at);
     //need to rotate about 90degrees around x->N axis => y<=>z,
     //then rotate new x-z-plane from x->North to x->LHC centre
     Px_at = P_at * sin(Theta_at) * sin(phi_at);
     Py_at = -P_at * cos(Theta_at);
     Pz_at = P_at * sin(Theta_at) * cos(phi_at);
 
     //compute maximal theta of secondary muons
     double theta_mu_max = Theta_at;
     double theta_mu_min = Theta_at;
 
     double phi_rel_min = 0.;  //phi_mu_min - phi_at
     double phi_rel_max = 0.;  //phi_mu_max - phi_at
 
     //std::cout << "SimTree->shower_Energy=" << SimTree->shower_Energy <<std::endl;
 
     Theta_mu.resize(nmuons);
     for (int imu = 0; imu < nmuons; ++imu) {
       Theta_mu[imu] = acos(-Py_mu[imu] / P_mu[imu]);
       if (Theta_mu[imu] > theta_mu_max)
         theta_mu_max = Theta_mu[imu];
       if (Theta_mu[imu] < theta_mu_min)
         theta_mu_min = Theta_mu[imu];
 
       double phi_mu = atan2(Px_mu[imu], Pz_mu[imu]);  // in (-Pi,Pi]
       double phi_rel = phi_mu - phi_at;
       if (phi_rel < -Pi)
         phi_rel += TwoPi;  //bring into interval (-Pi,Pi]
       else if (phi_rel > Pi)
         phi_rel -= TwoPi;
       if (phi_rel < phi_rel_min)
         phi_rel_min = phi_rel;
       else if (phi_rel > phi_rel_max)
         phi_rel_max = phi_rel;
     }
 
     double h_sf = SurfaceOfEarth + PlugWidth;  //[mm]
 
     double R_at = h_sf * tan(Theta_at);
 
     double JdRxzV_dR_trans = 1.;
     double JdPhiV_dPhi_trans = 1.;
     double JdR_trans_sqrt = 1.;
 
     //chose random vertex Phi and Rxz weighted to speed up and smoothen
     double R_mu_max = (h_sf + Target3dRadius) * tan(theta_mu_max);
     double R_max = std::min(SurfaceRadius, R_mu_max);
     double R_mu_min = (h_sf - Target3dRadius) * tan(theta_mu_min);
     double R_min = std::max(0., R_mu_min);
 
     if (R_at > SurfaceRadius) {
       std::cout << "CosmicMuonGenerator.cc: Warning! R_at=" << R_at << " > SurfaceRadius=" << SurfaceRadius
                 << std::endl;
     }
 
     //do phase space transformation for horizontal radius R
 
     //determine first phase space limits
 
     double psR1min = R_min + 0.25 * (R_max - R_min);
     double psR1max = std::min(SurfaceRadius, R_max - 0.25 * (R_max - R_min));  //no R's beyond R_max
     double psR1 = psR1max - psR1min;
 
     double psR2min = R_min;
     double psR2max = R_max;
     double psR2 = psR2max - psR2min;
 
     double psR3min = 0.;
     double psR3max = SurfaceRadius;
     double psR3 = psR3max - psR3min;
 
     //double psall = psR1+psR2+psR3;
     double psRall = psR3;
 
     double fR1 = psR1 / psRall, fR2 = psR2 / psRall, fR3 = psR3 / psRall;  //f1+f2+f3=130%
     double pR1 = 0.25, pR2 = 0.7, pR3 = 0.05;
 
     //do phase space transformation for azimuthal angle phi
     double psPh1 = 0.5 * (phi_rel_max - phi_rel_min);
     double psPh2 = phi_rel_max - phi_rel_min;
     double psPh3 = TwoPi;
     double psPhall = psPh3;
 
     double fPh1 = psPh1 / psPhall, fPh2 = psPh2 / psPhall,
            fPh3 = psPh3 / psPhall;  //(f1+f2+f3=TwoPi+f1+f2)/(TwoPi+f1+f2)
 
     double pPh1 = 0.25, pPh2 = 0.7, pPh3 = 0.05;
 
     Trials = 0;          //global int trials
     double trials = 0.;  //local weighted trials
     Vx_mu.resize(nmuons);
     Vy_mu.resize(nmuons);
     Vz_mu.resize(nmuons);
     int NmuHitTarget = 0;
     while (NmuHitTarget < MultiMuonNmin) {
       NmuHitTarget = 0;  //re-initialize every loop iteration
       double Nver = 0.;
 
       //chose phase space class
       double RxzV;
       double which_R_class = RanGen->flat();
       if (which_R_class < pR1) {  //pR1% in psR1
         RxzV = psR1min + psR1 * RanGen->flat();
         JdRxzV_dR_trans = fR1 / pR1 * SurfaceRadius / psR1;
       } else if (which_R_class < pR1 + pR2) {  //further pR2% in psR2
         RxzV = psR2min + psR2 * RanGen->flat();
         JdRxzV_dR_trans = fR2 / pR2 * SurfaceRadius / psR2;
       } else {  //remaining pR3% in psR3=[0., R_max]
         RxzV = psR3min + psR3 * RanGen->flat();
         JdRxzV_dR_trans = fR3 / pR3 * SurfaceRadius / psR3;
       }
 
       JdR_trans_sqrt = 2. * RxzV / SurfaceRadius;  //flat in sqrt(r) space
 
       //chose phase space class
       double PhiV;
       double which_phi_class = RanGen->flat();
       if (which_phi_class < pPh1) {  //pPh1% in psPh1
         PhiV = phi_at + phi_rel_min + psPh1 * RanGen->flat();
         JdPhiV_dPhi_trans = fPh1 / pPh1 * TwoPi / psPh1;
       } else if (which_phi_class < pPh1 + pPh2) {  //further pPh2% in psPh2
         PhiV = phi_at + phi_rel_min + psPh2 * RanGen->flat();
         JdPhiV_dPhi_trans = fPh2 / pPh2 * TwoPi / psPh2;
       } else {  //remaining pPh3% in psPh3=[-Pi,Pi]
         PhiV = phi_at + phi_rel_min + psPh3 * RanGen->flat();
         JdPhiV_dPhi_trans = fPh3 / pPh3 * TwoPi / psPh3;
       }
 
       //shuffle PhiV into [-Pi,+Pi] interval
       if (PhiV < -Pi)
         PhiV += TwoPi;
       else if (PhiV > Pi)
         PhiV -= TwoPi;
 
       Nver++;
       trials += JdR_trans_sqrt * JdRxzV_dR_trans * JdPhiV_dPhi_trans;
       Trials++;
       if (trials > max_Trials)
         break;              //while (Id_sf.size() < 2) loop
       Ngen += (Nver - 1.);  //add number of generated vertices to initial cosmic events
 
       Vx_at = RxzV * sin(PhiV);  // [mm]
 
       Vy_at = h_sf;  // [mm] (SurfaceOfEarth + PlugWidth; Determine primary particle height below)
       //Vy_at = SimTree->shower_StartingAltitude*10. + h_sf; // [mm]
       //std::cout << "SimTree->shower_StartingAltitude*10=" << SimTree->shower_StartingAltitude*10 <<std::endl;
       Vz_at = RxzV * cos(PhiV);  // [mm]
 
       int NmuHitTargetSphere = 0;
       for (int imu = 0; imu < nmuons; ++imu) {
         Vx_mu[imu] = Vx_at + (-SimTree->particle__x[imu] * sin(NorthCMSzDeltaPhi) +
                               SimTree->particle__y[imu] * cos(NorthCMSzDeltaPhi)) *
                                  10;  //[mm] (Corsika cm to CMSCGEN mm)
         Vy_mu[imu] = h_sf;            //[mm] fixed at surface + PlugWidth
         Vz_mu[imu] = Vz_at + (SimTree->particle__x[imu] * cos(NorthCMSzDeltaPhi) +
                               SimTree->particle__y[imu] * sin(NorthCMSzDeltaPhi)) *
                                  10;  //[mm] (Corsika cm to CMSCGEN mm)
 
         //add atmospheric height to primary particle (default SimTree->shower_StartingAltitude = 0.)
         double pt_sec = sqrt(Px_mu[imu] * Px_mu[imu] + Pz_mu[imu] * Pz_mu[imu]);
         double theta_sec = atan2(std::fabs(Py_mu[imu]), pt_sec);
         double r_sec = sqrt((Vx_mu[imu] - Vx_at) * (Vx_mu[imu] - Vx_at) + (Vz_mu[imu] - Vz_at) * (Vz_mu[imu] - Vz_at));
         double h_prod = r_sec * tan(theta_sec);
         if (h_prod + h_sf > Vy_at)
           Vy_at = h_prod + h_sf;
 
         //only muons
         if (SimTree->particle__ParticleID[imu] != 5 && SimTree->particle__ParticleID[imu] != 6)
           continue;
 
         if (P_mu[imu] < MinP_CMS && AcptAllMu == false)
           continue;
 
         //check here if at least 2 muons make it to the target sphere
         double Vxz_mu = sqrt(Vx_mu[imu] * Vx_mu[imu] + Vz_mu[imu] * Vz_mu[imu]);
         theta_mu_max = atan((Vxz_mu + Target3dRadius) / (h_sf - Target3dRadius));
         theta_mu_min = atan((Vxz_mu - Target3dRadius) / (h_sf + Target3dRadius));
         if (Theta_mu[imu] > theta_mu_min && Theta_mu[imu] < theta_mu_max) {
           // check phi range (for a sphere with Target3dRadius around the target)
           double dPhi = Pi;
           if (Vxz_mu > Target3dRadius)
             dPhi = asin(Target3dRadius / Vxz_mu);
           double PhiPmu = atan2(Px_mu[imu], Pz_mu[imu]);  //muon phi
           double PhiVmu = atan2(Vx_mu[imu], Vz_mu[imu]);  //muon phi
           double rotPhi = PhiVmu + Pi;
           if (rotPhi > Pi)
             rotPhi -= TwoPi;
           double disPhi = std::fabs(rotPhi - PhiPmu);
           if (disPhi > Pi)
             disPhi = TwoPi - disPhi;
           if (disPhi < dPhi) {
             NmuHitTargetSphere++;
           }
         }
 
       }  //end imu for loop
 
       if (NmuHitTargetSphere < MultiMuonNmin)
         continue;  //while (Id_sf.size() < 2) loop
 
       //nmuons outgoing particle at SurFace
       Id_sf.clear();
       Px_sf.clear();
       Py_sf.clear();
       Pz_sf.clear();
       E_sf.clear();
       //M_sf_out.clear();
       Vx_sf.clear();
       Vy_sf.clear();
       Vz_sf.clear();
       T0_sf.clear();
 
       //nmuons particles at UnderGround
       Id_ug.clear();
       Px_ug.clear();
       Py_ug.clear();
       Pz_ug.clear();
       E_ug.clear();
       //M_ug.clear();
       Vx_ug.clear();
       Vy_ug.clear();
       Vz_ug.clear();
       T0_ug.clear();
 
       int Id_sf_this = 0;
       double Px_sf_this = 0., Py_sf_this = 0., Pz_sf_this = 0.;
       double E_sf_this = 0.;
       //double M_sf_this=0.;
       double Vx_sf_this = 0., Vy_sf_this = 0., Vz_sf_this = 0.;
       double T0_sf_this = 0.;
 
       T0_at = SimTree->shower_GH_t0 * SpeedOfLight;  // [mm]
 
       for (int imu = 0; imu < nmuons; ++imu) {
         if (P_mu[imu] < MinP_CMS && AcptAllMu == false)
           continue;
         //for the time being only muons
         if (SimTree->particle__ParticleID[imu] != 5 && SimTree->particle__ParticleID[imu] != 6)
           continue;
 
         Id_sf_this = SimTree->particle__ParticleID[imu];
         if (Id_sf_this == 5)
           Id_sf_this = -13;  //mu+
         else if (Id_sf_this == 6)
           Id_sf_this = 13;  //mu-
 
         else if (Id_sf_this == 1)
           Id_sf_this = 22;  //gamma
         else if (Id_sf_this == 2)
           Id_sf_this = -11;  //e+
         else if (Id_sf_this == 3)
           Id_sf_this = 11;  //e-
         else if (Id_sf_this == 7)
           Id_sf_this = 111;  //pi0
         else if (Id_sf_this == 8)
           Id_sf_this = 211;  //pi+
         else if (Id_sf_this == 9)
           Id_sf_this = -211;  //pi-
         else if (Id_sf_this == 10)
           Id_sf_this = 130;  //KL0
         else if (Id_sf_this == 11)
           Id_sf_this = 321;  //K+
         else if (Id_sf_this == 12)
           Id_sf_this = -321;  //K-
         else if (Id_sf_this == 13)
           Id_sf_this = 2112;  //n
         else if (Id_sf_this == 14)
           Id_sf_this = 2212;  //p
         else if (Id_sf_this == 15)
           Id_sf_this = -2212;  //pbar
         else if (Id_sf_this == 16)
           Id_sf_this = 310;  //Ks0
         else if (Id_sf_this == 17)
           Id_sf_this = 221;  //eta
         else if (Id_sf_this == 18)
           Id_sf_this = 3122;  //Lambda
 
         else {
           std::cout << "CosmicMuonGenerator.cc: Warning! Muon Id=" << Id_sf_this << " from file read in" << std::endl;
           Id_sf_this = 99999;  //trouble
         }
 
         T0_sf_this = SimTree->particle__Time[imu] * SpeedOfLight;  //in [mm]
 
         Px_sf_this = Px_mu[imu];
         Py_sf_this = Py_mu[imu];  //Corsika down going particles defined in -z direction!
         Pz_sf_this = Pz_mu[imu];
         E_sf_this = sqrt(P_mu[imu] * P_mu[imu] + MuonMass * MuonMass);
         Vx_sf_this = Vx_mu[imu];
         Vy_sf_this = Vy_mu[imu];  //[mm] fixed at surface + PlugWidth
         Vz_sf_this = Vz_mu[imu];
 
         OneMuoEvt.create(Id_sf_this,
                          Px_sf_this,
                          Py_sf_this,
                          Pz_sf_this,
                          E_sf_this,
                          MuonMass,
                          Vx_sf_this,
                          Vy_sf_this,
                          Vz_sf_this,
                          T0_sf_this);
         // if angles are ok, propagate to target
         if (goodOrientation()) {
           OneMuoEvt.propagate(ElossScaleFactor, RadiusOfTarget, ZDistOfTarget, ZCentrOfTarget, TrackerOnly, MTCCHalf);
         }
 
         if ((OneMuoEvt.hitTarget() && sqrt(OneMuoEvt.e() * OneMuoEvt.e() - MuonMass * MuonMass) > MinP_CMS) ||
             AcptAllMu == true) {
           Id_sf.push_back(Id_sf_this);
           Px_sf.push_back(Px_sf_this);
           Py_sf.push_back(Py_sf_this);
           Pz_sf.push_back(Pz_sf_this);
           E_sf.push_back(E_sf_this);
           //M_sf.push_back(M_sf_this);
           Vx_sf.push_back(Vx_sf_this);
           Vy_sf.push_back(Vy_sf_this);
           Vz_sf.push_back(Vz_sf_this);
           T0_sf.push_back(T0_sf_this);
           //T0_sf.push_back(0.); //synchronised arrival for 100% efficient full simulation tests
 
           Id_ug.push_back(OneMuoEvt.id());
           Px_ug.push_back(OneMuoEvt.px());
           Py_ug.push_back(OneMuoEvt.py());
           Pz_ug.push_back(OneMuoEvt.pz());
           E_ug.push_back(OneMuoEvt.e());
           //M_sf.push_back(OneMuoEvt.m());
           Vx_ug.push_back(OneMuoEvt.vx());
           Vy_ug.push_back(OneMuoEvt.vy());
           Vz_ug.push_back(OneMuoEvt.vz());
           T0_ug.push_back(OneMuoEvt.t0());
 
           NmuHitTarget++;
         }
       }
 
     }  // while (Id_sf.size() < 2); //end of do loop
 
     if (trials > max_Trials) {
       std::cout << "CosmicMuonGenerator.cc: Warning! trials reach max_trials=" << max_Trials
                 << " without accepting event!" << std::endl;
       if (Debug) {
         std::cout << " N(mu)=" << Id_ug.size();
         if (!Id_ug.empty())
           std::cout << " E[0]=" << E_ug[0] << " theta="
                     << acos(-Py_ug[0] / sqrt(Px_ug[0] * Px_ug[0] + Py_ug[0] * Py_ug[0] + Pz_ug[0] * Pz_ug[0]))
                     << " R_xz=" << sqrt(Vx_sf[0] * Vx_sf[0] + Vy_sf[0] * Vy_sf[0]);
         std::cout << " Theta_at=" << Theta_at << std::endl;
       }
       std::cout << "Unweighted int num of Trials = " << Trials << std::endl;
       std::cout << "trying next event (" << SimTree_jentry << ") from file" << std::endl;
       NskippedMultiMuonEvents++;
       continue;  //EvtRejected while loop: get next event from file
     } else {
       if (NmuHitTarget < MultiMuonNmin) {
         std::cout << "CosmicMuonGenerator.cc: Warning! less than " << MultiMuonNmin << " muons hit target: N(mu=)"
                   << NmuHitTarget << std::endl;
         std::cout << "trying next event (" << SimTree_jentry << ") from file" << std::endl;
         NskippedMultiMuonEvents++;
         continue;  //EvtRejected while loop: get next event from file
       } else {     //if (MuInMaxDist) {
 
         //re-adjust T0's of surviving muons shifted to trigger time box
         //(possible T0 increase due to propagation (loss of energy/speed + travelled distance))
         double T0_ug_min, T0_ug_max;
         T0_ug_min = T0_ug_max = T0_ug[0];
         double Tbox = (MaxT0 - MinT0) * SpeedOfLight;  // [mm]
         double minDeltaT0 = 2 * Tbox;
         for (unsigned int imu = 0; imu < Id_ug.size(); ++imu) {
           double T0_this = T0_ug[imu];
           if (T0_this < T0_ug_min)
             T0_ug_min = T0_this;
           if (T0_this > T0_ug_max)
             T0_ug_max = T0_this;
           if (Debug)
             std::cout << "imu=" << imu << " T0_this=" << T0_this
                       << " P=" << sqrt(pow(Px_ug[imu], 2) + pow(Py_ug[imu], 2) + pow(Pz_ug[imu], 2)) << std::endl;
           for (unsigned int jmu = 0; jmu < imu; ++jmu) {
             if (std::fabs(T0_ug[imu] - T0_ug[jmu]) < minDeltaT0)
               minDeltaT0 = std::fabs(T0_ug[imu] - T0_ug[jmu]);
           }
         }
 
         if (int(Id_ug.size()) >= MultiMuonNmin && MultiMuonNmin >= 2 && minDeltaT0 > Tbox)
           continue;  //EvtRejected while loop: get next event from file
 
         double T0_min = T0_ug_min + MinT0 * SpeedOfLight;  //-12.5ns * c [mm]
         double T0_max = T0_ug_max + MaxT0 * SpeedOfLight;  //+12.5ns * c [mm]
 
         //ckeck if >= NmuMin in time box, else throw new random number + augment evt weight
         int TboxTrials = 0;
         int NmuInTbox;
         double T0_offset, T0diff;
         for (int tboxtrial = 0; tboxtrial < 1000; ++tboxtrial) {  //max 1000 trials
           T0_offset = RanGen->flat() * (T0_max - T0_min);         // [mm]
           TboxTrials++;
           T0diff = T0_offset - T0_max;  // [mm]
           NmuInTbox = 0;
           for (unsigned int imu = 0; imu < Id_ug.size(); ++imu) {
             if (T0_ug[imu] + T0diff > MinT0 * SpeedOfLight && T0_ug[imu] + T0diff < MaxT0 * SpeedOfLight)
               NmuInTbox++;
           }
           if (NmuInTbox >= MultiMuonNmin)
             break;
         }
         if (NmuInTbox < MultiMuonNmin)
           continue;  //EvtRejected while loop: get next event from file
 
         if (Debug)
           std::cout << "initial T0_at=" << T0_at << " T0_min=" << T0_min << " T0_max=" << T0_max
                     << " T0_offset=" << T0_offset;
         T0_at += T0diff;  //[mm]
         if (Debug)
           std::cout << " T0diff=" << T0diff << std::endl;
         for (unsigned int imu = 0; imu < Id_ug.size(); ++imu) {  //adjust @ surface + underground
           if (Debug)
             std::cout << "before: T0_sf[" << imu << "]=" << T0_sf[imu] << "  T0_ug=" << T0_ug[imu];
           T0_sf[imu] += T0diff;
           T0_ug[imu] += T0diff;
           if (Debug)
             std::cout << "   after: T0_sf[" << imu << "]=" << T0_sf[imu] << "  T0_ug=" << T0_ug[imu] << std::endl;
         }
         if (Debug)
           std::cout << "T0diff=" << T0diff << " T0_at=" << T0_at << std::endl;
 
         Nsel += 1;
         EventWeight = JdR_trans_sqrt * JdRxzV_dR_trans * JdPhiV_dPhi_trans / (trials * TboxTrials);
         EvtRejected = false;
         if (Debug)
           std::cout << "CosmicMuonGenerator.cc: Theta_at=" << Theta_at << " phi_at=" << phi_at << " Px_at=" << Px_at
                     << " Py_at=" << Py_at << " Pz_at=" << Pz_at << " T0_at=" << T0_at << " Vx_at=" << Vx_at
                     << " Vy_at=" << Vy_at << " Vz_at=" << Vz_at << " EventWeight=" << EventWeight
                     << " Nmuons=" << Id_sf.size() << std::endl;
       }
     }
 
   }  //while loop EvtRejected
 
   return true;  //write event to HepMC;
 }

◆ runCMG()

void CosmicMuonGenerator::runCMG ( )

Definition at line 10 of file CosmicMuonGenerator.cc.

References initialize(), nextEvent(), NumberOfEvents, and terminate().

                                  {
   initialize();
   for (unsigned int iGen = 0; iGen < NumberOfEvents; ++iGen) {
     nextEvent();
   }
   terminate();
 }

◆ setAcptAllMu()

void CosmicMuonGenerator::setAcptAllMu ( bool AllMu )

Definition at line 1277 of file CosmicMuonGenerator.cc.

References AcptAllMu, and NotInitialized.

                                                  {
   if (NotInitialized)
     AcptAllMu = AllMu;
 }

◆ setClayWidth()

void CosmicMuonGenerator::setClayWidth ( double ClayLaeyrWidth )

Definition at line 1257 of file CosmicMuonGenerator.cc.

References ClayWidth, and NotInitialized.

                                                             {
   if (NotInitialized)
     ClayWidth = ClayLayerWidth;
 }

◆ setElossScaleFactor()

void CosmicMuonGenerator::setElossScaleFactor ( double ElossScaleFact )

Definition at line 1173 of file CosmicMuonGenerator.cc.

References ElossScaleFactor, and NotInitialized.

                                                                    {
   if (NotInitialized)
     ElossScaleFactor = ElossScaleFact;
 }

◆ setMaxEnu()

void CosmicMuonGenerator::setMaxEnu ( double MaxEn )

Definition at line 1266 of file CosmicMuonGenerator.cc.

References MaxEnu, and NotInitialized.

                                                 {
   if (NotInitialized)
     MaxEnu = MaxEn;
 }

◆ setMaxP()

void CosmicMuonGenerator::setMaxP ( double P )

Definition at line 1138 of file CosmicMuonGenerator.cc.

References MaxP, and NotInitialized.

                                           {
   if (NotInitialized)
     MaxP = P;
 }

◆ setMaxPhi()

void CosmicMuonGenerator::setMaxPhi ( double Phi )

Definition at line 1158 of file CosmicMuonGenerator.cc.

References Deg2Rad, MaxPhi, NotInitialized, and VtxSmearedParameters_cfi::Phi.

                                               {
   if (NotInitialized)
     MaxPhi = Phi * Deg2Rad;
 }

◆ setMaxT0()

void CosmicMuonGenerator::setMaxT0 ( double T0 )

Definition at line 1168 of file CosmicMuonGenerator.cc.

References MaxT0, and NotInitialized.

                                             {
   if (NotInitialized)
     MaxT0 = T0;
 }

◆ setMaxTheta()

void CosmicMuonGenerator::setMaxTheta ( double Theta )

Definition at line 1148 of file CosmicMuonGenerator.cc.

References Deg2Rad, MaxTheta, and NotInitialized.

                                                   {
   if (NotInitialized)
     MaxTheta = Theta * Deg2Rad;
 }

◆ setMinEnu()

void CosmicMuonGenerator::setMinEnu ( double MinEn )

Definition at line 1262 of file CosmicMuonGenerator.cc.

References MinEnu, and NotInitialized.

                                                 {
   if (NotInitialized)
     MinEnu = MinEn;
 }

◆ setMinP()

void CosmicMuonGenerator::setMinP ( double P )

Definition at line 1128 of file CosmicMuonGenerator.cc.

References MinP, and NotInitialized.

                                           {
   if (NotInitialized)
     MinP = P;
 }

◆ setMinP_CMS()

void CosmicMuonGenerator::setMinP_CMS ( double P )

Definition at line 1133 of file CosmicMuonGenerator.cc.

References MinP_CMS, and NotInitialized.

                                               {
   if (NotInitialized)
     MinP_CMS = P;
 }

◆ setMinPhi()

void CosmicMuonGenerator::setMinPhi ( double Phi )

Definition at line 1153 of file CosmicMuonGenerator.cc.

References Deg2Rad, MinPhi, NotInitialized, and VtxSmearedParameters_cfi::Phi.

                                               {
   if (NotInitialized)
     MinPhi = Phi * Deg2Rad;
 }

◆ setMinT0()

void CosmicMuonGenerator::setMinT0 ( double T0 )

Definition at line 1163 of file CosmicMuonGenerator.cc.

References MinT0, and NotInitialized.

                                             {
   if (NotInitialized)
     MinT0 = T0;
 }

◆ setMinTheta()

void CosmicMuonGenerator::setMinTheta ( double Theta )

Definition at line 1143 of file CosmicMuonGenerator.cc.

References Deg2Rad, MinTheta, and NotInitialized.

                                                   {
   if (NotInitialized)
     MinTheta = Theta * Deg2Rad;
 }

◆ setMTCCHalf()

void CosmicMuonGenerator::setMTCCHalf ( bool MTCC )

Definition at line 1224 of file CosmicMuonGenerator.cc.

References MTCCHalf, and NotInitialized.

                                                {
   if (NotInitialized)
     MTCCHalf = MTCC;
 }

◆ setMultiMuon()

void CosmicMuonGenerator::setMultiMuon ( bool MultiMu )

Definition at line 1198 of file CosmicMuonGenerator.cc.

References MultiMuon, and NotInitialized.

                                                    {
   if (NotInitialized)
     MultiMuon = MultiMu;
 }

◆ setMultiMuonFileFirstEvent()

void CosmicMuonGenerator::setMultiMuonFileFirstEvent ( int MultiMuFile1stEvt )

Definition at line 1206 of file CosmicMuonGenerator.cc.

References MultiMuonFileFirstEvent, and NotInitialized.

                                                                           {
   if (NotInitialized)
     MultiMuonFileFirstEvent = MultiMuFile1stEvt;
 }

◆ setMultiMuonFileName()

void CosmicMuonGenerator::setMultiMuonFileName ( std::string MultiMuonFileName )

Definition at line 1202 of file CosmicMuonGenerator.cc.

References MultiMuonFileName, and NotInitialized.

                                                                     {
   if (NotInitialized)
     MultiMuonFileName = MultiMuFile;
 }

◆ setMultiMuonNmin()

void CosmicMuonGenerator::setMultiMuonNmin ( int MultiMuNmin )

Definition at line 1210 of file CosmicMuonGenerator.cc.

References MultiMuonNmin, and NotInitialized.

                                                           {
   if (NotInitialized)
     MultiMuonNmin = MultiMuNmin;
 }

◆ setNumberOfEvents()

void CosmicMuonGenerator::setNumberOfEvents ( unsigned int N )

Definition at line 1118 of file CosmicMuonGenerator.cc.

References N, NotInitialized, and NumberOfEvents.

                                                           {
   if (NotInitialized)
     NumberOfEvents = N;
 }

◆ setNuProdAlt()

void CosmicMuonGenerator::setNuProdAlt ( double NuPrdAlt )

Definition at line 1270 of file CosmicMuonGenerator.cc.

References NotInitialized, and NuProdAlt.

                                                       {
   if (NotInitialized)
     NuProdAlt = NuPrdAlt;
 }

◆ setPlugVx()

void CosmicMuonGenerator::setPlugVx ( double PlugVtx )

Definition at line 1229 of file CosmicMuonGenerator.cc.

References NotInitialized, and PlugVx.

                                                   {
   if (NotInitialized)
     PlugVx = PlugVtx;
 }

◆ setPlugVz()

void CosmicMuonGenerator::setPlugVz ( double PlugVtz )

Definition at line 1233 of file CosmicMuonGenerator.cc.

References NotInitialized, and PlugVz.

                                                   {
   if (NotInitialized)
     PlugVz = PlugVtz;
 }

◆ setRadiusOfTarget()

void CosmicMuonGenerator::setRadiusOfTarget ( double R )

Definition at line 1178 of file CosmicMuonGenerator.cc.

References NotInitialized, dttmaxenums::R, and RadiusOfTarget.

                                                     {
   if (NotInitialized)
     RadiusOfTarget = R;
 }

◆ setRandomEngine()

void CosmicMuonGenerator::setRandomEngine ( CLHEP::HepRandomEngine * v )

Definition at line 18 of file CosmicMuonGenerator.cc.

References Cosmics, delRanGen, RanGen, CMSCGEN::setRandomEngine(), and findQualityFiles::v.

                                                                  {
   if (delRanGen)
     delete RanGen;
   RanGen = v;
   delRanGen = false;
   Cosmics->setRandomEngine(v);
 }

◆ setRanSeed()

void CosmicMuonGenerator::setRanSeed ( int N )

Definition at line 1123 of file CosmicMuonGenerator.cc.

References N, NotInitialized, and RanSeed.

                                           {
   if (NotInitialized)
     RanSeed = N;
 }

◆ setRhoAir()

void CosmicMuonGenerator::setRhoAir ( double VarRhoAir )

Definition at line 1237 of file CosmicMuonGenerator.cc.

References NotInitialized, and RhoAir.

                                                     {
   if (NotInitialized)
     RhoAir = VarRhoAir;
 }

◆ setRhoClay()

void CosmicMuonGenerator::setRhoClay ( double VarRhoClay )

Definition at line 1249 of file CosmicMuonGenerator.cc.

References NotInitialized, and RhoClay.

                                                       {
   if (NotInitialized)
     RhoClay = VarRhoClay;
 }

◆ setRhoPlug()

void CosmicMuonGenerator::setRhoPlug ( double VarRhoPlug )

Definition at line 1253 of file CosmicMuonGenerator.cc.

References NotInitialized, and RhoPlug.

                                                       {
   if (NotInitialized)
     RhoPlug = VarRhoPlug;
 }

◆ setRhoRock()

void CosmicMuonGenerator::setRhoRock ( double VarRhoRock )

Definition at line 1245 of file CosmicMuonGenerator.cc.

References NotInitialized, and RhoRock.

                                                       {
   if (NotInitialized)
     RhoRock = VarRhoRock;
 }

◆ setRhoWall()

void CosmicMuonGenerator::setRhoWall ( double VarRhoSWall )

Definition at line 1241 of file CosmicMuonGenerator.cc.

References NotInitialized, and RhoWall.

                                                       {
   if (NotInitialized)
     RhoWall = VarRhoWall;
 }

◆ setTIFOnly_constant()

void CosmicMuonGenerator::setTIFOnly_constant ( bool TIF )

Definition at line 1215 of file CosmicMuonGenerator.cc.

References NotInitialized, and TIFOnly_constant.

                                                       {
   if (NotInitialized)
     TIFOnly_constant = TIF;
 }

◆ setTIFOnly_linear()

void CosmicMuonGenerator::setTIFOnly_linear ( bool TIF )

Definition at line 1220 of file CosmicMuonGenerator.cc.

References NotInitialized, and TIFOnly_linear.

                                                     {
   if (NotInitialized)
     TIFOnly_linear = TIF;
 }

◆ setTrackerOnly()

void CosmicMuonGenerator::setTrackerOnly ( bool Tracker )

Definition at line 1193 of file CosmicMuonGenerator.cc.

References NotInitialized, align::Tracker, and TrackerOnly.

                                                      {
   if (NotInitialized)
     TrackerOnly = Tracker;
 }

◆ setZCentrOfTarget()

void CosmicMuonGenerator::setZCentrOfTarget ( double Z )

Definition at line 1188 of file CosmicMuonGenerator.cc.

References NotInitialized, beamSpotPI::Z, and ZCentrOfTarget.

                                                     {
   if (NotInitialized)
     ZCentrOfTarget = Z;
 }

◆ setZDistOfTarget()

void CosmicMuonGenerator::setZDistOfTarget ( double Z )

Definition at line 1183 of file CosmicMuonGenerator.cc.

References NotInitialized, beamSpotPI::Z, and ZDistOfTarget.

                                                    {
   if (NotInitialized)
     ZDistOfTarget = Z;
 }

◆ terminate()

void CosmicMuonGenerator::terminate ( void )

Definition at line 831 of file CosmicMuonGenerator.cc.

References custom_jme_cff::area, funct::cos(), gather_cfg::cout, Deg2Rad, MillePedeFileConverter_cfg::e, ElossScaleFactor, EventRate, CMSCGENnorm::events_n100cos(), createfilelist::int, MaxP, MaxPhi, MaxT0, MaxTheta, MinP, MinPhi, MinT0, MinTheta, Ndiced, Ngen, CMSCGENnorm::norm(), Norm, Nsel, NumberOfEvents, Pi, Rad2Deg, RadiusOfTarget, rateErr_stat, rateErr_syst, mathSSE::sqrt(), SurfaceOfEarth, SurfaceRadius, and ZDistOfTarget.

Referenced by runCMG().

                                     {
   if (NumberOfEvents > 0) {
     std::cout << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << "***                                                   ***" << std::endl;
     std::cout << "***    C O S M I C   M U O N   S T A T I S T I C S    ***" << std::endl;
     std::cout << "***                                                   ***" << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << std::endl;
     std::cout << "       number of initial cosmic events:  " << int(Ngen) << std::endl;
     std::cout << "       number of actually diced events:  " << int(Ndiced) << std::endl;
     std::cout << "       number of generated and accepted events:  " << int(Nsel) << std::endl;
     double selEff = Nsel / Ngen;  // selection efficiency
     std::cout << "       event selection efficiency:  " << selEff * 100. << "%" << std::endl;
     int n100cos =
         Norm->events_n100cos(0., 0.);  //get final amount of cosmics in defined range for normalisation of flux
     std::cout << "       events with ~100 GeV and 1 - cos(theta) < 1/2pi: " << n100cos << std::endl;
     std::cout << std::endl;
     std::cout << "       momentum range: " << MinP << " ... " << MaxP << " GeV" << std::endl;
     std::cout << "       theta  range:   " << MinTheta * Rad2Deg << " ... " << MaxTheta * Rad2Deg << " deg"
               << std::endl;
     std::cout << "       phi    range:   " << MinPhi * Rad2Deg << " ... " << MaxPhi * Rad2Deg << " deg" << std::endl;
     std::cout << "       time   range:   " << MinT0 << " ... " << MaxT0 << " ns" << std::endl;
     std::cout << "       energy  loss:   " << ElossScaleFactor * 100. << "%" << std::endl;
     std::cout << std::endl;
     double area = 1.e-6 * Pi * SurfaceRadius * SurfaceRadius;  // area on surface [m^2]
     if (MinTheta > 90. * Deg2Rad)                              //upgoing muons from neutrinos)
       std::cout << "       area of initial cosmics at CMS detector bottom surface:   " << area << " m^2" << std::endl;
     else
       std::cout << "       area of initial cosmics on Surface + PlugWidth:   " << area << " m^2" << std::endl;
     std::cout << "       depth of CMS detector (from Surface):   " << SurfaceOfEarth / 1000 << " m" << std::endl;
 
     //at least 100 evts., and
     //downgoing inside theta parametersisation range
     //or upgoing neutrino muons
     if ((n100cos > 0 && MaxTheta < 84.26 * Deg2Rad) || MinTheta > 90. * Deg2Rad) {
       // rate: corrected for area and selection-Eff. and normalized to known flux, integration over solid angle (dOmega) is implicit
       // flux is normalised with respect to known flux of vertical 100GeV muons in area at suface level
       // rate seen by detector is lower than rate at surface area, so has to be corrected for selection-Eff.
       // normalisation factor has unit [1/s/m^2]
       // rate = N/time --> normalization factor gives 1/runtime/area
       // normalization with respect to number of actually diced events (Ndiced)
 
       if (MinTheta > 90. * Deg2Rad) {  //upgoing muons from neutrinos)
         double Omega = (cos(MinTheta) - cos(MaxTheta)) * (MaxPhi - MinPhi);
         //EventRate = (Ndiced * 3.e-13) * Omega * area*1.e4 * selEff;//area in cm, flux=3.e-13cm^-2s^-1sr^-1
         EventRate = (Ndiced * 3.e-13) * Omega * 4. * RadiusOfTarget * ZDistOfTarget * 1.e-2 *
                     selEff;                               //area in cm, flux=3.e-13cm^-2s^-1sr^-1
         rateErr_stat = EventRate / sqrt((double)Ndiced);  // stat. rate error
         rateErr_syst = EventRate / 3.e-13 * 1.0e-13;      // syst. rate error, from error of known flux
       } else {
         EventRate = (Ndiced * Norm->norm(n100cos)) * area * selEff;
         rateErr_stat = EventRate / sqrt((double)n100cos);  // stat. rate error
         rateErr_syst = EventRate / 2.63e-3 * 0.06e-3;      // syst. rate error, from error of known flux
       }
 
       // normalisation in region 1.-cos(theta) < 1./(2.*Pi), if MaxTheta even lower correct for this
       if (MaxTheta < 0.572) {
         double spacean = 2. * Pi * (1. - cos(MaxTheta));
         EventRate = (Ndiced * Norm->norm(n100cos)) * area * selEff * spacean;
         rateErr_stat = EventRate / sqrt((double)n100cos);  // rate error
         rateErr_syst = EventRate / 2.63e-3 * 0.06e-3;      // syst. rate error, from error of known flux
       }
 
     } else {
       EventRate = Nsel;  //no info as no muons at 100 GeV
       rateErr_stat = Nsel;
       rateErr_syst = Nsel;
       std::cout << std::endl;
       if (MinP > 100.)
         std::cout << " !!! MinP > 100 GeV. Cannot apply normalisation!" << std::endl;
       else if (MaxTheta > 84.26 * Deg2Rad)
         std::cout << " !!! Note: generated cosmics exceed parameterisation. No flux calculated!" << std::endl;
 
       else
         std::cout << " !!! Not enough statistics to apply normalisation (rate=1 +- 1) !!!" << std::endl;
     }
 
     std::cout << "!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!" << std::endl;
     std::cout << "       rate is " << EventRate << " +-" << rateErr_stat << " (stat) "
               << "+-" << rateErr_syst << " (syst) "
               << " muons per second" << std::endl;
     if (EventRate != 0)
       std::cout << "       number of events corresponds to " << Nsel / EventRate << " s"
                 << std::endl;  //runtime at CMS = Nsel/rate
     std::cout << "!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!" << std::endl;
     std::cout << std::endl;
     std::cout << "*********************************************************" << std::endl;
     std::cout << "*********************************************************" << std::endl;
   }
 }

Member Data Documentation

◆ AcptAllMu

bool CosmicMuonGenerator::AcptAllMu

private

Definition at line 221 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), nextMultiEvent(), and setAcptAllMu().

◆ ClayWidth

double CosmicMuonGenerator::ClayWidth

private

Definition at line 214 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), and setClayWidth().

◆ Cosmics

CMSCGEN* CosmicMuonGenerator::Cosmics

private

Definition at line 168 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), nextEvent(), setRandomEngine(), and ~CosmicMuonGenerator().

◆ delRanGen

bool CosmicMuonGenerator::delRanGen

private

Definition at line 225 of file CosmicMuonGenerator.h.

Referenced by initialize(), setRandomEngine(), and ~CosmicMuonGenerator().

◆ E_at

double CosmicMuonGenerator::E_at

Definition at line 116 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ E_sf

std::vector<double> CosmicMuonGenerator::E_sf

Definition at line 138 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ E_ug

std::vector<double> CosmicMuonGenerator::E_ug

Definition at line 149 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ ElossScaleFactor

double CosmicMuonGenerator::ElossScaleFactor

private

Definition at line 181 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), nextEvent(), nextMultiEvent(), setElossScaleFactor(), and terminate().

◆ EventRate

double CosmicMuonGenerator::EventRate

private

Definition at line 195 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), getRate(), and terminate().

◆ EventWeight

double CosmicMuonGenerator::EventWeight

Definition at line 109 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Id_at

int CosmicMuonGenerator::Id_at

Definition at line 112 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Id_sf

std::vector<int> CosmicMuonGenerator::Id_sf

Definition at line 134 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Id_ug

std::vector<int> CosmicMuonGenerator::Id_ug

Definition at line 145 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ MaxEnu

double CosmicMuonGenerator::MaxEnu

private

Definition at line 218 of file CosmicMuonGenerator.h.

Referenced by checkIn(), initialize(), and setMaxEnu().

◆ MaxP

double CosmicMuonGenerator::MaxP

private

Definition at line 174 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), initEvDis(), initialize(), setMaxP(), and terminate().

◆ MaxPhi

double CosmicMuonGenerator::MaxPhi

private

Definition at line 178 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), initialize(), nextEvent(), setMaxPhi(), and terminate().

◆ MaxT0

double CosmicMuonGenerator::MaxT0

private

Definition at line 180 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), nextEvent(), nextMultiEvent(), setMaxT0(), and terminate().

◆ MaxTheta

double CosmicMuonGenerator::MaxTheta

private

Definition at line 176 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), initialize(), setMaxTheta(), and terminate().

◆ MinEnu

double CosmicMuonGenerator::MinEnu

private

Definition at line 217 of file CosmicMuonGenerator.h.

Referenced by checkIn(), initialize(), and setMinEnu().

◆ MinP

double CosmicMuonGenerator::MinP

private

Definition at line 172 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), initEvDis(), initialize(), setMinP(), and terminate().

◆ MinP_CMS

double CosmicMuonGenerator::MinP_CMS

private

Definition at line 173 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), nextEvent(), nextMultiEvent(), and setMinP_CMS().

◆ MinPhi

double CosmicMuonGenerator::MinPhi

private

Definition at line 177 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), initialize(), nextEvent(), setMinPhi(), and terminate().

◆ MinT0

double CosmicMuonGenerator::MinT0

private

Definition at line 179 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), nextEvent(), nextMultiEvent(), setMinT0(), and terminate().

◆ MinTheta

double CosmicMuonGenerator::MinTheta

private

Definition at line 175 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), goodOrientation(), initialize(), nextEvent(), setMinTheta(), and terminate().

◆ MTCCHalf

bool CosmicMuonGenerator::MTCCHalf

private

Definition at line 193 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), nextEvent(), nextMultiEvent(), and setMTCCHalf().

◆ MultiIn

TFile* CosmicMuonGenerator::MultiIn

private

Definition at line 157 of file CosmicMuonGenerator.h.

Referenced by initialize().

◆ MultiMuon

bool CosmicMuonGenerator::MultiMuon

private

Definition at line 187 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setMultiMuon().

◆ MultiMuonFileFirstEvent

int CosmicMuonGenerator::MultiMuonFileFirstEvent

private

Definition at line 189 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setMultiMuonFileFirstEvent().

◆ MultiMuonFileName

std::string CosmicMuonGenerator::MultiMuonFileName

private

Definition at line 188 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setMultiMuonFileName().

◆ MultiMuonNmin

int CosmicMuonGenerator::MultiMuonNmin

private

Definition at line 190 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), nextMultiEvent(), and setMultiMuonNmin().

◆ MultiTree

TTree* CosmicMuonGenerator::MultiTree

private

Definition at line 158 of file CosmicMuonGenerator.h.

Referenced by initialize().

◆ NcloseMultiMuonEvents

int CosmicMuonGenerator::NcloseMultiMuonEvents

private

Definition at line 162 of file CosmicMuonGenerator.h.

Referenced by initialize(), and nextMultiEvent().

◆ Ndiced

double CosmicMuonGenerator::Ndiced

private

Definition at line 202 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), nextEvent(), and terminate().

◆ Ngen

double CosmicMuonGenerator::Ngen

private

Definition at line 200 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), nextEvent(), nextMultiEvent(), and terminate().

◆ Norm

CMSCGENnorm* CosmicMuonGenerator::Norm

private

Definition at line 166 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), nextEvent(), terminate(), and ~CosmicMuonGenerator().

◆ NotInitialized

bool CosmicMuonGenerator::NotInitialized

private

◆ Nsel

double CosmicMuonGenerator::Nsel

private

Definition at line 201 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), nextEvent(), nextMultiEvent(), and terminate().

◆ NskippedMultiMuonEvents

int CosmicMuonGenerator::NskippedMultiMuonEvents

private

Definition at line 163 of file CosmicMuonGenerator.h.

Referenced by initialize(), and nextMultiEvent().

◆ NumberOfEvents

unsigned int CosmicMuonGenerator::NumberOfEvents

private

Definition at line 170 of file CosmicMuonGenerator.h.

Referenced by checkIn(), CosmicMuonGenerator(), initialize(), runCMG(), setNumberOfEvents(), and terminate().

◆ NuProdAlt

double CosmicMuonGenerator::NuProdAlt

private

Definition at line 219 of file CosmicMuonGenerator.h.

Referenced by initialize(), and setNuProdAlt().

◆ OneMuoEvt

SingleParticleEvent CosmicMuonGenerator::OneMuoEvt

Definition at line 107 of file CosmicMuonGenerator.h.

Referenced by displayEv(), goodOrientation(), initialize(), nextEvent(), and nextMultiEvent().

◆ P_mu

std::vector<double> CosmicMuonGenerator::P_mu

Definition at line 127 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ PlugVx

double CosmicMuonGenerator::PlugVx

private

Definition at line 205 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setPlugVx().

◆ PlugVz

double CosmicMuonGenerator::PlugVz

private

Definition at line 206 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setPlugVz().

◆ Px_at

double CosmicMuonGenerator::Px_at

Definition at line 113 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Px_mu

std::vector<double> CosmicMuonGenerator::Px_mu

Definition at line 124 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Px_sf

std::vector<double> CosmicMuonGenerator::Px_sf

Definition at line 135 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Px_ug

std::vector<double> CosmicMuonGenerator::Px_ug

Definition at line 146 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Py_at

double CosmicMuonGenerator::Py_at

Definition at line 114 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Py_mu

std::vector<double> CosmicMuonGenerator::Py_mu

Definition at line 125 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Py_sf

std::vector<double> CosmicMuonGenerator::Py_sf

Definition at line 136 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Py_ug

std::vector<double> CosmicMuonGenerator::Py_ug

Definition at line 147 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Pz_at

double CosmicMuonGenerator::Pz_at

Definition at line 115 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Pz_mu

std::vector<double> CosmicMuonGenerator::Pz_mu

Definition at line 126 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Pz_sf

std::vector<double> CosmicMuonGenerator::Pz_sf

Definition at line 137 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Pz_ug

std::vector<double> CosmicMuonGenerator::Pz_ug

Definition at line 148 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ RadiusOfTarget

double CosmicMuonGenerator::RadiusOfTarget

private

Definition at line 182 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), nextEvent(), nextMultiEvent(), setRadiusOfTarget(), and terminate().

◆ RanGen

CLHEP::HepRandomEngine* CosmicMuonGenerator::RanGen

private

Definition at line 224 of file CosmicMuonGenerator.h.

Referenced by initialize(), nextEvent(), nextMultiEvent(), setRandomEngine(), and ~CosmicMuonGenerator().

◆ RanSeed

int CosmicMuonGenerator::RanSeed

private

Definition at line 171 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setRanSeed().

◆ rateErr_stat

double CosmicMuonGenerator::rateErr_stat

private

Definition at line 196 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), and terminate().

◆ rateErr_syst

double CosmicMuonGenerator::rateErr_syst

private

Definition at line 197 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), and terminate().

◆ RhoAir

double CosmicMuonGenerator::RhoAir

private

Definition at line 209 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setRhoAir().

◆ RhoClay

double CosmicMuonGenerator::RhoClay

private

Definition at line 212 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setRhoClay().

◆ RhoPlug

double CosmicMuonGenerator::RhoPlug

private

Definition at line 213 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setRhoPlug().

◆ RhoRock

double CosmicMuonGenerator::RhoRock

private

Definition at line 211 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setRhoRock().

◆ RhoWall

double CosmicMuonGenerator::RhoWall

private

Definition at line 210 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setRhoWall().

◆ SimTree

sim* CosmicMuonGenerator::SimTree

private

Definition at line 159 of file CosmicMuonGenerator.h.

Referenced by initialize(), and nextMultiEvent().

◆ SimTree_jentry

ULong64_t CosmicMuonGenerator::SimTree_jentry

private

Definition at line 161 of file CosmicMuonGenerator.h.

Referenced by initialize(), and nextMultiEvent().

◆ SimTreeEntries

ULong64_t CosmicMuonGenerator::SimTreeEntries

private

Definition at line 160 of file CosmicMuonGenerator.h.

Referenced by initialize(), and nextMultiEvent().

◆ SumIntegrals

double CosmicMuonGenerator::SumIntegrals

private

Definition at line 199 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator().

◆ SurfaceRadius

double CosmicMuonGenerator::SurfaceRadius

private

Definition at line 204 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), nextEvent(), nextMultiEvent(), and terminate().

◆ T0_at

double CosmicMuonGenerator::T0_at

Definition at line 121 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ T0_sf

std::vector<double> CosmicMuonGenerator::T0_sf

Definition at line 143 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ T0_ug

std::vector<double> CosmicMuonGenerator::T0_ug

Definition at line 154 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Target3dRadius

double CosmicMuonGenerator::Target3dRadius

private

Definition at line 203 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), goodOrientation(), initialize(), nextEvent(), and nextMultiEvent().

◆ Theta_at

double CosmicMuonGenerator::Theta_at

Definition at line 122 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Theta_mu

std::vector<double> CosmicMuonGenerator::Theta_mu

Definition at line 132 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ TIFOnly_constant

bool CosmicMuonGenerator::TIFOnly_constant

private

Definition at line 191 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setTIFOnly_constant().

◆ TIFOnly_linear

bool CosmicMuonGenerator::TIFOnly_linear

private

Definition at line 192 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), and setTIFOnly_linear().

◆ TrackerOnly

bool CosmicMuonGenerator::TrackerOnly

private

Definition at line 186 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), displayEv(), initEvDis(), initialize(), nextEvent(), nextMultiEvent(), and setTrackerOnly().

◆ Trials

double CosmicMuonGenerator::Trials

Definition at line 110 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Vx_at

double CosmicMuonGenerator::Vx_at

Definition at line 118 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Vx_mu

std::vector<double> CosmicMuonGenerator::Vx_mu

Definition at line 128 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Vx_sf

std::vector<double> CosmicMuonGenerator::Vx_sf

Definition at line 140 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Vx_ug

std::vector<double> CosmicMuonGenerator::Vx_ug

Definition at line 151 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Vxz_mu

double CosmicMuonGenerator::Vxz_mu

Definition at line 131 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Vy_at

double CosmicMuonGenerator::Vy_at

Definition at line 119 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Vy_mu

std::vector<double> CosmicMuonGenerator::Vy_mu

Definition at line 129 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Vy_sf

std::vector<double> CosmicMuonGenerator::Vy_sf

Definition at line 141 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Vy_ug

std::vector<double> CosmicMuonGenerator::Vy_ug

Definition at line 152 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Vz_at

double CosmicMuonGenerator::Vz_at

Definition at line 120 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Vz_mu

std::vector<double> CosmicMuonGenerator::Vz_mu

Definition at line 130 of file CosmicMuonGenerator.h.

Referenced by nextMultiEvent().

◆ Vz_sf

std::vector<double> CosmicMuonGenerator::Vz_sf

Definition at line 142 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ Vz_ug

std::vector<double> CosmicMuonGenerator::Vz_ug

Definition at line 153 of file CosmicMuonGenerator.h.

Referenced by nextEvent(), and nextMultiEvent().

◆ ZCentrOfTarget

double CosmicMuonGenerator::ZCentrOfTarget

private

Definition at line 185 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), nextEvent(), nextMultiEvent(), and setZCentrOfTarget().

◆ ZDistOfTarget

double CosmicMuonGenerator::ZDistOfTarget

private

Definition at line 183 of file CosmicMuonGenerator.h.

Referenced by CosmicMuonGenerator(), initialize(), nextEvent(), nextMultiEvent(), setZDistOfTarget(), and terminate().

Public Member Functions

Public Attributes

Private Member Functions

Private Attributes

Detailed Description

Constructor & Destructor Documentation

◆ CosmicMuonGenerator()

◆ ~CosmicMuonGenerator()

Member Function Documentation

◆ checkIn()

◆ displayEv()

◆ getRate()

◆ goodOrientation()

◆ initEvDis()

◆ initialize()

◆ nextEvent()

◆ nextMultiEvent()

◆ runCMG()

◆ setAcptAllMu()

◆ setClayWidth()

◆ setElossScaleFactor()

◆ setMaxEnu()

◆ setMaxP()

◆ setMaxPhi()

◆ setMaxT0()

◆ setMaxTheta()

◆ setMinEnu()

◆ setMinP()

◆ setMinP_CMS()

◆ setMinPhi()

◆ setMinT0()

◆ setMinTheta()

◆ setMTCCHalf()

◆ setMultiMuon()

◆ setMultiMuonFileFirstEvent()

◆ setMultiMuonFileName()

◆ setMultiMuonNmin()

◆ setNumberOfEvents()

◆ setNuProdAlt()

◆ setPlugVx()

◆ setPlugVz()

◆ setRadiusOfTarget()

◆ setRandomEngine()

◆ setRanSeed()

◆ setRhoAir()

◆ setRhoClay()

◆ setRhoPlug()

◆ setRhoRock()

◆ setRhoWall()

◆ setTIFOnly_constant()

◆ setTIFOnly_linear()

◆ setTrackerOnly()

◆ setZCentrOfTarget()

◆ setZDistOfTarget()

◆ terminate()

Member Data Documentation

◆ AcptAllMu

◆ ClayWidth

◆ Cosmics

◆ delRanGen

◆ E_at

◆ E_sf

◆ E_ug

◆ ElossScaleFactor

◆ EventRate

◆ EventWeight

◆ Id_at

◆ Id_sf

◆ Id_ug

◆ MaxEnu

◆ MaxP

◆ MaxPhi

◆ MaxT0

◆ MaxTheta

◆ MinEnu

◆ MinP

◆ MinP_CMS

◆ MinPhi

◆ MinT0

◆ MinTheta