DreamSD Class Reference

#include <DreamSD.h>

Inheritance diagram for DreamSD:

Public Member Functions
	DreamSD (const std::string &, const DDCompactView *, const cms::DDCompactView *, const SensitiveDetectorCatalog &, edm::ParameterSet const &, const SimTrackManager *)
uint32_t	setDetUnitId (const G4Step *) override
	~DreamSD () override
Public Member Functions inherited from CaloSD
	CaloSD (const std::string &aSDname, const SensitiveDetectorCatalog &clg, edm::ParameterSet const &p, const SimTrackManager *, float timeSlice=1., bool ignoreTkID=false, const std::string &newcolname="")
void	clear () override
void	clearHits () override
void	DrawAll () override
void	EndOfEvent (G4HCofThisEvent *eventHC) override
void	fillHits (edm::PCaloHitContainer &, const std::string &) override
void	Initialize (G4HCofThisEvent *HCE) override
bool	isItFineCalo (const G4VTouchable *touch)
void	newCollection (const std::string &name, edm::ParameterSet const &p)
void	PrintAll () override
G4bool	ProcessHits (G4Step *step, G4TouchableHistory *) override
bool	ProcessHits (G4GFlashSpot *aSpot, G4TouchableHistory *) override
void	reset () override
	~CaloSD () override
Public Member Functions inherited from SensitiveCaloDetector
	SensitiveCaloDetector (const std::string &iname, const SensitiveDetectorCatalog &clg, const std::string &newcollname="")
Public Member Functions inherited from SensitiveDetector
void	EndOfEvent (G4HCofThisEvent *eventHC) override
const std::vector< std::string > &	getNames () const
void	Initialize (G4HCofThisEvent *eventHC) override
bool	isCaloSD () const
	SensitiveDetector (const std::string &iname, const SensitiveDetectorCatalog &, bool calo, const std::string &newcollname="")
	~SensitiveDetector () override
Public Member Functions inherited from Observer< const BeginOfRun *>
	Observer ()
void	slotForUpdate (const BeginOfRun * iT)
virtual	~Observer ()
Public Member Functions inherited from Observer< const BeginOfEvent *>
	Observer ()
void	slotForUpdate (const BeginOfEvent * iT)
virtual	~Observer ()
Public Member Functions inherited from Observer< const BeginOfTrack *>
	Observer ()
void	slotForUpdate (const BeginOfTrack * iT)
virtual	~Observer ()
Public Member Functions inherited from Observer< const EndOfTrack *>
	Observer ()
void	slotForUpdate (const EndOfTrack * iT)
virtual	~Observer ()
Public Member Functions inherited from Observer< const EndOfEvent *>
	Observer ()
void	slotForUpdate (const EndOfEvent * iT)
virtual	~Observer ()

Protected Member Functions
double	getEnergyDeposit (const G4Step *) override
void	initRun () override
Protected Member Functions inherited from CaloSD
bool	checkHit (int k=0)
CaloG4Hit *	createNewHit (const G4Step *, const G4Track *, int k)
virtual void	endEvent ()
virtual double	EnergyCorrected (const G4Step &step, const G4Track *)
virtual bool	filterHit (CaloG4Hit *, double)
unsigned int	findBoundaryCrossingParent (const G4Track *track, bool markParentAsSaveable=true)
double	getAttenuation (const G4Step *aStep, double birk1, double birk2, double birk3) const
virtual uint16_t	getDepth (const G4Step *)
virtual bool	getFromLibrary (const G4Step *step)
int	getNumberOfHits (int k=0)
double	getResponseWt (const G4Track *, int k=0)
virtual int	getTrackID (const G4Track *)
bool	hitExists (const G4Step *, int k)
void	ignoreRejection ()
virtual void	initEvent (const BeginOfEvent *)
void	printDetectorLevels (const G4VTouchable *) const
void	processHit (const G4Step *step)
virtual void	processSecondHit (const G4Step *, const G4Track *)
void	resetForNewPrimary (const G4Step *)
void	setNumberCheckedHits (int val, int k=0)
void	setParameterized (bool val)
G4ThreeVector	setToGlobal (const G4ThreeVector &, const G4VTouchable *) const
G4ThreeVector	setToLocal (const G4ThreeVector &, const G4VTouchable *) const
virtual int	setTrackID (const G4Step *)
void	setUseMap (bool val)
std::string	shortreprID (const CaloHitID &ID)
std::string	shortreprID (const CaloG4Hit *hit)
void	update (const BeginOfRun *) override
	This routine will be called when the appropriate signal arrives. More...
void	update (const BeginOfEvent *) override
	This routine will be called when the appropriate signal arrives. More...
void	update (const BeginOfTrack *trk) override
	This routine will be called when the appropriate signal arrives. More...
void	update (const EndOfTrack *trk) override
	This routine will be called when the appropriate signal arrives. More...
void	update (const ::EndOfEvent *) override
void	updateHit (CaloG4Hit *, int k)
Protected Member Functions inherited from SensitiveDetector
TrackInformation *	cmsTrackInformation (const G4Track *aTrack)
Local3DPoint	ConvertToLocal3DPoint (const G4ThreeVector &point) const
Local3DPoint	FinalStepPosition (const G4Step *step, coordinates) const
Local3DPoint	InitialStepPosition (const G4Step *step, coordinates) const
Local3DPoint	LocalPostStepPosition (const G4Step *step) const
Local3DPoint	LocalPreStepPosition (const G4Step *step) const
void	NaNTrap (const G4Step *step) const
void	setNames (const std::vector< std::string > &)
Protected Member Functions inherited from Observer< const EndOfEvent *>
virtual void	update (const EndOfEvent *)=0
	This routine will be called when the appropriate signal arrives. More...

Private Types
typedef std::map< G4LogicalVolume *, Doubles >	DimensionMap
typedef std::pair< double, double >	Doubles

Private Member Functions
double	cherenkovDeposit_ (const G4Step *aStep)
	Returns the total energy due to Cherenkov radiation. More...
double	crystalLength (G4LogicalVolume *) const
double	crystalWidth (G4LogicalVolume *) const
double	curve_LY (const G4Step *, int)
void	fillMap (const std::string &, double, double)
double	getAverageNumberOfPhotons_ (const double charge, const double beta, const G4Material *aMaterial, const G4MaterialPropertyVector *rIndex)
	Returns average number of photons created by track. More...
double	getPhotonEnergyDeposit_ (const G4ParticleMomentum &p, const G4ThreeVector &x, const G4Step *aStep)
	Returns energy deposit for a given photon. More...
void	initMap (const std::string &)
bool	setPbWO2MaterialProperties_ (G4Material *aMaterial)
	Sets material properties at run-time... More...

Private Attributes
double	birk1_
double	birk2_
double	birk3_
std::unique_ptr< G4PhysicsFreeVector >	chAngleIntegrals_
	Table of Cherenkov angle integrals vs photon momentum. More...
const cms::DDCompactView *	cpvDD4hep_
const DDCompactView *	cpvDDD_
bool	dd4hep_
bool	doCherenkov_
G4MaterialPropertiesTable *	materialPropertiesTable_
int	nphotons_
bool	readBothSide_
int	side_
double	slopeLY_
bool	useBirk_
DimensionMap	xtalLMap_

Static Private Attributes
static constexpr double	k_ScaleFromDD4hepToG4 = 1.0 / dd4hep::mm
static constexpr double	k_ScaleFromDDDToG4 = 1.0

Additional Inherited Members
Protected Types inherited from SensitiveDetector
enum	coordinates { WorldCoordinates, LocalCoordinates }
Static Protected Member Functions inherited from CaloSD
static std::string	printableDecayChain (const std::vector< unsigned int > &decayChain)
Protected Attributes inherited from CaloSD
std::string	collName_ [2]
CaloG4Hit *	currentHit [2]
CaloHitID	currentID [2]
std::string	detName_
float	edepositEM
float	edepositHAD
double	eminHit
double	energyCut
G4ThreeVector	entranceLocal
G4ThreeVector	entrancePoint
bool	forceSave
std::vector< std::string >	hcn_
float	incidentEnergy
double	kmaxIon
double	kmaxNeutron
double	kmaxProton
int	nHC_
G4ThreeVector	posGlobal
CaloHitID	previousID [2]
bool	suppressHeavy
double	tmaxHit
std::vector< int >	useResMap_

Detailed Description

Definition at line 20 of file DreamSD.h.

Member Typedef Documentation

DimensionMap

typedef std::map<G4LogicalVolume *, Doubles> DreamSD::DimensionMap

private

Definition at line 38 of file DreamSD.h.

Doubles

typedef std::pair<double, double> DreamSD::Doubles

private

Definition at line 37 of file DreamSD.h.

Constructor & Destructor Documentation

DreamSD()

DreamSD::DreamSD	(	const std::string &	name,
		const DDCompactView *	cpvDDD,
		const cms::DDCompactView *	cpvDD4hep,
		const SensitiveDetectorCatalog &	clg,
		edm::ParameterSet const &	p,
		const SimTrackManager *	manager
	)

Definition at line 32 of file DreamSD.cc.

References birk1_, birk2_, birk3_, chAngleIntegrals_, dd4hep_, doCherenkov_, g, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), initMap(), dqmdumpme::k, Skims_PA_cff::name, AlCaHLTBitMon_ParallelJobs::p, readBothSide_, slopeLY_, and useBirk_.

    : CaloSD(name, clg, p, manager), cpvDDD_(cpvDDD), cpvDD4hep_(cpvDD4hep) {
  edm::ParameterSet m_EC = p.getParameter<edm::ParameterSet>("ECalSD");
  useBirk_ = m_EC.getParameter<bool>("UseBirkLaw");
  doCherenkov_ = m_EC.getParameter<bool>("doCherenkov");
  birk1_ = m_EC.getParameter<double>("BirkC1") * (CLHEP::g / (CLHEP::MeV * CLHEP::cm2));
  birk2_ = m_EC.getParameter<double>("BirkC2");
  birk3_ = m_EC.getParameter<double>("BirkC3");
  slopeLY_ = m_EC.getParameter<double>("SlopeLightYield");
  readBothSide_ = m_EC.getUntrackedParameter<bool>("ReadBothSide", false);
  dd4hep_ = p.getParameter<bool>("g4GeometryDD4hepSource");

  chAngleIntegrals_.reset(nullptr);

  edm::LogVerbatim("EcalSim") << "Constructing a DreamSD  with name " << GetName()
                              << "\nDreamSD:: Use of Birks law is set to      " << useBirk_
                              << "  with three constants kB = " << birk1_ << ", C1 = " << birk2_ << ", C2 = " << birk3_
                              << "\n          Slope for Light yield is set to " << slopeLY_
                              << "\n          Parameterization of Cherenkov is set to " << doCherenkov_
                              << ", readout both sides is " << readBothSide_ << " and dd4hep flag " << dd4hep_;
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << GetName() << " initialized";
  const G4LogicalVolumeStore *lvs = G4LogicalVolumeStore::GetInstance();
  unsigned int k(0);
  for (auto lvcite = lvs->begin(); lvcite != lvs->end(); ++lvcite, ++k)
    edm::LogVerbatim("EcalSim") << "Volume[" << k << "] " << (*lvcite)->GetName();
#endif
  initMap(name);
}

~DreamSD()

DreamSD::~DreamSD ( )

inlineoverride

Definition at line 28 of file DreamSD.h.

{}

Member Function Documentation

cherenkovDeposit_()

double DreamSD::cherenkovDeposit_ ( const G4Step *  aStep )

private

Returns the total energy due to Cherenkov radiation.

Definition at line 243 of file DreamSD.cc.

References HLT_2024v13_cff::beta, ALCARECOTkAlJpsiMuMu_cff::charge, funct::cos(), l1tSlwPFPuppiJets_cfi::cosPhi, Calorimetry_cff::dp, getAverageNumberOfPhotons_(), getPhotonEnergyDeposit_(), materialPropertiesTable_, phi, ElectronMcFakeValidator_cfi::Pmax, multPhiCorr_741_25nsDY_cfi::px, multPhiCorr_741_25nsDY_cfi::py, funct::sin(), l1tSlwPFPuppiJets_cfi::sinPhi, and mathSSE::sqrt().

Referenced by getEnergyDeposit().

                                                     {
  double cherenkovEnergy = 0;
  if (!materialPropertiesTable_)
    return cherenkovEnergy;
  G4Material *material = aStep->GetTrack()->GetMaterial();

  // Retrieve refractive index
  G4MaterialPropertyVector *Rindex = materialPropertiesTable_->GetProperty("RINDEX");
  if (Rindex == nullptr) {
    edm::LogWarning("EcalSim") << "Couldn't retrieve refractive index";
    return cherenkovEnergy;
  }

  // V.Ivanchenko - temporary close log output for 9.5
  // Material refraction properties
  int Rlength = Rindex->GetVectorLength() - 1;
  double Pmin = Rindex->Energy(0);
  double Pmax = Rindex->Energy(Rlength);
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "Material properties: \n  Pmin = " << Pmin << "  Pmax = " << Pmax;
#endif
  // Get particle properties
  const G4StepPoint *pPreStepPoint = aStep->GetPreStepPoint();
  const G4StepPoint *pPostStepPoint = aStep->GetPostStepPoint();
  const G4ThreeVector &x0 = pPreStepPoint->GetPosition();
  G4ThreeVector p0 = aStep->GetDeltaPosition().unit();
  const G4DynamicParticle *aParticle = aStep->GetTrack()->GetDynamicParticle();
  const double charge = aParticle->GetDefinition()->GetPDGCharge();
  // beta is averaged over step
  double beta = 0.5 * (pPreStepPoint->GetBeta() + pPostStepPoint->GetBeta());
  double BetaInverse = 1.0 / beta;

#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "Particle properties: \n  charge = " << charge << "  beta   = " << beta;
#endif

  // Now get number of photons generated in this step
  double meanNumberOfPhotons = getAverageNumberOfPhotons_(charge, beta, material, Rindex);
  if (meanNumberOfPhotons <= 0.0) {  // Don't do anything
#ifdef EDM_ML_DEBUG
    edm::LogVerbatim("EcalSim") << "Mean number of photons is zero: " << meanNumberOfPhotons << ", stopping here";
#endif
    return cherenkovEnergy;
  }

  // number of photons is in unit of Geant4...
  meanNumberOfPhotons *= aStep->GetStepLength();

  // Now get a poisson distribution
  int numPhotons = static_cast<int>(G4Poisson(meanNumberOfPhotons));
  // edm::LogVerbatim("EcalSim") << "Number of photons = " << numPhotons;
  if (numPhotons <= 0) {
#ifdef EDM_ML_DEBUG
    edm::LogVerbatim("EcalSim") << "Poission number of photons is zero: " << numPhotons << ", stopping here";
#endif
    return cherenkovEnergy;
  }

  // Material refraction properties
  double dp = Pmax - Pmin;
  double maxCos = BetaInverse / (*Rindex)[Rlength];
  double maxSin2 = (1.0 - maxCos) * (1.0 + maxCos);

  // Finally: get contribution of each photon
  for (int iPhoton = 0; iPhoton < numPhotons; ++iPhoton) {
    // Determine photon momentum
    double randomNumber;
    double sampledMomentum, sampledRI;
    double cosTheta, sin2Theta;

    // sample a momentum (not sure why this is needed!)
    do {
      randomNumber = G4UniformRand();
      sampledMomentum = Pmin + randomNumber * dp;
      sampledRI = Rindex->Value(sampledMomentum);
      cosTheta = BetaInverse / sampledRI;

      sin2Theta = (1.0 - cosTheta) * (1.0 + cosTheta);
      randomNumber = G4UniformRand();

    } while (randomNumber * maxSin2 > sin2Theta);

    // Generate random position of photon on cone surface
    // defined by Theta
    randomNumber = G4UniformRand();

    double phi = twopi * randomNumber;
    double sinPhi = sin(phi);
    double cosPhi = cos(phi);

    // Create photon momentum direction vector
    // The momentum direction is still w.r.t. the coordinate system where the
    // primary particle direction is aligned with the z axis
    double sinTheta = sqrt(sin2Theta);
    double px = sinTheta * cosPhi;
    double py = sinTheta * sinPhi;
    double pz = cosTheta;
    G4ThreeVector photonDirection(px, py, pz);

    // Rotate momentum direction back to global (crystal) reference system
    photonDirection.rotateUz(p0);

    // Create photon position and momentum
    randomNumber = G4UniformRand();
    G4ThreeVector photonPosition = x0 + randomNumber * aStep->GetDeltaPosition();
    G4ThreeVector photonMomentum = sampledMomentum * photonDirection;

    // Collect energy on APD
    cherenkovEnergy += getPhotonEnergyDeposit_(photonMomentum, photonPosition, aStep);
  }
  return cherenkovEnergy;
}

crystalLength()

double DreamSD::crystalLength ( G4LogicalVolume *  lv ) const

private

Definition at line 223 of file DreamSD.cc.

References xtalLMap_.

Referenced by curve_LY(), and getPhotonEnergyDeposit_().

                                                       {
  double length = -1.;
  DimensionMap::const_iterator ite = xtalLMap_.find(lv);
  if (ite != xtalLMap_.end())
    length = ite->second.first;
  return length;
}

crystalWidth()

double DreamSD::crystalWidth ( G4LogicalVolume *  lv ) const

private

Definition at line 232 of file DreamSD.cc.

References ApeEstimator_cff::width, and xtalLMap_.

Referenced by getPhotonEnergyDeposit_().

                                                      {
  double width = -1.;
  DimensionMap::const_iterator ite = xtalLMap_.find(lv);
  if (ite != xtalLMap_.end())
    width = ite->second.second;
  return width;
}

curve_LY()

double DreamSD::curve_LY ( const G4Step *  aStep, int  flag  )

private

Definition at line 196 of file DreamSD.cc.

References crystalLength(), RemoveAddSevLevel::flag, CaloSD::setToLocal(), slopeLY_, and mps_merge::weight.

Referenced by getEnergyDeposit().

                                                      {
  auto const stepPoint = aStep->GetPreStepPoint();
  auto const lv = stepPoint->GetTouchable()->GetVolume(0)->GetLogicalVolume();
  G4String nameVolume = lv->GetName();

  double weight = 1.;
  G4ThreeVector localPoint = setToLocal(stepPoint->GetPosition(), stepPoint->GetTouchable());
  double crlength = crystalLength(lv);
  double localz = localPoint.x();
  double dapd = 0.5 * crlength - flag * localz;  // Distance from closest APD
  if (dapd >= -0.1 || dapd <= crlength + 0.1) {
    if (dapd <= 100.)
      weight = 1.0 + slopeLY_ - dapd * 0.01 * slopeLY_;
  } else {
    edm::LogWarning("EcalSim") << "DreamSD: light coll curve : wrong distance "
                               << "to APD " << dapd << " crlength = " << crlength << " crystal name = " << nameVolume
                               << " z of localPoint = " << localz << " take weight = " << weight;
  }
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "DreamSD, light coll curve : " << dapd << " crlength = " << crlength
                              << " crystal name = " << nameVolume << " z of localPoint = " << localz
                              << " take weight = " << weight;
#endif
  return weight;
}

fillMap()

void DreamSD::fillMap ( const std::string &  name, double  length, double  width  )

private

Definition at line 176 of file DreamSD.cc.

References Skims_PA_cff::name, DD4hep2DDDName::noNameSpace(), AlCaHLTBitMon_QueryRunRegistry::string, ApeEstimator_cff::width, and xtalLMap_.

Referenced by initMap().

                                                                        {
  const G4LogicalVolumeStore *lvs = G4LogicalVolumeStore::GetInstance();
  edm::LogVerbatim("EcalSim") << "LV Store with " << lvs->size() << " elements";
  G4LogicalVolume *lv = nullptr;
  for (auto lvcite = lvs->begin(); lvcite != lvs->end(); lvcite++) {
    edm::LogVerbatim("EcalSim") << name << " vs " << (*lvcite)->GetName();
    std::string namex = static_cast<std::string>((*lvcite)->GetName());
    if (name == DD4hep2DDDName::noNameSpace(static_cast<std::string>(namex))) {
      lv = (*lvcite);
      break;
    }
  }
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "DreamSD::fillMap (for " << name << " Logical Volume " << lv << " Length " << length
                              << " Width " << width;
#endif
  xtalLMap_.insert(std::pair<G4LogicalVolume *, Doubles>(lv, Doubles(length, width)));
}

getAverageNumberOfPhotons_()

double DreamSD::getAverageNumberOfPhotons_ ( const double  charge, const double  beta, const G4Material *  aMaterial, const G4MaterialPropertyVector *  rIndex  )

private

Returns average number of photons created by track.

Definition at line 359 of file DreamSD.cc.

References HLT_2024v13_cff::beta, chAngleIntegrals_, ALCARECOTkAlJpsiMuMu_cff::charge, Calorimetry_cff::dp, metDiagnosticParameterSet_cfi::nMax, metDiagnosticParameterSet_cfi::nMin, and ElectronMcFakeValidator_cfi::Pmax.

Referenced by cherenkovDeposit_().

                                                                                   {
  const double rFact = 369.81 / (eV * cm);

  if (beta <= 0.0)
    return 0.0;

  double BetaInverse = 1. / beta;

  // Vectors used in computation of Cerenkov Angle Integral:
  //         - Refraction Indices for the current material
  //        - new G4PhysicsOrderedFreeVector allocated to hold CAI's

  // Min and Max photon momenta
  int Rlength = Rindex->GetVectorLength() - 1;
  double Pmin = Rindex->Energy(0);
  double Pmax = Rindex->Energy(Rlength);

  // Min and Max Refraction Indices
  double nMin = (*Rindex)[0];
  double nMax = (*Rindex)[Rlength];

  // Max Cerenkov Angle Integral
  double CAImax = chAngleIntegrals_.get()->GetMaxEnergy();

  double dp = 0., ge = 0., CAImin = 0.;

  // If n(Pmax) < 1/Beta -- no photons generated
  if (nMax < BetaInverse) {
  }

  // otherwise if n(Pmin) >= 1/Beta -- photons generated
  else if (nMin > BetaInverse) {
    dp = Pmax - Pmin;
    ge = CAImax;
  }
  // If n(Pmin) < 1/Beta, and n(Pmax) >= 1/Beta, then
  // we need to find a P such that the value of n(P) == 1/Beta.
  // Interpolation is performed by the GetPhotonEnergy() and
  // GetProperty() methods of the G4MaterialPropertiesTable and
  // the GetValue() method of G4PhysicsVector.
  else {
    Pmin = Rindex->Value(BetaInverse);
    dp = Pmax - Pmin;
    // need boolean for current implementation of G4PhysicsVector
    // ==> being phased out
    double CAImin = chAngleIntegrals_->Value(Pmin);
    ge = CAImax - CAImin;
  }

  // Calculate number of photons
  double numPhotons = rFact * charge / eplus * charge / eplus * (dp - ge * BetaInverse * BetaInverse);

  edm::LogVerbatim("EcalSim") << "@SUB=getAverageNumberOfPhotons\nCAImin = " << CAImin << "\nCAImax = " << CAImax
                              << "\ndp = " << dp << ", ge = " << ge << "\nnumPhotons = " << numPhotons;
  return numPhotons;
}

getEnergyDeposit()

double DreamSD::getEnergyDeposit ( const G4Step *  aStep )

overrideprotectedvirtual

Reimplemented from CaloSD.

Definition at line 68 of file DreamSD.cc.

References birk1_, birk2_, birk3_, cherenkovDeposit_(), curve_LY(), doCherenkov_, CaloSD::getAttenuation(), side_, useBirk_, and mps_merge::weight.

                                                    {
  // take into account light collection curve for crystals
  double weight = curve_LY(aStep, side_);
  if (useBirk_)
    weight *= getAttenuation(aStep, birk1_, birk2_, birk3_);
  double edep = aStep->GetTotalEnergyDeposit() * weight;

  // Get Cerenkov contribution
  if (doCherenkov_) {
    edep += cherenkovDeposit_(aStep);
  }
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "DreamSD:: " << aStep->GetPreStepPoint()->GetPhysicalVolume()->GetName() << " Side "
                              << side_ << " Light Collection Efficiency " << weight << " Weighted Energy Deposit "
                              << edep / CLHEP::MeV << " MeV";
#endif
  return edep;
}

getPhotonEnergyDeposit_()

double DreamSD::getPhotonEnergyDeposit_ ( const G4ParticleMomentum &  p, const G4ThreeVector &  x, const G4Step *  aStep  )

private

Returns energy deposit for a given photon.

Definition at line 504 of file DreamSD.cc.

References funct::abs(), crystalLength(), crystalWidth(), hcalRecHitTable_cff::energy, PMTResponse::getEfficiency(), AlCaHLTBitMon_ParallelJobs::p, x, and y.

Referenced by cherenkovDeposit_().

                                                                                                           {
  double energy = 0;

  // Crystal dimensions

  // edm::LogVerbatim("EcalSim") << p << x;

  // 1. Check if this photon goes straight to the APD:
  //    - assume that APD is at x=xtalLength/2.0
  //    - extrapolate from x=x0 to x=xtalLength/2.0 using momentum in x-y

  G4StepPoint *stepPoint = aStep->GetPreStepPoint();
  G4LogicalVolume *lv = stepPoint->GetTouchable()->GetVolume(0)->GetLogicalVolume();
  G4String nameVolume = lv->GetName();

  double crlength = crystalLength(lv);
  double crwidth = crystalWidth(lv);
  double dapd = 0.5 * crlength - x.x();  // Distance from closest APD
  double y = p.y() / p.x() * dapd;

#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "Distance to APD: " << dapd << " - y at APD: " << y;
#endif
  // Not straight: compute probability
  if (std::abs(y) > crwidth * 0.5) {
  }

  // 2. Retrieve efficiency for this wavelength (in nm, from MeV)
  double waveLength = p.mag() * 1.239e8;

  energy = p.mag() * PMTResponse::getEfficiency(waveLength);
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "Wavelength: " << waveLength << " - Energy: " << energy;
#endif
  return energy;
}

initMap()

void DreamSD::initMap ( const std::string &  sd )

private

Definition at line 121 of file DreamSD.cc.

References cpvDD4hep_, cpvDDD_, dd4hep_, cms::DDSolidShapeMap, fillMap(), ALCARECOTkAlBeamHalo_cff::filter, DDFilteredView::firstChild(), cms::DDFilteredView::firstChild(), mps_fire::i, k_ScaleFromDD4hepToG4, k_ScaleFromDDDToG4, DDFilteredView::logicalPart(), Skims_PA_cff::name, cms::dd::name(), cms::DDFilteredView::name(), DDFilteredView::next(), DD4hep2DDDName::noNameSpace(), cms::DDFilteredView::parameters(), cms::DDFilteredView::shape(), mkfit::Const::sol, DDLogicalPart::solid(), jetUpdater_cfi::sort, AlCaHLTBitMon_QueryRunRegistry::string, ApeEstimator_cff::width, and xtalLMap_.

Referenced by DreamSD().

                                         {
  if (dd4hep_) {
    const cms::DDFilter filter("ReadOutName", sd);
    cms::DDFilteredView fv((*cpvDD4hep_), filter);
    while (fv.firstChild()) {
      std::string name = DD4hep2DDDName::noNameSpace(static_cast<std::string>(fv.name()));
      std::vector<double> paras(fv.parameters());
#ifdef EDM_ML_DEBUG
      edm::LogVerbatim("EcalSim") << "DreamSD::initMap (for " << sd << "): Solid " << name << " Shape "
                                  << cms::dd::name(cms::DDSolidShapeMap, fv.shape()) << " Parameter 0 = " << paras[0];
#endif
      // Set length to be the largest size, width the smallest
      std::sort(paras.begin(), paras.end());
      double length = 2.0 * k_ScaleFromDD4hepToG4 * paras.back();
      double width = 2.0 * k_ScaleFromDD4hepToG4 * paras.front();
      fillMap(name, length, width);
    }
  } else {
    DDSpecificsMatchesValueFilter filter{DDValue("ReadOutName", sd, 0)};
    DDFilteredView fv((*cpvDDD_), filter);
    fv.firstChild();
    bool dodet = true;
    while (dodet) {
      const DDSolid &sol = fv.logicalPart().solid();
      std::vector<double> paras(sol.parameters());
      std::string name = static_cast<std::string>(sol.name().name());
#ifdef EDM_ML_DEBUG
      edm::LogVerbatim("EcalSim") << "DreamSD::initMap (for " << sd << "): Solid " << name << " Shape " << sol.shape()
                                  << " Parameter 0 = " << paras[0];
#endif
      // Set length to be the largest size, width the smallest
      std::sort(paras.begin(), paras.end());
      double length = 2.0 * k_ScaleFromDDDToG4 * paras.back();
      double width = 2.0 * k_ScaleFromDDDToG4 * paras.front();
      fillMap(name, length, width);
      dodet = fv.next();
    }
  }
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "DreamSD: Length Table for ReadOutName = " << sd << ":";
#endif
  DimensionMap::const_iterator ite = xtalLMap_.begin();
  int i = 0;
  for (; ite != xtalLMap_.end(); ite++, i++) {
    G4String name = "Unknown";
    if (ite->first != nullptr)
      name = (ite->first)->GetName();
#ifdef EDM_ML_DEBUG
    edm::LogVerbatim("EcalSim") << " " << i << " " << ite->first << " " << name << " L = " << ite->second.first
                                << " W = " << ite->second.second;
#endif
  }
}

initRun()

void DreamSD::initRun ( )

overrideprotectedvirtual

Reimplemented from CaloSD.

Definition at line 88 of file DreamSD.cc.

References materialPropertiesTable_, setPbWO2MaterialProperties_(), and xtalLMap_.

                      {
  // Get the material and set properties if needed
  DimensionMap::const_iterator ite = xtalLMap_.begin();
  const G4LogicalVolume *lv = (ite->first);
  G4Material *material = lv->GetMaterial();
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "DreamSD::initRun: Initializes for material " << material->GetName() << " in "
                              << lv->GetName();
#endif
  materialPropertiesTable_ = material->GetMaterialPropertiesTable();
  if (!materialPropertiesTable_) {
    if (!setPbWO2MaterialProperties_(material)) {
      edm::LogWarning("EcalSim") << "Couldn't retrieve material properties table\n Material = " << material->GetName();
    }
    materialPropertiesTable_ = material->GetMaterialPropertiesTable();
  }
}

setDetUnitId()

uint32_t DreamSD::setDetUnitId ( const G4Step *  aStep )

overridevirtual

Implements CaloSD.

Definition at line 107 of file DreamSD.cc.

References l1ctLayer2EG_cff::id, readBothSide_, and side_.

                                                  {
  const G4VTouchable *touch = aStep->GetPreStepPoint()->GetTouchable();
  uint32_t id = (touch->GetReplicaNumber(1)) * 10 + (touch->GetReplicaNumber(0));
  side_ = readBothSide_ ? -1 : 1;
  if (side_ < 0) {
    ++id;
  }
#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "DreamSD:: ID " << id;
#endif
  return id;
}

setPbWO2MaterialProperties_()

bool DreamSD::setPbWO2MaterialProperties_ ( G4Material *  aMaterial )

private

Sets material properties at run-time...

Definition at line 422 of file DreamSD.cc.

References chAngleIntegrals_, Skims_PA_cff::name, DD4hep2DDDName::noNameSpace(), AlCaHLTBitMon_QueryRunRegistry::string, and TableParser::table.

Referenced by initRun().

                                                               {
  std::string pbWO2Name("E_PbWO4");
  std::string name = static_cast<std::string>(aMaterial->GetName());
  if (DD4hep2DDDName::noNameSpace(name) != pbWO2Name) {  // Wrong material!
    edm::LogWarning("EcalSim") << "This is not the right material: "
                               << "expecting " << pbWO2Name << ", got " << aMaterial->GetName();
    return false;
  }

  G4MaterialPropertiesTable *table = new G4MaterialPropertiesTable();

  // Refractive index as a function of photon momentum
  // FIXME: Should somehow put that in the configuration
  const int nEntries = 14;
  double PhotonEnergy[nEntries] = {1.7712 * eV,
                                   1.8368 * eV,
                                   1.90745 * eV,
                                   1.98375 * eV,
                                   2.0664 * eV,
                                   2.15625 * eV,
                                   2.25426 * eV,
                                   2.3616 * eV,
                                   2.47968 * eV,
                                   2.61019 * eV,
                                   2.75521 * eV,
                                   2.91728 * eV,
                                   3.09961 * eV,
                                   3.30625 * eV};
  double RefractiveIndex[nEntries] = {2.17728,
                                      2.18025,
                                      2.18357,
                                      2.18753,
                                      2.19285,
                                      2.19813,
                                      2.20441,
                                      2.21337,
                                      2.22328,
                                      2.23619,
                                      2.25203,
                                      2.27381,
                                      2.30282,
                                      2.34666};

  table->AddProperty("RINDEX", PhotonEnergy, RefractiveIndex, nEntries);
  aMaterial->SetMaterialPropertiesTable(table);  // FIXME: could this leak? What does G4 do?

  // Calculate Cherenkov angle integrals:
  // This is an ad-hoc solution (we hold it in the class, not in the material)
  chAngleIntegrals_ = std::make_unique<G4PhysicsFreeVector>(nEntries);

  int index = 0;
  double currentRI = RefractiveIndex[index];
  double currentPM = PhotonEnergy[index];
  double currentCAI = 0.0;
  chAngleIntegrals_.get()->PutValue(0, currentPM, currentCAI);
  double prevPM = currentPM;
  double prevCAI = currentCAI;
  double prevRI = currentRI;
  while (++index < nEntries) {
    currentRI = RefractiveIndex[index];
    currentPM = PhotonEnergy[index];
    currentCAI = 0.5 * (1.0 / (prevRI * prevRI) + 1.0 / (currentRI * currentRI));
    currentCAI = prevCAI + (currentPM - prevPM) * currentCAI;

    chAngleIntegrals_.get()->PutValue(index, currentPM, currentCAI);

    prevPM = currentPM;
    prevCAI = currentCAI;
    prevRI = currentRI;
  }

#ifdef EDM_ML_DEBUG
  edm::LogVerbatim("EcalSim") << "Material properties set for " << aMaterial->GetName();
#endif
  return true;
}

Member Data Documentation

birk1_

double DreamSD::birk1_

private

Definition at line 65 of file DreamSD.h.

Referenced by DreamSD(), and getEnergyDeposit().

birk2_

double DreamSD::birk2_

private

Definition at line 65 of file DreamSD.h.

Referenced by DreamSD(), and getEnergyDeposit().

birk3_

double DreamSD::birk3_

private

Definition at line 65 of file DreamSD.h.

Referenced by DreamSD(), and getEnergyDeposit().

chAngleIntegrals_

std::unique_ptr<G4PhysicsFreeVector> DreamSD::chAngleIntegrals_

private

Table of Cherenkov angle integrals vs photon momentum.

Definition at line 72 of file DreamSD.h.

Referenced by DreamSD(), getAverageNumberOfPhotons_(), and setPbWO2MaterialProperties_().

cpvDD4hep_

const cms::DDCompactView* DreamSD::cpvDD4hep_

private

Definition at line 62 of file DreamSD.h.

Referenced by initMap().

cpvDDD_

const DDCompactView* DreamSD::cpvDDD_

private

Definition at line 61 of file DreamSD.h.

Referenced by initMap().

dd4hep_

bool DreamSD::dd4hep_

private

Definition at line 64 of file DreamSD.h.

Referenced by DreamSD(), and initMap().

doCherenkov_

bool DreamSD::doCherenkov_

private

Definition at line 64 of file DreamSD.h.

Referenced by DreamSD(), and getEnergyDeposit().

k_ScaleFromDD4hepToG4

constexpr double DreamSD::k_ScaleFromDD4hepToG4 = 1.0 / dd4hep::mm

staticprivate

Definition at line 59 of file DreamSD.h.

Referenced by initMap().

k_ScaleFromDDDToG4

constexpr double DreamSD::k_ScaleFromDDDToG4 = 1.0

staticprivate

Definition at line 58 of file DreamSD.h.

Referenced by initMap().

materialPropertiesTable_

G4MaterialPropertiesTable* DreamSD::materialPropertiesTable_

private

Definition at line 73 of file DreamSD.h.

Referenced by cherenkovDeposit_(), and initRun().

nphotons_

int DreamSD::nphotons_

private

Definition at line 75 of file DreamSD.h.

readBothSide_

bool DreamSD::readBothSide_

private

Definition at line 64 of file DreamSD.h.

Referenced by DreamSD(), and setDetUnitId().

side_

int DreamSD::side_

private

Definition at line 69 of file DreamSD.h.

Referenced by getEnergyDeposit(), and setDetUnitId().

slopeLY_

double DreamSD::slopeLY_

private

Definition at line 66 of file DreamSD.h.

Referenced by curve_LY(), and DreamSD().

useBirk_

bool DreamSD::useBirk_

private

Definition at line 64 of file DreamSD.h.

Referenced by DreamSD(), and getEnergyDeposit().

xtalLMap_

DimensionMap DreamSD::xtalLMap_

private

Definition at line 67 of file DreamSD.h.

Referenced by crystalLength(), crystalWidth(), fillMap(), initMap(), and initRun().