/*
* Delphes: a framework for fast simulation of a generic collider experiment
* Copyright (C) 2012-2014 Universite catholique de Louvain (UCL), Belgium
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
/** \class Calorimeter
*
* Fills calorimeter towers, performs calorimeter resolution smearing,
* and creates energy flow objects (tracks, photons, and neutral hadrons).
*
* \author P. Demin - UCL, Louvain-la-Neuve
*
*/
#include "modules/Calorimeter.h"
#include "classes/DelphesClasses.h"
#include "classes/DelphesFactory.h"
#include "classes/DelphesFormula.h"
#include "ExRootAnalysis/ExRootResult.h"
#include "ExRootAnalysis/ExRootFilter.h"
#include "ExRootAnalysis/ExRootClassifier.h"
#include "TMath.h"
#include "TString.h"
#include "TFormula.h"
#include "TRandom3.h"
#include "TObjArray.h"
#include "TDatabasePDG.h"
#include "TLorentzVector.h"
#include
#include
#include
#include
using namespace std;
//------------------------------------------------------------------------------
Calorimeter::Calorimeter() :
fECalResolutionFormula(0), fHCalResolutionFormula(0),
fItParticleInputArray(0), fItTrackInputArray(0),
fTowerTrackArray(0), fItTowerTrackArray(0)
{
fECalResolutionFormula = new DelphesFormula;
fHCalResolutionFormula = new DelphesFormula;
fTowerTrackArray = new TObjArray;
fItTowerTrackArray = fTowerTrackArray->MakeIterator();
}
//------------------------------------------------------------------------------
Calorimeter::~Calorimeter()
{
if(fECalResolutionFormula) delete fECalResolutionFormula;
if(fHCalResolutionFormula) delete fHCalResolutionFormula;
if(fTowerTrackArray) delete fTowerTrackArray;
if(fItTowerTrackArray) delete fItTowerTrackArray;
}
//------------------------------------------------------------------------------
void Calorimeter::Init()
{
ExRootConfParam param, paramEtaBins, paramPhiBins, paramFractions;
Long_t i, j, k, size, sizeEtaBins, sizePhiBins;
Double_t ecalFraction, hcalFraction;
TBinMap::iterator itEtaBin;
set< Double_t >::iterator itPhiBin;
vector< Double_t > *phiBins;
// read eta and phi bins
param = GetParam("EtaPhiBins");
size = param.GetSize();
fBinMap.clear();
fEtaBins.clear();
fPhiBins.clear();
for(i = 0; i < size/2; ++i)
{
paramEtaBins = param[i*2];
sizeEtaBins = paramEtaBins.GetSize();
paramPhiBins = param[i*2 + 1];
sizePhiBins = paramPhiBins.GetSize();
for(j = 0; j < sizeEtaBins; ++j)
{
for(k = 0; k < sizePhiBins; ++k)
{
fBinMap[paramEtaBins[j].GetDouble()].insert(paramPhiBins[k].GetDouble());
}
}
}
// for better performance we transform map of sets to parallel vectors:
// vector< double > and vector< vector< double >* >
for(itEtaBin = fBinMap.begin(); itEtaBin != fBinMap.end(); ++itEtaBin)
{
fEtaBins.push_back(itEtaBin->first);
phiBins = new vector< double >(itEtaBin->second.size());
fPhiBins.push_back(phiBins);
phiBins->clear();
for(itPhiBin = itEtaBin->second.begin(); itPhiBin != itEtaBin->second.end(); ++itPhiBin)
{
phiBins->push_back(*itPhiBin);
}
}
// read energy fractions for different particles
param = GetParam("EnergyFraction");
size = param.GetSize();
// set default energy fractions values
fFractionMap.clear();
fFractionMap[0] = make_pair(0.0, 1.0);
for(i = 0; i < size/2; ++i)
{
paramFractions = param[i*2 + 1];
ecalFraction = paramFractions[0].GetDouble();
hcalFraction = paramFractions[1].GetDouble();
fFractionMap[param[i*2].GetInt()] = make_pair(ecalFraction, hcalFraction);
}
/*
TFractionMap::iterator itFractionMap;
for(itFractionMap = fFractionMap.begin(); itFractionMap != fFractionMap.end(); ++itFractionMap)
{
cout << itFractionMap->first << " " << itFractionMap->second.first << " " << itFractionMap->second.second << endl;
}
*/
// read min E value for towers to be saved
fECalEnergyMin = GetDouble("ECalEnergyMin", 0.0);
fHCalEnergyMin = GetDouble("HCalEnergyMin", 0.0);
fECalEnergySignificanceMin = GetDouble("ECalEnergySignificanceMin", 0.0);
fHCalEnergySignificanceMin = GetDouble("HCalEnergySignificanceMin", 0.0);
// switch on or off the dithering of the center of calorimeter towers
fDitherTowerCenter = GetBool("DitherTowerCenter", true);
// read resolution formulas
fECalResolutionFormula->Compile(GetString("ECalResolutionFormula", "0"));
fHCalResolutionFormula->Compile(GetString("HCalResolutionFormula", "0"));
// import array with output from other modules
fParticleInputArray = ImportArray(GetString("ParticleInputArray", "ParticlePropagator/particles"));
fItParticleInputArray = fParticleInputArray->MakeIterator();
fTrackInputArray = ImportArray(GetString("TrackInputArray", "ParticlePropagator/tracks"));
fItTrackInputArray = fTrackInputArray->MakeIterator();
// create output arrays
fTowerOutputArray = ExportArray(GetString("TowerOutputArray", "towers"));
fPhotonOutputArray = ExportArray(GetString("PhotonOutputArray", "photons"));
fEFlowTrackOutputArray = ExportArray(GetString("EFlowTrackOutputArray", "eflowTracks"));
fEFlowPhotonOutputArray = ExportArray(GetString("EFlowPhotonOutputArray", "eflowPhotons"));
fEFlowNeutralHadronOutputArray = ExportArray(GetString("EFlowNeutralHadronOutputArray", "eflowNeutralHadrons"));
}
//------------------------------------------------------------------------------
void Calorimeter::Finish()
{
vector< vector< Double_t >* >::iterator itPhiBin;
if(fItParticleInputArray) delete fItParticleInputArray;
if(fItTrackInputArray) delete fItTrackInputArray;
for(itPhiBin = fPhiBins.begin(); itPhiBin != fPhiBins.end(); ++itPhiBin)
{
delete *itPhiBin;
}
}
//------------------------------------------------------------------------------
void Calorimeter::Process()
{
Candidate *particle, *track;
TLorentzVector position, momentum;
Short_t etaBin, phiBin, flags;
Int_t number;
Long64_t towerHit, towerEtaPhi, hitEtaPhi;
Double_t ecalFraction, hcalFraction;
Double_t ecalEnergy, hcalEnergy;
Int_t pdgCode;
TFractionMap::iterator itFractionMap;
vector< Double_t >::iterator itEtaBin;
vector< Double_t >::iterator itPhiBin;
vector< Double_t > *phiBins;
vector< Long64_t >::iterator itTowerHits;
DelphesFactory *factory = GetFactory();
fTowerHits.clear();
fTowerECalFractions.clear();
fTowerHCalFractions.clear();
fTrackECalFractions.clear();
fTrackHCalFractions.clear();
// loop over all particles
fItParticleInputArray->Reset();
number = -1;
while((particle = static_cast(fItParticleInputArray->Next())))
{
const TLorentzVector &particlePosition = particle->Position;
++number;
pdgCode = TMath::Abs(particle->PID);
itFractionMap = fFractionMap.find(pdgCode);
if(itFractionMap == fFractionMap.end())
{
itFractionMap = fFractionMap.find(0);
}
ecalFraction = itFractionMap->second.first;
hcalFraction = itFractionMap->second.second;
fTowerECalFractions.push_back(ecalFraction);
fTowerHCalFractions.push_back(hcalFraction);
if(ecalFraction < 1.0E-9 && hcalFraction < 1.0E-9) continue;
// find eta bin [1, fEtaBins.size - 1]
itEtaBin = lower_bound(fEtaBins.begin(), fEtaBins.end(), particlePosition.Eta());
if(itEtaBin == fEtaBins.begin() || itEtaBin == fEtaBins.end()) continue;
etaBin = distance(fEtaBins.begin(), itEtaBin);
// phi bins for given eta bin
phiBins = fPhiBins[etaBin];
// find phi bin [1, phiBins.size - 1]
itPhiBin = lower_bound(phiBins->begin(), phiBins->end(), particlePosition.Phi());
if(itPhiBin == phiBins->begin() || itPhiBin == phiBins->end()) continue;
phiBin = distance(phiBins->begin(), itPhiBin);
flags = 0;
flags |= (pdgCode == 11 || pdgCode == 22) << 1;
// make tower hit {16-bits for eta bin number, 16-bits for phi bin number, 8-bits for flags, 24-bits for particle number}
towerHit = (Long64_t(etaBin) << 48) | (Long64_t(phiBin) << 32) | (Long64_t(flags) << 24) | Long64_t(number);
fTowerHits.push_back(towerHit);
}
// loop over all tracks
fItTrackInputArray->Reset();
number = -1;
while((track = static_cast(fItTrackInputArray->Next())))
{
const TLorentzVector &trackPosition = track->Position;
++number;
pdgCode = TMath::Abs(track->PID);
itFractionMap = fFractionMap.find(pdgCode);
if(itFractionMap == fFractionMap.end())
{
itFractionMap = fFractionMap.find(0);
}
ecalFraction = itFractionMap->second.first;
hcalFraction = itFractionMap->second.second;
fTrackECalFractions.push_back(ecalFraction);
fTrackHCalFractions.push_back(hcalFraction);
// find eta bin [1, fEtaBins.size - 1]
itEtaBin = lower_bound(fEtaBins.begin(), fEtaBins.end(), trackPosition.Eta());
if(itEtaBin == fEtaBins.begin() || itEtaBin == fEtaBins.end()) continue;
etaBin = distance(fEtaBins.begin(), itEtaBin);
// phi bins for given eta bin
phiBins = fPhiBins[etaBin];
// find phi bin [1, phiBins.size - 1]
itPhiBin = lower_bound(phiBins->begin(), phiBins->end(), trackPosition.Phi());
if(itPhiBin == phiBins->begin() || itPhiBin == phiBins->end()) continue;
phiBin = distance(phiBins->begin(), itPhiBin);
flags = 1;
// make tower hit {16-bits for eta bin number, 16-bits for phi bin number, 8-bits for flags, 24-bits for track number}
towerHit = (Long64_t(etaBin) << 48) | (Long64_t(phiBin) << 32) | (Long64_t(flags) << 24) | Long64_t(number);
fTowerHits.push_back(towerHit);
}
// all hits are sorted first by eta bin number, then by phi bin number,
// then by flags and then by particle or track number
sort(fTowerHits.begin(), fTowerHits.end());
// loop over all hits
towerEtaPhi = 0;
fTower = 0;
for(itTowerHits = fTowerHits.begin(); itTowerHits != fTowerHits.end(); ++itTowerHits)
{
towerHit = (*itTowerHits);
flags = (towerHit >> 24) & 0x00000000000000FFLL;
number = (towerHit) & 0x0000000000FFFFFFLL;
hitEtaPhi = towerHit >> 32;
if(towerEtaPhi != hitEtaPhi)
{
// switch to next tower
towerEtaPhi = hitEtaPhi;
// finalize previous tower
FinalizeTower();
// create new tower
fTower = factory->NewCandidate();
phiBin = (towerHit >> 32) & 0x000000000000FFFFLL;
etaBin = (towerHit >> 48) & 0x000000000000FFFFLL;
// phi bins for given eta bin
phiBins = fPhiBins[etaBin];
// calculate eta and phi of the tower's center
fTowerEta = 0.5*(fEtaBins[etaBin - 1] + fEtaBins[etaBin]);
fTowerPhi = 0.5*((*phiBins)[phiBin - 1] + (*phiBins)[phiBin]);
fTowerEdges[0] = fEtaBins[etaBin - 1];
fTowerEdges[1] = fEtaBins[etaBin];
fTowerEdges[2] = (*phiBins)[phiBin - 1];
fTowerEdges[3] = (*phiBins)[phiBin];
fTowerECalEnergy = 0.0;
fTowerHCalEnergy = 0.0;
fTrackECalEnergy = 0.0;
fTrackHCalEnergy = 0.0;
fTowerECalTime = 0.0;
fTowerHCalTime = 0.0;
fTrackECalTime = 0.0;
fTrackHCalTime = 0.0;
fTowerECalTimeWeight = 0.0;
fTowerHCalTimeWeight = 0.0;
fTowerTrackHits = 0;
fTowerPhotonHits = 0;
fTowerTrackArray->Clear();
}
// check for track hits
if(flags & 1)
{
++fTowerTrackHits;
track = static_cast(fTrackInputArray->At(number));
momentum = track->Momentum;
position = track->Position;
ecalEnergy = momentum.E() * fTrackECalFractions[number];
hcalEnergy = momentum.E() * fTrackHCalFractions[number];
fTrackECalEnergy += ecalEnergy;
fTrackHCalEnergy += hcalEnergy;
fTrackECalTime += TMath::Sqrt(ecalEnergy)*position.T();
fTrackHCalTime += TMath::Sqrt(hcalEnergy)*position.T();
fTrackECalTimeWeight += TMath::Sqrt(ecalEnergy);
fTrackHCalTimeWeight += TMath::Sqrt(hcalEnergy);
fTowerTrackArray->Add(track);
continue;
}
// check for photon and electron hits in current tower
if(flags & 2) ++fTowerPhotonHits;
particle = static_cast(fParticleInputArray->At(number));
momentum = particle->Momentum;
position = particle->Position;
// fill current tower
ecalEnergy = momentum.E() * fTowerECalFractions[number];
hcalEnergy = momentum.E() * fTowerHCalFractions[number];
fTowerECalEnergy += ecalEnergy;
fTowerHCalEnergy += hcalEnergy;
fTowerECalTime += TMath::Sqrt(ecalEnergy)*position.T();
fTowerHCalTime += TMath::Sqrt(hcalEnergy)*position.T();
fTowerECalTimeWeight += TMath::Sqrt(ecalEnergy);
fTowerHCalTimeWeight += TMath::Sqrt(hcalEnergy);
fTower->AddCandidate(particle);
}
// finalize last tower
FinalizeTower();
}
//------------------------------------------------------------------------------
void Calorimeter::FinalizeTower()
{
Candidate *track, *tower;
Double_t energy, pt, eta, phi;
Double_t ecalEnergy, hcalEnergy;
Double_t ecalSigma, hcalSigma;
Double_t ecalTime, hcalTime, time;
if(!fTower) return;
ecalSigma = fECalResolutionFormula->Eval(0.0, fTowerEta, 0.0, fTowerECalEnergy);
hcalSigma = fHCalResolutionFormula->Eval(0.0, fTowerEta, 0.0, fTowerHCalEnergy);
ecalEnergy = LogNormal(fTowerECalEnergy, ecalSigma);
hcalEnergy = LogNormal(fTowerHCalEnergy, hcalSigma);
ecalTime = (fTowerECalTimeWeight < 1.0E-09 ) ? 0.0 : fTowerECalTime/fTowerECalTimeWeight;
hcalTime = (fTowerHCalTimeWeight < 1.0E-09 ) ? 0.0 : fTowerHCalTime/fTowerHCalTimeWeight;
ecalSigma = fECalResolutionFormula->Eval(0.0, fTowerEta, 0.0, ecalEnergy);
hcalSigma = fHCalResolutionFormula->Eval(0.0, fTowerEta, 0.0, hcalEnergy);
if(ecalEnergy < fECalEnergyMin || ecalEnergy < fECalEnergySignificanceMin*ecalSigma) ecalEnergy = 0.0;
if(hcalEnergy < fHCalEnergyMin || hcalEnergy < fHCalEnergySignificanceMin*hcalSigma) hcalEnergy = 0.0;
energy = ecalEnergy + hcalEnergy;
time = (TMath::Sqrt(ecalEnergy)*ecalTime + TMath::Sqrt(hcalEnergy)*hcalTime)/(TMath::Sqrt(ecalEnergy) + TMath::Sqrt(hcalEnergy));
if(fDitherTowerCenter)
{
eta = gRandom->Uniform(fTowerEdges[0], fTowerEdges[1]);
phi = gRandom->Uniform(fTowerEdges[2], fTowerEdges[3]);
}
else
{
eta = fTowerEta;
phi = fTowerPhi;
}
pt = energy / TMath::CosH(eta);
fTower->Position.SetPtEtaPhiE(1.0, eta, phi, time);
fTower->Momentum.SetPtEtaPhiE(pt, eta, phi, energy);
fTower->Eem = ecalEnergy;
fTower->Ehad = hcalEnergy;
fTower->Edges[0] = fTowerEdges[0];
fTower->Edges[1] = fTowerEdges[1];
fTower->Edges[2] = fTowerEdges[2];
fTower->Edges[3] = fTowerEdges[3];
if(energy > 0.0)
{
if(fTowerPhotonHits > 0 && fTowerTrackHits == 0)
{
fPhotonOutputArray->Add(fTower);
}
fTowerOutputArray->Add(fTower);
}
// fill energy flow candidates
// save all the tracks as energy flow tracks
fItTowerTrackArray->Reset();
while((track = static_cast(fItTowerTrackArray->Next())))
{
fEFlowTrackOutputArray->Add(track);
}
ecalEnergy -= fTrackECalEnergy;
hcalEnergy -= fTrackHCalEnergy;
ecalSigma = fECalResolutionFormula->Eval(0.0, fTowerEta, 0.0, ecalEnergy);
hcalSigma = fHCalResolutionFormula->Eval(0.0, fTowerEta, 0.0, hcalEnergy);
if(ecalEnergy < fECalEnergyMin || ecalEnergy < fECalEnergySignificanceMin*ecalSigma) ecalEnergy = 0.0;
if(hcalEnergy < fHCalEnergyMin || hcalEnergy < fHCalEnergySignificanceMin*hcalSigma) hcalEnergy = 0.0;
energy = ecalEnergy + hcalEnergy;
if(ecalEnergy > 0.0)
{
// create new photon tower
tower = static_cast(fTower->Clone());
pt = ecalEnergy / TMath::CosH(eta);
tower->Momentum.SetPtEtaPhiE(pt, eta, phi, ecalEnergy);
tower->Eem = ecalEnergy;
tower->Ehad = 0.0;
fEFlowPhotonOutputArray->Add(tower);
}
if(hcalEnergy > 0.0)
{
// create new neutral hadron tower
tower = static_cast(fTower->Clone());
pt = hcalEnergy / TMath::CosH(eta);
tower->Momentum.SetPtEtaPhiE(pt, eta, phi, hcalEnergy);
tower->Eem = 0.0;
tower->Ehad = hcalEnergy;
fEFlowNeutralHadronOutputArray->Add(tower);
}
}
//------------------------------------------------------------------------------
Double_t Calorimeter::LogNormal(Double_t mean, Double_t sigma)
{
Double_t a, b;
if(mean > 0.0)
{
b = TMath::Sqrt(TMath::Log((1.0 + (sigma*sigma)/(mean*mean))));
a = TMath::Log(mean) - 0.5*b*b;
return TMath::Exp(a + b*gRandom->Gaus(0.0, 1.0));
}
else
{
return 0.0;
}
}