ZdcSimHitStudy Class Reference

#include <ZdcSimHitStudy.h>

Inheritance diagram for ZdcSimHitStudy:

Public Member Functions
	ZdcSimHitStudy (const edm::ParameterSet &ps)
	~ZdcSimHitStudy () override
Public Member Functions inherited from DQMEDAnalyzer
void	accumulate (edm::Event const &event, edm::EventSetup const &setup) final
void	beginLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final
void	beginRun (edm::Run const &run, edm::EventSetup const &setup) final
void	beginStream (edm::StreamID id) final
virtual void	dqmBeginRun (edm::Run const &, edm::EventSetup const &)
	DQMEDAnalyzer ()
void	endLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final
void	endRun (edm::Run const &run, edm::EventSetup const &setup) final
virtual bool	getCanSaveByLumi ()
Public Member Functions inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
	EDProducer ()=default
	EDProducer (const EDProducer &)=delete
bool	hasAbilityToProduceInBeginLumis () const final
bool	hasAbilityToProduceInBeginProcessBlocks () const final
bool	hasAbilityToProduceInBeginRuns () const final
bool	hasAbilityToProduceInEndLumis () const final
bool	hasAbilityToProduceInEndProcessBlocks () const final
bool	hasAbilityToProduceInEndRuns () const final
const EDProducer &	operator= (const EDProducer &)=delete

Protected Member Functions
void	analyze (const edm::Event &e, const edm::EventSetup &c) override
void	analyzeHits (std::vector< PCaloHit > &)
void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
int	FillHitValHist (int side, int section, int channel, double energy, double time)
Protected Member Functions inherited from DQMEDAnalyzer
uint64_t	meId () const

Private Attributes
bool	checkHit_
double	enetot
double	enetotEmN
double	enetotEmP
double	enetotHadN
double	enetotHadP
double	enetotN
double	enetotP
std::string	g4Label
MonitorElement *	genpart_GammaB
MonitorElement *	genpart_GammaB_counts
MonitorElement *	genpart_GammaB_energydist
MonitorElement *	genpart_GammaF
MonitorElement *	genpart_GammaF_counts
MonitorElement *	genpart_GammaF_energydist
MonitorElement *	genpart_NeutB
MonitorElement *	genpart_NeutB_counts
MonitorElement *	genpart_NeutB_energydist
MonitorElement *	genpart_NeutF
MonitorElement *	genpart_NeutF_counts
MonitorElement *	genpart_NeutF_energydist
MonitorElement *	genpart_Pi0B
MonitorElement *	genpart_Pi0B_counts
MonitorElement *	genpart_Pi0B_energydist
MonitorElement *	genpart_Pi0F
MonitorElement *	genpart_Pi0F_counts
MonitorElement *	genpart_Pi0F_energydist
MonitorElement *	meAllZdcNHit_
MonitorElement *	meBadZdcDetHit_
MonitorElement *	meBadZdcIdHit_
MonitorElement *	meBadZdcSecHit_
MonitorElement *	meZdc10Ene_
MonitorElement *	meZdc10EneP_
MonitorElement *	meZdcChannelHit_
MonitorElement *	meZdcCorEEmNEHadN_
MonitorElement *	meZdcCorEEmPEHadP_
MonitorElement *	meZdcCorEtotNEtotP_
MonitorElement *	meZdcDetectHit_
MonitorElement *	meZdcEEMCh_
MonitorElement *	meZdcEHadCh_
MonitorElement *	meZdcEMEnergyHit_
MonitorElement *	meZdcEML10EneP_
MonitorElement *	meZdcEneEmN1_
MonitorElement *	meZdcEneEmN2_
MonitorElement *	meZdcEneEmN3_
MonitorElement *	meZdcEneEmN4_
MonitorElement *	meZdcEneEmN5_
MonitorElement *	meZdcEneEmNTot_
MonitorElement *	meZdcEneEmP1_
MonitorElement *	meZdcEneEmP2_
MonitorElement *	meZdcEneEmP3_
MonitorElement *	meZdcEneEmP4_
MonitorElement *	meZdcEneEmP5_
MonitorElement *	meZdcEneEmPTot_
MonitorElement *	meZdcEneHadN1_
MonitorElement *	meZdcEneHadN2_
MonitorElement *	meZdcEneHadN3_
MonitorElement *	meZdcEneHadN4_
MonitorElement *	meZdcEneHadNTot_
MonitorElement *	meZdcEneHadP1_
MonitorElement *	meZdcEneHadP2_
MonitorElement *	meZdcEneHadP3_
MonitorElement *	meZdcEneHadP4_
MonitorElement *	meZdcEneHadPTot_
MonitorElement *	meZdcEneNTot_
MonitorElement *	meZdcEnePTot_
MonitorElement *	meZdcEnergyHit_
MonitorElement *	meZdcEneTEmN1_
MonitorElement *	meZdcEneTEmN2_
MonitorElement *	meZdcEneTEmN3_
MonitorElement *	meZdcEneTEmN4_
MonitorElement *	meZdcEneTEmN5_
MonitorElement *	meZdcEneTEmP1_
MonitorElement *	meZdcEneTEmP2_
MonitorElement *	meZdcEneTEmP3_
MonitorElement *	meZdcEneTEmP4_
MonitorElement *	meZdcEneTEmP5_
MonitorElement *	meZdcEneTHadN1_
MonitorElement *	meZdcEneTHadN2_
MonitorElement *	meZdcEneTHadN3_
MonitorElement *	meZdcEneTHadN4_
MonitorElement *	meZdcEneTHadP1_
MonitorElement *	meZdcEneTHadP2_
MonitorElement *	meZdcEneTHadP3_
MonitorElement *	meZdcEneTHadP4_
MonitorElement *	meZdcEneTot_
MonitorElement *	meZdcETime_
MonitorElement *	meZdcHadEnergyHit_
MonitorElement *	meZdcHadL10EneP_
MonitorElement *	meZdcNHit_
MonitorElement *	meZdcNHitEM_
MonitorElement *	meZdcNHitHad_
MonitorElement *	meZdcNHitLum_
MonitorElement *	meZdcSectionHit_
MonitorElement *	meZdcSideHit_
MonitorElement *	meZdcTimeHit_
MonitorElement *	meZdcTimeWHit_
std::string	outFile_
edm::EDGetTokenT< reco::GenParticleCollection >	tok_gen_
edm::EDGetTokenT< edm::PCaloHitContainer >	tok_hits_
bool	verbose_
std::string	zdcHits

Additional Inherited Members
Public Types inherited from DQMEDAnalyzer
typedef dqm::reco::DQMStore	DQMStore
typedef dqm::reco::MonitorElement	MonitorElement
Public Types inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
using	CacheTypes = CacheContexts< T... >
using	GlobalCache = typename CacheTypes::GlobalCache
using	HasAbility = AbilityChecker< T... >
using	InputProcessBlockCache = typename CacheTypes::InputProcessBlockCache
using	LuminosityBlockCache = typename CacheTypes::LuminosityBlockCache
using	LuminosityBlockContext = LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >
using	LuminosityBlockSummaryCache = typename CacheTypes::LuminosityBlockSummaryCache
using	RunCache = typename CacheTypes::RunCache
using	RunContext = RunContextT< RunCache, GlobalCache >
using	RunSummaryCache = typename CacheTypes::RunSummaryCache
Static Public Member Functions inherited from DQMEDAnalyzer
static void	globalEndJob (DQMEDAnalyzerGlobalCache const *)
static void	globalEndLuminosityBlockProduce (edm::LuminosityBlock &lumi, edm::EventSetup const &setup, LuminosityBlockContext const *context)
static void	globalEndRunProduce (edm::Run &run, edm::EventSetup const &setup, RunContext const *context)
static std::unique_ptr< DQMEDAnalyzerGlobalCache >	initializeGlobalCache (edm::ParameterSet const &)
Protected Attributes inherited from DQMEDAnalyzer
edm::EDPutTokenT< DQMToken >	lumiToken_
edm::EDPutTokenT< DQMToken >	runToken_
unsigned int	streamId_

Detailed Description

Definition at line 57 of file ZdcSimHitStudy.h.

Constructor & Destructor Documentation

ZdcSimHitStudy()

ZdcSimHitStudy::ZdcSimHitStudy

(

const edm::ParameterSet &

ps

)

Definition at line 33 of file ZdcSimHitStudy.cc.

                                                        {
  g4Label = ps.getUntrackedParameter<std::string>("moduleLabel", "g4SimHits");
  zdcHits = ps.getUntrackedParameter<std::string>("HitCollection", "ZdcHits");
  outFile_ = ps.getUntrackedParameter<std::string>("outputFile", "zdcHitStudy.root");
  verbose_ = ps.getUntrackedParameter<bool>("Verbose", false);
  checkHit_ = true;
 
  tok_gen_ = consumes<reco::GenParticleCollection>(edm::InputTag("genParticles"));
  tok_hits_ = consumes<edm::PCaloHitContainer>(edm::InputTag(g4Label, zdcHits));
 
  edm::LogInfo("ZdcSimHitStudy")
      // std::cout
      << "Module Label: " << g4Label << "   Hits: " << zdcHits << " / " << checkHit_ << "   Output: " << outFile_;
}

References checkHit_, g4Label, edm::ParameterSet::getUntrackedParameter(), outFile_, AlCaHLTBitMon_QueryRunRegistry::string, tok_gen_, tok_hits_, verbose_, and zdcHits.

~ZdcSimHitStudy()

ZdcSimHitStudy::~ZdcSimHitStudy ( )

override

Definition at line 48 of file ZdcSimHitStudy.cc.

{}

Member Function Documentation

analyze()

void ZdcSimHitStudy::analyze ( const edm::Event &  e, const edm::EventSetup &  c  )

overrideprotectedvirtual

GEN PARTICLE HISTOS///////////////////////////////////

Reimplemented from DQMEDAnalyzer.

Definition at line 527 of file ZdcSimHitStudy.cc.

                                                                                {
 
  using namespace edm;
  bool gotGenParticles = true;
 
  Handle<reco::GenParticleCollection> genhandle;
 
  if (!(iEvent.getByToken(tok_gen_, genhandle))) {
    gotGenParticles = false;  // this is the same kind of boolean except for the
                              // genparticles collection
  }
  if (!(genhandle.isValid())) {
    gotGenParticles = false;
  }
 
  // Handle<edm::PCaloHitContainer> zdcsimhandle;
 
 
  if (gotGenParticles == true) {  // if the boolean was able to find the leaf
                                  // "genparticles" then do this
    for (reco::GenParticleCollection::const_iterator gen = genhandle->begin(); gen != genhandle->end();
         ++gen)  // here we iterate over all generated particles
    {
      //         double energy=gen->energy();
      reco::GenParticle thisParticle = (reco::GenParticle)(*gen);  // get the particle "gen" points to
      double energy_2 = thisParticle.energy();  // here I grab some of the attributes of the generated
                                                // particle....like its energy, its phi and its eta and
                                                // what kind of particle it is
      double gen_phi = thisParticle.phi();
      double gen_eta = thisParticle.eta();
      int gen_id = thisParticle.pdgId();
 
      if (gen_id == 111) {    // here i require a pi0
        if (gen_eta > 8.3) {  // eta requirement
 
          //# IMPORTANT     IMPORTANT         IMPORTANT            IMPORTANT #
          //# The real eta of the ZDC is |eta| > 8.3, I have only changed it
          // here to 3 because# # in the PG simulation the ZDC is at an eta of
          // about 4.5-7, in the real GEANT the # # ZDC is in its appropriate
          // place at the very foward region...please edit this if # # looking
          // at MinBias data or the like # # # # IMPORTANT     IMPORTANT
          // IMPORTANT IMPORTANT                          #
 
          genpart_Pi0F->Fill(gen_eta, gen_phi, energy_2);  // fill the lego plot
          genpart_Pi0F_counts->Fill(gen_eta, gen_phi, 1);
          // genpart_Pi0F_profile->Fill(gen_eta,gen_phi,energy_2);
          genpart_Pi0F_energydist->Fill(energy_2);  // fill the 1D distribution
        }
        if (gen_eta < -8.3) {  // neg eta requirement
          genpart_Pi0B->Fill(gen_eta, gen_phi, energy_2);
          // genpart_Pi0B_profile->Fill(gen_eta,gen_phi,energy_2);
          genpart_Pi0B_counts->Fill(gen_eta, gen_phi, 1);
          genpart_Pi0B_energydist->Fill(energy_2);
        }
      }
      if (gen_id == 2112) {  // require neutron
        if (gen_eta > 8.3) {
          genpart_NeutF->Fill(gen_eta, gen_phi, energy_2);
          // genpart_NeutF_profile->Fill(gen_eta,gen_phi,energy_2);
          genpart_NeutF_counts->Fill(gen_eta, gen_phi, 1);
          genpart_NeutF_energydist->Fill(energy_2);
        }
        if (gen_eta < -8.3) {
          genpart_NeutB->Fill(gen_eta, gen_phi, energy_2);
          // genpart_NeutB_profile->Fill(gen_eta,gen_phi,energy_2);
          genpart_NeutB_counts->Fill(gen_eta, gen_phi, 1);
          genpart_NeutB_energydist->Fill(energy_2);
        }
      }
 
      if (gen_id == 22) {  // require gamma
        if (gen_eta > 8.3) {
          genpart_GammaF->Fill(gen_eta, gen_phi, energy_2);
          // genpart_GammaF_profile->Fill(gen_eta,gen_phi,energy_2);
          genpart_GammaF_counts->Fill(gen_eta, gen_phi, 1);
          genpart_GammaF_energydist->Fill(energy_2);
        }
        if (gen_eta < -8.3) {
          genpart_GammaB->Fill(gen_eta, gen_phi, energy_2);
          // genpart_GammaB_profile->Fill(gen_eta,gen_phi,energy_2);
          genpart_GammaB_counts->Fill(gen_eta, gen_phi, 1);
          genpart_GammaB_energydist->Fill(energy_2);
        }
      }
 
    }  // end of GEN loop
  }
 
 
  // Below is the old script which I will comment later
 
  edm::LogVerbatim("ZdcSimHitStudy") << "Run = " << iEvent.id().run() << " Event = " << iEvent.id().event();
 
  std::vector<PCaloHit> caloHits;
  edm::Handle<edm::PCaloHitContainer> hitsZdc;
 
  bool getHits = false;
  if (checkHit_) {
    iEvent.getByToken(tok_hits_, hitsZdc);
    if (hitsZdc.isValid())
      getHits = true;
  }
 
  edm::LogVerbatim("ZdcSim") << "ZdcValidation: Input flags Hits " << getHits;
 
  if (getHits) {
    caloHits.insert(caloHits.end(), hitsZdc->begin(), hitsZdc->end());
    edm::LogVerbatim("ZdcSimHitStudy") << "ZdcValidation: Hit buffer " << caloHits.size();
    analyzeHits(caloHits);
  }
}

References analyzeHits(), checkHit_, reco::LeafCandidate::energy(), reco::LeafCandidate::eta(), dqm::impl::MonitorElement::Fill(), relval_steps::gen(), genpart_GammaB, genpart_GammaB_counts, genpart_GammaB_energydist, genpart_GammaF, genpart_GammaF_counts, genpart_GammaF_energydist, genpart_NeutB, genpart_NeutB_counts, genpart_NeutB_energydist, genpart_NeutF, genpart_NeutF_counts, genpart_NeutF_energydist, genpart_Pi0B, genpart_Pi0B_counts, genpart_Pi0B_energydist, genpart_Pi0F, genpart_Pi0F_counts, genpart_Pi0F_energydist, GenParticle::GenParticle, iEvent, edm::HandleBase::isValid(), reco::LeafCandidate::pdgId(), reco::LeafCandidate::phi(), tok_gen_, and tok_hits_.

analyzeHits()

void ZdcSimHitStudy::analyzeHits ( std::vector< PCaloHit > &  hits )

protected

Definition at line 645 of file ZdcSimHitStudy.cc.

                                                          {
  int nHit = hits.size();
  int nZdcEM = 0, nZdcHad = 0, nZdcLum = 0;
  int nBad1 = 0, nBad2 = 0, nBad = 0;
  std::vector<double> encontZdcEM(140, 0.);
  std::vector<double> encontZdcHad(140, 0.);
  double entotZdcEM = 0;
  double entotZdcHad = 0;
 
  enetotEmN = 0;
  enetotHadN = 0.;
  enetotN = 0;
  enetotEmP = 0;
  enetotHadP = 0;
  enetotP = 0;
  enetot = 0;
 
  for (int i = 0; i < nHit; i++) {
    double energy = hits[i].energy();
    double log10en = log10(energy);
    int log10i = int((log10en + 10.) * 10.);
    double time = hits[i].time();
    unsigned int id_ = hits[i].id();
    HcalZDCDetId id = HcalZDCDetId(id_);
    int det = id.det();
    int side = id.zside();
    int section = id.section();
    int channel = id.channel();
 
    FillHitValHist(side, section, channel, energy, time);
 
    edm::LogVerbatim("ZdcSimHitStudy") << "Hit[" << i << "] ID " << std::hex << id_ << std::dec << " DetID " << id
                                       << " Det " << det << " side " << side << " Section " << section << " channel "
                                       << channel << " E " << energy << " time \n"
                                       << time;
 
    if (det == 5) {  // Check DetId.h
      if (section == HcalZDCDetId::EM)
        nZdcEM++;
      else if (section == HcalZDCDetId::HAD)
        nZdcHad++;
      else if (section == HcalZDCDetId::LUM)
        nZdcLum++;
      else {
        nBad++;
        nBad2++;
      }
    } else {
      nBad++;
      nBad1++;
    }
 
    meZdcDetectHit_->Fill(double(det));
    if (det == 5) {
      meZdcSideHit_->Fill(double(side));
      meZdcSectionHit_->Fill(double(section));
      meZdcChannelHit_->Fill(double(channel));
      meZdcEnergyHit_->Fill(energy);
      if (section == HcalZDCDetId::EM) {
        meZdcEMEnergyHit_->Fill(energy);
        meZdcEEMCh_->Fill(energy, channel);
        if (log10i >= 0 && log10i < 140)
          encontZdcEM[log10i] += energy;
        entotZdcEM += energy;
      }
      if (section == HcalZDCDetId::HAD) {
        meZdcHadEnergyHit_->Fill(energy);
        meZdcEHadCh_->Fill(energy, channel);
        if (log10i >= 0 && log10i < 140)
          encontZdcHad[log10i] += energy;
        entotZdcHad += energy;
      }
      meZdcTimeHit_->Fill(time);
      meZdcTimeWHit_->Fill(double(time), energy);
      meZdc10Ene_->Fill(log10en);
      meZdcETime_->Fill(energy, double(time));
    }
  }
 
  if (entotZdcEM != 0)
    for (int i = 0; i < 140; i++)
      meZdcEML10EneP_->Fill(-10. + (float(i) + 0.5) / 10., encontZdcEM[i] / entotZdcEM);
  if (entotZdcHad != 0)
    for (int i = 0; i < 140; i++)
      meZdcHadL10EneP_->Fill(-10. + (float(i) + 0.5) / 10., encontZdcHad[i] / entotZdcHad);
 
  if (nHit > 0) {
    meAllZdcNHit_->Fill(double(nHit));
    meBadZdcDetHit_->Fill(double(nBad1));
    meBadZdcSecHit_->Fill(double(nBad2));
    meBadZdcIdHit_->Fill(double(nBad));
    meZdcNHitEM_->Fill(double(nZdcEM));
    meZdcNHitHad_->Fill(double(nZdcHad));
    meZdcNHitLum_->Fill(double(nZdcLum));
    meZdcEnePTot_->Fill(enetotP);
    meZdcEneNTot_->Fill(enetotN);
    meZdcEneHadNTot_->Fill(enetotHadN);
    meZdcEneHadPTot_->Fill(enetotHadP);
    meZdcEneEmNTot_->Fill(enetotEmN);
    meZdcEneEmPTot_->Fill(enetotEmP);
    meZdcCorEEmNEHadN_->Fill(enetotEmN, enetotHadN);
    meZdcCorEEmPEHadP_->Fill(enetotEmP, enetotHadP);
    meZdcCorEtotNEtotP_->Fill(enetotN, enetotP);
    meZdcEneTot_->Fill(enetot);
  }
  edm::LogVerbatim("HcalSimHitStudy") << "HcalSimHitStudy::analyzeHits: Had " << nZdcHad << " EM " << nZdcEM << " Bad "
                                      << nBad << " All " << nHit;
}

References TauDecayModes::dec, HcalZDCDetId::EM, HCALHighEnergyHPDFilter_cfi::energy, enetot, enetotEmN, enetotEmP, enetotHadN, enetotHadP, enetotN, enetotP, dqm::impl::MonitorElement::Fill(), FillHitValHist(), HcalZDCDetId::HAD, hfClusterShapes_cfi::hits, mps_fire::i, createfilelist::int, HcalZDCDetId::LUM, meAllZdcNHit_, meBadZdcDetHit_, meBadZdcIdHit_, meBadZdcSecHit_, meZdc10Ene_, meZdcChannelHit_, meZdcCorEEmNEHadN_, meZdcCorEEmPEHadP_, meZdcCorEtotNEtotP_, meZdcDetectHit_, meZdcEEMCh_, meZdcEHadCh_, meZdcEMEnergyHit_, meZdcEML10EneP_, meZdcEneEmNTot_, meZdcEneEmPTot_, meZdcEneHadNTot_, meZdcEneHadPTot_, meZdcEneNTot_, meZdcEnePTot_, meZdcEnergyHit_, meZdcEneTot_, meZdcETime_, meZdcHadEnergyHit_, meZdcHadL10EneP_, meZdcNHitEM_, meZdcNHitHad_, meZdcNHitLum_, meZdcSectionHit_, meZdcSideHit_, meZdcTimeHit_, meZdcTimeWHit_, hgcalPlots::section, and protons_cff::time.

Referenced by analyze().

bookHistograms()

void ZdcSimHitStudy::bookHistograms ( DQMStore::IBooker &  ib, edm::Run const &  run, edm::EventSetup const &  es  )

overrideprotectedvirtual

GenParticle Plots///////////////////////////////////////

GEN Particle Energy Distributions/////////////////////

Implements DQMEDAnalyzer.

Definition at line 50 of file ZdcSimHitStudy.cc.

                                                                                                   {
  ib.setCurrentFolder("ZDCValidation");
  // Histograms for Hits
  //# Below we are filling the histograms made in the .h file. The syntax is as
  // follows:                                      # # plot_code_name =
  // ib.TypeofPlot[(1,2,3)-D,(F,I,D)]("Name as it will appear","Title",axis
  // options);                    # # They will be stored in the TFile
  // subdirectory set by :    ib.setCurrentFolder("FolderIwant") # # axis
  // options are like (#ofbins,min,max) #
 
  if (checkHit_) {
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits");
    meAllZdcNHit_ = ib.book1D("ZDC Hits", "Number of All Hits in ZDC", 100, 0., 100.);
    meAllZdcNHit_->setAxisTitle("Total Hits", 1);
    meAllZdcNHit_->setAxisTitle("Counts", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/Excess_Info/Debug_Helper");
    meBadZdcDetHit_ = ib.book1D("Hiits with the wrong Det", "Hits with wrong Det in ZDC", 100, 0., 100.);
    meBadZdcDetHit_->setAxisTitle("Wrong Hits", 1);
    meBadZdcDetHit_->setAxisTitle("Counts", 2);
    meBadZdcSecHit_ = ib.book1D("Wrong Section Hits", "Hits with wrong Section in ZDC", 100, 0., 100.);
    meBadZdcSecHit_->setAxisTitle("Hits in wrong section", 1);
    meBadZdcSecHit_->setAxisTitle("Counts", 2);
    meBadZdcIdHit_ = ib.book1D("Wrong_ID_Hits", "Hits with wrong ID in ZDC", 100, 0., 100.);
    meBadZdcIdHit_->setAxisTitle("Hits with wrong ID", 1);
    meBadZdcIdHit_->setAxisTitle("Counts", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/Excess_Info/BasicHitInfo");
    meZdcNHitEM_ = ib.book1D("Hits in EM", "Number of Hits in ZDC EM", 100, 0., 100.);
    meZdcNHitEM_->setAxisTitle("EM Hits", 1);
    meZdcNHitEM_->setAxisTitle("Counts", 2);
    meZdcNHitHad_ = ib.book1D("Hits in HAD", "Number of Hits in ZDC Had", 100, 0., 100.);
    meZdcNHitHad_->setAxisTitle("HAD Hits", 1);
    meZdcNHitHad_->setAxisTitle("Counts", 2);
    meZdcNHitLum_ = ib.book1D("Hits in LUM", "Number of Hits in ZDC Lum", 100, 0., 100.);
    meZdcNHitLum_->setAxisTitle("LUM Hits", 1);
    meZdcNHitLum_->setAxisTitle("Counts", 2);
    meZdcDetectHit_ = ib.book1D("Calo Detector ID", "Calo Detector ID", 50, 0., 50.);
    meZdcDetectHit_->setAxisTitle("Detector Hits", 1);
    meZdcDetectHit_->setAxisTitle("Counts", 2);
    meZdcSideHit_ = ib.book1D("ZDC Side", "Side in ZDC", 4, -2, 2.);
    meZdcSideHit_->setAxisTitle("ZDC Side", 1);
    meZdcSideHit_->setAxisTitle("Counts", 2);
    meZdcSectionHit_ = ib.book1D("ZDC Section", "Section in ZDC", 4, 0., 4.);
    meZdcSectionHit_->setAxisTitle("ZDC Section", 1);
    meZdcSectionHit_->setAxisTitle("Counts", 2);
    meZdcChannelHit_ = ib.book1D("ZDC Channel", "Channel in ZDC", 10, 0., 10.);
    meZdcChannelHit_->setAxisTitle("ZDC Channel", 1);
    meZdcChannelHit_->setAxisTitle("Counts", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/");
    meZdcEnergyHit_ = ib.book1D("Hit Energy", "Hits Energy", 4000, 0., 8000.);
    meZdcEnergyHit_->setAxisTitle("Counts", 2);
    meZdcEnergyHit_->setAxisTitle("Energy (GeV)", 1);
    meZdcHadEnergyHit_ = ib.book1D("Hit Energy HAD", "Hits Energy in Had Section", 4000, 0., 8000.);
    meZdcHadEnergyHit_->setAxisTitle("Counts", 2);
    meZdcHadEnergyHit_->setAxisTitle("Energy (GeV)", 1);
    meZdcEMEnergyHit_ = ib.book1D("Hit Energy EM", "Hits Energy in EM Section", 4000, 0., 8000.);
    meZdcEMEnergyHit_->setAxisTitle("Counts", 2);
    meZdcEMEnergyHit_->setAxisTitle("Energy (GeV)", 1);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/Excess_Info/BasicHitInfo");
    meZdcTimeHit_ = ib.book1D("Time in ZDC", "Time in ZDC", 300, 0., 600.);
    meZdcTimeHit_->setAxisTitle("Time (ns)", 1);
    meZdcTimeHit_->setAxisTitle("Counts", 2);
    meZdcTimeWHit_ = ib.book1D("Energy Weighted Time in ZDC", "Time in ZDC (E wtd)", 300, 0., 600.);
    meZdcTimeWHit_->setAxisTitle("Time (ns)", 1);
    meZdcTimeWHit_->setAxisTitle("Counts", 2);
    meZdc10Ene_ = ib.book1D("ZDC Log(E)", "Log10Energy in ZDC", 140, -20., 20.);
    meZdc10Ene_->setAxisTitle("Log(E) (GeV)", 1);
    meZdc10Ene_->setAxisTitle("Counts", 2);
    meZdcHadL10EneP_ = ib.bookProfile(
        "Log(EHAD) vs Contribution", "Log10Energy in Had ZDC vs Hit contribution", 140, -1., 20., 100, 0., 1.);
    meZdcHadL10EneP_->setAxisTitle("Log(EHAD) (GeV)", 1);
    meZdcHadL10EneP_->setAxisTitle("Counts", 2);
    meZdcEML10EneP_ = ib.bookProfile(
        "Log(EEM) vs Contribution", "Log10Energy in EM ZDC vs Hit contribution", 140, -1., 20., 100, 0., 1.);
    meZdcEML10EneP_->setAxisTitle("Log(EEM) (GeV)", 1);
    meZdcEML10EneP_->setAxisTitle("Counts", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits");
    meZdcEHadCh_ = ib.book2D("ZDC EHAD vs Channel", "ZDC Had Section Energy vs Channel", 4000, 0., 8000., 6, 0., 6.);
    meZdcEHadCh_->setAxisTitle("Hadronic Channel Number", 2);
    meZdcEHadCh_->setAxisTitle("Energy (GeV)", 1);
    meZdcEEMCh_ = ib.book2D("ZDC EEM vs Channel", "ZDC EM Section Energy vs Channel", 4000, 0., 8000., 6, 0., 6.);
    meZdcEEMCh_->setAxisTitle("EM Channel Number", 2);
    meZdcEEMCh_->setAxisTitle("Energy (GeV)", 1);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/Excess_Info/BasicHitInfo");
    meZdcETime_ = ib.book2D("E vs T", "Hits ZDC Energy vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcETime_->setAxisTitle("Energy (GeV)", 1);
    meZdcETime_->setAxisTitle("Time (ns)", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/ENERGY_SUMS/Individual_Channels/NZDC");
    meZdcEneEmN1_ = ib.book1D("NZDC EM1 Energy", "Energy EM module N1", 4000, 0., 8000.);
    meZdcEneEmN1_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmN1_->setAxisTitle("Counts", 2);
    meZdcEneEmN2_ = ib.book1D("NZDC EM2 Energy", "Energy EM module N2", 4000, 0., 8000.);
    meZdcEneEmN2_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmN2_->setAxisTitle("Counts", 2);
    meZdcEneEmN3_ = ib.book1D("NZDC EM3 Energy", "Energy EM module N3", 4000, 0., 8000.);
    meZdcEneEmN3_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmN3_->setAxisTitle("Counts", 2);
    meZdcEneEmN4_ = ib.book1D("NZDC EM4 Energy", "Energy EM module N4", 4000, 0., 8000.);
    meZdcEneEmN4_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmN4_->setAxisTitle("Counts", 2);
    meZdcEneEmN5_ = ib.book1D("NZDC EM5 Energy", "Energy EM module N5", 4000, 0., 8000.);
    meZdcEneEmN5_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmN5_->setAxisTitle("Counts", 2);
    meZdcEneHadN1_ = ib.book1D("NZDC HAD1 Energy", "Energy HAD module N1", 4000, 0., 8000.);
    meZdcEneHadN1_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadN1_->setAxisTitle("Counts", 2);
    meZdcEneHadN2_ = ib.book1D("NZDC HAD2 Energy", "Energy HAD module N2", 4000, 0., 8000.);
    meZdcEneHadN2_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadN2_->setAxisTitle("Counts", 2);
    meZdcEneHadN3_ = ib.book1D("NZDC HAD3 Energy", "Energy HAD module N3", 4000, 0., 8000.);
    meZdcEneHadN3_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadN3_->setAxisTitle("Counts", 2);
    meZdcEneHadN4_ = ib.book1D("NZDC HAD4 Energy", "Energy HAD module N4", 4000, 0., 8000.);
    meZdcEneHadN4_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadN4_->setAxisTitle("Counts", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/Excess_Info/Individual_ChannelvsTime/NZDC");
    meZdcEneTEmN1_ = ib.book2D("NZDC EM1 Energy vs Time", "Energy EM mod N1 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmN1_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmN1_->setAxisTitle("Time (ns)", 2);
    meZdcEneTEmN2_ = ib.book2D("NZDC EM2 Energy vs Time", "Energy EM mod N2 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmN2_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmN2_->setAxisTitle("Time (ns)", 2);
    meZdcEneTEmN3_ = ib.book2D("NZDC EM3 Energy vs Time", "Energy EM mod N3 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmN3_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmN3_->setAxisTitle("Time (ns)", 2);
    meZdcEneTEmN4_ = ib.book2D("NZDC EM4 Energy vs Time", "Energy EM mod N4 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmN4_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmN4_->setAxisTitle("Time (ns)", 2);
    meZdcEneTEmN5_ = ib.book2D("NZDC EM5 Energy vs Time", "Energy EM mod N5 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmN5_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmN5_->setAxisTitle("Time (ns)", 2);
    meZdcEneTHadN1_ =
        ib.book2D("NZDC HAD1 Energy vs Time", "Energy HAD mod N1 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTHadN1_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTHadN1_->setAxisTitle("Time (ns)", 2);
    meZdcEneTHadN2_ =
        ib.book2D("NZDC HAD2 Energy vs Time", "Energy HAD mod N2 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTHadN2_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTHadN2_->setAxisTitle("Time (ns)", 2);
    meZdcEneTHadN3_ =
        ib.book2D("NZDC HAD3 Energy vs Time", "Energy HAD mod N3 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTHadN3_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTHadN3_->setAxisTitle("Time (ns)", 2);
    meZdcEneTHadN4_ =
        ib.book2D("NZDC HAD4 Energy vs Time", "Energy HAD mod N4 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTHadN4_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTHadN4_->setAxisTitle("Time (ns)", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/ENERGY_SUMS/NZDC");
    meZdcEneHadNTot_ = ib.book1D("NZDC EHAD", "Total N-ZDC HAD Energy", 4000, 0., 4000.);
    meZdcEneHadNTot_->setAxisTitle("Counts", 2);
    meZdcEneHadNTot_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmNTot_ = ib.book1D("NZDC EEM", "Total N-ZDC EM Energy", 3000, 0., 3000.);
    meZdcEneEmNTot_->setAxisTitle("Counts", 2);
    meZdcEneEmNTot_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneNTot_ = ib.book1D("NZDC ETOT", "Total N-ZDC Energy ", 7000, 0., 7000.);
    meZdcEneNTot_->setAxisTitle("Counts", 2);
    meZdcEneNTot_->setAxisTitle("Energy (GeV)", 1);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/ENERGY_SUMS/Individual_Channels/PZDC");
    meZdcEneEmP1_ = ib.book1D("PZDC EM1 Energy", "Energy EM module P1", 3000, 0., 3000.);
    meZdcEneEmP1_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmP1_->setAxisTitle("Counts", 2);
    meZdcEneEmP2_ = ib.book1D("PZDC EM2 Energy", "Energy EM module P2", 3000, 0., 3000.);
    meZdcEneEmP2_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmP2_->setAxisTitle("Counts", 2);
    meZdcEneEmP3_ = ib.book1D("PZDC EM3 Energy", "Energy EM module P3", 3000, 0., 3000.);
    meZdcEneEmP3_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmP3_->setAxisTitle("Counts", 2);
    meZdcEneEmP4_ = ib.book1D("PZDC EM4 Energy", "Energy EM module P4", 3000, 0., 3000.);
    meZdcEneEmP4_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmP4_->setAxisTitle("Counts", 2);
    meZdcEneEmP5_ = ib.book1D("PZDC EM5 Energy", "Energy EM module P5", 3000, 0., 3000.);
    meZdcEneEmP5_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmP5_->setAxisTitle("Counts", 2);
    meZdcEneHadP1_ = ib.book1D("PZDC HAD1 Energy", "Energy HAD module P1", 3000, 0., 3000.);
    meZdcEneHadP1_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadP1_->setAxisTitle("Counts", 2);
    meZdcEneHadP2_ = ib.book1D("PZDC HAD2 Energy", "Energy HAD module P2", 3000, 0., 3000.);
    meZdcEneHadP2_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadP2_->setAxisTitle("Counts", 2);
    meZdcEneHadP3_ = ib.book1D("PZDC HAD3 Energy", "Energy HAD module P3", 3000, 0., 3000.);
    meZdcEneHadP3_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadP3_->setAxisTitle("Counts", 2);
    meZdcEneHadP4_ = ib.book1D("PZDC HAD4 Energy", "Energy HAD module P4", 3000, 0., 3000.);
    meZdcEneHadP4_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadP4_->setAxisTitle("Counts", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/Excess_Info/Individual_ChannelvsTime/PZDC");
    meZdcEneTEmP1_ = ib.book2D("PZDC EM1 Energy vs Time", "Energy EM mod P1 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmP1_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmP1_->setAxisTitle("Time (ns)", 2);
    meZdcEneTEmP2_ = ib.book2D("PZDC EM2 Energy vs Time", "Energy EM mod P2 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmP2_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmP2_->setAxisTitle("Time (ns)", 2);
    meZdcEneTEmP3_ = ib.book2D("PZDC EM3 Energy vs Time", "Energy EM mod P3 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmP3_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmP3_->setAxisTitle("Time (ns)", 2);
    meZdcEneTEmP4_ = ib.book2D("PZDC EM4 Energy vs Time", "Energy EM mod P4 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmP4_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmP4_->setAxisTitle("Time (ns)", 2);
    meZdcEneTEmP5_ = ib.book2D("PZDC EM5 Energy vs Time", "Energy EM mod P5 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTEmP5_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTEmP5_->setAxisTitle("Time (ns)", 2);
    meZdcEneTHadP1_ =
        ib.book2D("PZDC HAD1 Energy vs Time", "Energy HAD mod P1 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTHadP1_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTHadP1_->setAxisTitle("Time (ns)", 2);
    meZdcEneTHadP2_ =
        ib.book2D("PZDC HAD2 Energy vs Time", "Energy HAD mod P2 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTHadP2_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTHadP2_->setAxisTitle("Time (ns)", 2);
    meZdcEneTHadP3_ =
        ib.book2D("PZDC HAD3 Energy vs Time", "Energy HAD mod P3 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTHadP3_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTHadP3_->setAxisTitle("Time (ns)", 2);
    meZdcEneTHadP4_ =
        ib.book2D("PZDC HAD4 Energy vs Time", "Energy HAD mod P4 vs Time", 4000, 0., 8000., 300, 0., 600.);
    meZdcEneTHadP4_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneTHadP4_->setAxisTitle("Time (ns)", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/ENERGY_SUMS/PZDC");
    meZdcEneHadPTot_ = ib.book1D("PZDC EHAD", "Total P-ZDC HAD Energy", 10000, 0., 10000.);
    meZdcEneHadPTot_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneHadPTot_->setAxisTitle("Counts", 2);
    meZdcEneEmPTot_ = ib.book1D("PZDC EEM", "Total P-ZDC EM Energy", 10000, 0., 10000.);
    meZdcEneEmPTot_->setAxisTitle("Energy (GeV)", 1);
    meZdcEneEmPTot_->setAxisTitle("Counts", 2);
    meZdcEnePTot_ = ib.book1D("PZDC ETOT", "Total P-ZDC Energy", 10000, 0., 10000.);
    meZdcEnePTot_->setAxisTitle("Energy (GeV)", 1);
    meZdcEnePTot_->setAxisTitle("Counts", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/ENERGY_SUMS/NZDC");
    meZdcCorEEmNEHadN_ = ib.book2D("NZDC EMvHAD", "N-ZDC Energy EM vs HAD", 3000, 0., 3000., 3000, 0., 3000.);
    meZdcCorEEmNEHadN_->setAxisTitle("EM Energy (GeV)", 1);
    meZdcCorEEmNEHadN_->setAxisTitle("HAD Energy (GeV)", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/ENERGY_SUMS/PZDC");
    meZdcCorEEmPEHadP_ = ib.book2D("PZDC EMvHAD", "P-ZDC Energy EM vs HAD", 3000, 0., 3000., 3000, 0., 3000.);
    meZdcCorEEmPEHadP_->setAxisTitle("EM Energy (GeV)", 1);
    meZdcCorEEmPEHadP_->setAxisTitle("HAD Energy (GeV)", 2);
    ib.setCurrentFolder("ZDCValidation/ZdcSimHits/ENERGY_SUMS");
    meZdcCorEtotNEtotP_ = ib.book2D("PZDC vs NZDC", "Energy N-ZDC vs P-ZDC", 3000, 0., 3000., 3000, 0., 3000.);
    meZdcCorEtotNEtotP_->setAxisTitle("N-ZDC Total Energy (GeV)", 1);
    meZdcCorEtotNEtotP_->setAxisTitle("P-ZDC Total Energy (GeV)", 2);
    meZdcEneTot_ = ib.book1D("ETOT ZDCs", "Total Energy ZDCs", 3000, 0., 3000.);
    meZdcEneTot_->setAxisTitle("Counts", 2);
    meZdcEneTot_->setAxisTitle("Energy (GeV)", 1);
 
 
    ib.setCurrentFolder("ZDCValidation/GenParticles/Forward");
    genpart_Pi0F = ib.book2D("Pi0_Forward", "Forward Generated Pi0s", 200, 7.5, 13, 100, -3.15, 3.15);
    genpart_Pi0F->setAxisTitle("Eta", 1);
    genpart_Pi0F->setAxisTitle("Phi (radians)", 2);
    genpart_Pi0F->setAxisTitle("Energy (GeV)", 3);
    genpart_Pi0F->setOption("lego2z,prof");
    genpart_Pi0F->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_Pi0F->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_Pi0F_counts =
        ib.book2D("Pi0_Forward_Counts", "Number of Forward Generated Pi0s", 200, 7.5, 13, 100, -3.15, 3.15);
    genpart_Pi0F_counts->setAxisTitle("#eta", 1);
    genpart_Pi0F_counts->setAxisTitle("#phi (radians)", 2);
    genpart_Pi0F_counts->setAxisTitle("Energy (GeV)", 3);
    genpart_Pi0F_counts->setOption("lego2z,prof");
    genpart_Pi0F_counts->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_Pi0F_counts->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_NeutF = ib.book2D("Neutron_Forward", "Forward Generated Neutrons", 200, 7.5, 13, 100, -3.15, 3.15);
    genpart_NeutF->setAxisTitle("Eta", 1);
    genpart_NeutF->setAxisTitle("Phi (radians)", 2);
    genpart_NeutF->setAxisTitle("Energy (GeV)", 3);
    genpart_NeutF->setOption("lego2z,prof");
    genpart_NeutF->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_NeutF->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_NeutF_counts =
        ib.book2D("Neutron_Forward_Counts", "Number of Forward Generated Neutrons", 200, 7.5, 13, 100, -3.15, 3.15);
    genpart_NeutF_counts->setAxisTitle("#eta", 1);
    genpart_NeutF_counts->setAxisTitle("#phi (radians)", 2);
    genpart_NeutF_counts->setAxisTitle("Energy (GeV)", 3);
    genpart_NeutF_counts->setOption("lego2z,prof");
    genpart_NeutF_counts->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_NeutF_counts->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_GammaF = ib.book2D("Gamma_Forward", "Forward Generated Gammas", 200, 7.5, 13, 100, -3.15, 3.15);
    genpart_GammaF->setAxisTitle("Eta", 1);
    genpart_GammaF->setAxisTitle("Phi (radians)", 2);
    genpart_GammaF->setAxisTitle("Energy (GeV)", 3);
    genpart_GammaF->setOption("lego2z,prof");
    genpart_GammaF->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_GammaF->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_GammaF_counts =
        ib.book2D("Gamma_Forward_Counts", "Number of Forward Generated Gammas", 200, 7.5, 13, 100, -3.15, 3.15);
    genpart_GammaF_counts->setAxisTitle("#eta", 1);
    genpart_GammaF_counts->setAxisTitle("#phi (radians)", 2);
    genpart_GammaF_counts->setAxisTitle("Energy (GeV)", 3);
    genpart_GammaF_counts->setOption("lego2z,prof");
    genpart_GammaF_counts->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_GammaF_counts->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_Pi0F_energydist = ib.book1D("Pi0_Forward_EDistribution", "Gen-Level Forward Pi0 Energy", 1500, 0, 1500);
    genpart_Pi0F_energydist->setAxisTitle("Energy (GeV)", 1);
    genpart_Pi0F_energydist->setAxisTitle("Counts", 2);
    genpart_NeutF_energydist = ib.book1D("N_Forward_EDistribution", "Gen-Level Forward Neutron Energy", 1500, 0, 1500);
    genpart_NeutF_energydist->setAxisTitle("Energy (GeV)", 1);
    genpart_NeutF_energydist->setAxisTitle("Counts", 2);
    genpart_GammaF_energydist =
        ib.book1D("Gamma_Forward_EDistribution", "Gen-Level Fowarad Gamma Energy", 1500, 0, 1500);
    genpart_GammaF_energydist->setAxisTitle("Energy (GeV)", 1);
    genpart_GammaF_energydist->setAxisTitle("Counts", 2);
    ib.setCurrentFolder("ZDCValidation/GenParticles/Backward");
    genpart_Pi0B = ib.book2D("Pi0_Backward", "Backward Generated Pi0s", 1000, -13, -7.5, 100, -3.15, 3.15);
    genpart_Pi0B->setAxisTitle("Eta", 1);
    genpart_Pi0B->setAxisTitle("Phi (radians)", 2);
    genpart_Pi0B->setAxisTitle("Energy (GeV)", 3);
    genpart_Pi0B->setOption("lego2z,prof");
    genpart_Pi0B->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_Pi0B->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_Pi0B_counts =
        ib.book2D("Pi0_Backwards_Counts", "Number of Backward Generated Pi0s", 200, -13, -7.5, 100, -3.15, 3.15);
    genpart_Pi0B_counts->setAxisTitle("#eta", 1);
    genpart_Pi0B_counts->setAxisTitle("#phi (radians)", 2);
    genpart_Pi0B_counts->setAxisTitle("Energy (GeV)", 3);
    genpart_Pi0B_counts->setOption("lego2z,prof");
    genpart_Pi0B_counts->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_Pi0B_counts->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_NeutB = ib.book2D("Neutron_Backward", "Backward Generated Neutrons", 1000, -13, -7.5, 100, -3.15, 3.15);
    genpart_NeutB->setAxisTitle("Eta", 1);
    genpart_NeutB->setAxisTitle("Phi (radians)", 2);
    genpart_NeutB->setAxisTitle("Energy (GeV)", 3);
    genpart_NeutB->setOption("lego2z,prof");
    genpart_NeutB->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_NeutB->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_NeutB_counts = ib.book2D(
        "Neutron_Backwards_Counts", "Number of Backward Generated Neutrons", 200, -13, -7.5, 100, -3.15, 3.15);
    genpart_NeutB_counts->setAxisTitle("#eta", 1);
    genpart_NeutB_counts->setAxisTitle("#phi (radians)", 2);
    genpart_NeutB_counts->setAxisTitle("Energy (GeV)", 3);
    genpart_NeutB_counts->setOption("lego2z,prof");
    genpart_NeutB_counts->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_NeutB_counts->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_GammaB = ib.book2D("Gamma_Backward", "Backward Generated Gammas", 1000, -13, -7.5, 100, -3.15, 3.15);
    genpart_GammaB->setAxisTitle("Eta", 1);
    genpart_GammaB->setAxisTitle("Phi (radians)", 2);
    genpart_GammaB->setAxisTitle("Energy (GeV)", 3);
    genpart_GammaB->setOption("lego2z,prof");
    genpart_GammaB->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_GammaB->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_GammaB_counts =
        ib.book2D("Gamma_Backwards_Counts", "Number of Backward Generated Gammas", 200, -13, -7.5, 100, -3.15, 3.15);
    genpart_GammaB_counts->setAxisTitle("#eta", 1);
    genpart_GammaB_counts->setAxisTitle("#phi (radians)", 2);
    genpart_GammaB_counts->setAxisTitle("Energy (GeV)", 3);
    genpart_GammaB_counts->setOption("lego2z,prof");
    genpart_GammaB_counts->getTH2F()->SetTitleOffset(1.4, "x");
    genpart_GammaB_counts->getTH2F()->SetTitleOffset(1.4, "y");
 
    genpart_Pi0B_energydist = ib.book1D("Pi0_Backward_EDistribution", "Gen-Level Backward Pi0 Energy", 1500, 0, 1500);
    genpart_Pi0B_energydist->setAxisTitle("Energy (GeV)", 1);
    genpart_Pi0B_energydist->setAxisTitle("Counts", 2);
    genpart_NeutB_energydist = ib.book1D("N_Backward_EDistribution", "Gen-Level Foward Neutron Energy", 1500, 0, 1500);
    genpart_NeutB_energydist->setAxisTitle("Energy (GeV)", 1);
    genpart_NeutB_energydist->setAxisTitle("Counts", 2);
    genpart_GammaB_energydist =
        ib.book1D("Gamma_Backward_EDistribution", "Gen-Level Backward Gamma Energy", 1500, 0, 1500);
    genpart_GammaB_energydist->setAxisTitle("Energy (GeV)", 1);
    genpart_GammaB_energydist->setAxisTitle("Counts", 2);
  }
}

References checkHit_, genpart_GammaB, genpart_GammaB_counts, genpart_GammaB_energydist, genpart_GammaF, genpart_GammaF_counts, genpart_GammaF_energydist, genpart_NeutB, genpart_NeutB_counts, genpart_NeutB_energydist, genpart_NeutF, genpart_NeutF_counts, genpart_NeutF_energydist, genpart_Pi0B, genpart_Pi0B_counts, genpart_Pi0B_energydist, genpart_Pi0F, genpart_Pi0F_counts, genpart_Pi0F_energydist, dqm::impl::MonitorElement::getTH2F(), cuy::ib, meAllZdcNHit_, meBadZdcDetHit_, meBadZdcIdHit_, meBadZdcSecHit_, meZdc10Ene_, meZdcChannelHit_, meZdcCorEEmNEHadN_, meZdcCorEEmPEHadP_, meZdcCorEtotNEtotP_, meZdcDetectHit_, meZdcEEMCh_, meZdcEHadCh_, meZdcEMEnergyHit_, meZdcEML10EneP_, meZdcEneEmN1_, meZdcEneEmN2_, meZdcEneEmN3_, meZdcEneEmN4_, meZdcEneEmN5_, meZdcEneEmNTot_, meZdcEneEmP1_, meZdcEneEmP2_, meZdcEneEmP3_, meZdcEneEmP4_, meZdcEneEmP5_, meZdcEneEmPTot_, meZdcEneHadN1_, meZdcEneHadN2_, meZdcEneHadN3_, meZdcEneHadN4_, meZdcEneHadNTot_, meZdcEneHadP1_, meZdcEneHadP2_, meZdcEneHadP3_, meZdcEneHadP4_, meZdcEneHadPTot_, meZdcEneNTot_, meZdcEnePTot_, meZdcEnergyHit_, meZdcEneTEmN1_, meZdcEneTEmN2_, meZdcEneTEmN3_, meZdcEneTEmN4_, meZdcEneTEmN5_, meZdcEneTEmP1_, meZdcEneTEmP2_, meZdcEneTEmP3_, meZdcEneTEmP4_, meZdcEneTEmP5_, meZdcEneTHadN1_, meZdcEneTHadN2_, meZdcEneTHadN3_, meZdcEneTHadN4_, meZdcEneTHadP1_, meZdcEneTHadP2_, meZdcEneTHadP3_, meZdcEneTHadP4_, meZdcEneTot_, meZdcETime_, meZdcHadEnergyHit_, meZdcHadL10EneP_, meZdcNHitEM_, meZdcNHitHad_, meZdcNHitLum_, meZdcSectionHit_, meZdcSideHit_, meZdcTimeHit_, meZdcTimeWHit_, dqm::impl::MonitorElement::setAxisTitle(), and dqm::impl::MonitorElement::setOption().

FillHitValHist()

int ZdcSimHitStudy::FillHitValHist ( int  side, int  section, int  channel, double  energy, double  time  )

protected

Definition at line 754 of file ZdcSimHitStudy.cc.

                                                                                                 {
  enetot += enetot;
  if (side == -1) {
    enetotN += energy;
    if (section == HcalZDCDetId::EM) {
      enetotEmN += energy;
      switch (channel) {
        case 1:
          meZdcEneEmN1_->Fill(energy);
          meZdcEneTEmN1_->Fill(energy, time);
          break;
        case 2:
          meZdcEneEmN2_->Fill(energy);
          meZdcEneTEmN2_->Fill(energy, time);
          break;
        case 3:
          meZdcEneEmN3_->Fill(energy);
          meZdcEneTEmN3_->Fill(energy, time);
          break;
        case 4:
          meZdcEneEmN4_->Fill(energy);
          meZdcEneTEmN4_->Fill(energy, time);
          break;
        case 5:
          meZdcEneEmN4_->Fill(energy);
          meZdcEneTEmN4_->Fill(energy, time);
          break;
      }
    }
    if (section == HcalZDCDetId::HAD) {
      enetotHadN += energy;
      switch (channel) {
        case 1:
          meZdcEneHadN1_->Fill(energy);
          meZdcEneTHadN1_->Fill(energy, time);
          break;
        case 2:
          meZdcEneHadN2_->Fill(energy);
          meZdcEneTHadN2_->Fill(energy, time);
          break;
        case 3:
          meZdcEneHadN3_->Fill(energy);
          meZdcEneTHadN3_->Fill(energy, time);
          break;
        case 4:
          meZdcEneHadN4_->Fill(energy);
          meZdcEneTHadN4_->Fill(energy, time);
          break;
      }
    }
  }
  if (side == 1) {
    enetotP += energy;
    if (section == HcalZDCDetId::EM) {
      enetotEmP += energy;
      switch (channel) {
        case 1:
          meZdcEneEmP1_->Fill(energy);
          meZdcEneTEmP1_->Fill(energy, time);
          break;
        case 2:
          meZdcEneEmP2_->Fill(energy);
          meZdcEneTEmP2_->Fill(energy, time);
          break;
        case 3:
          meZdcEneEmP3_->Fill(energy);
          meZdcEneTEmP3_->Fill(energy, time);
          break;
        case 4:
          meZdcEneEmP4_->Fill(energy);
          meZdcEneTEmP4_->Fill(energy, time);
          break;
        case 5:
          meZdcEneEmP4_->Fill(energy);
          meZdcEneTEmP4_->Fill(energy, time);
          break;
      }
    }
    if (section == HcalZDCDetId::HAD) {
      enetotHadP += energy;
      switch (channel) {
        case 1:
          meZdcEneHadP1_->Fill(energy);
          meZdcEneTHadP1_->Fill(energy, time);
          break;
        case 2:
          meZdcEneHadP2_->Fill(energy);
          meZdcEneTHadP2_->Fill(energy, time);
          break;
        case 3:
          meZdcEneHadP3_->Fill(energy);
          meZdcEneTHadP3_->Fill(energy, time);
          break;
        case 4:
          meZdcEneHadP4_->Fill(energy);
          meZdcEneTHadP4_->Fill(energy, time);
          break;
      }
    }
  }
  return 0;
}

References HcalZDCDetId::EM, HCALHighEnergyHPDFilter_cfi::energy, enetot, enetotEmN, enetotEmP, enetotHadN, enetotHadP, enetotN, enetotP, dqm::impl::MonitorElement::Fill(), HcalZDCDetId::HAD, meZdcEneEmN1_, meZdcEneEmN2_, meZdcEneEmN3_, meZdcEneEmN4_, meZdcEneEmP1_, meZdcEneEmP2_, meZdcEneEmP3_, meZdcEneEmP4_, meZdcEneHadN1_, meZdcEneHadN2_, meZdcEneHadN3_, meZdcEneHadN4_, meZdcEneHadP1_, meZdcEneHadP2_, meZdcEneHadP3_, meZdcEneHadP4_, meZdcEneTEmN1_, meZdcEneTEmN2_, meZdcEneTEmN3_, meZdcEneTEmN4_, meZdcEneTEmP1_, meZdcEneTEmP2_, meZdcEneTEmP3_, meZdcEneTEmP4_, meZdcEneTHadN1_, meZdcEneTHadN2_, meZdcEneTHadN3_, meZdcEneTHadN4_, meZdcEneTHadP1_, meZdcEneTHadP2_, meZdcEneTHadP3_, meZdcEneTHadP4_, hgcalPlots::section, and protons_cff::time.

Referenced by analyzeHits().

Member Data Documentation

checkHit_

bool ZdcSimHitStudy::checkHit_

private

Definition at line 83 of file ZdcSimHitStudy.h.

Referenced by analyze(), bookHistograms(), and ZdcSimHitStudy().

enetot

double ZdcSimHitStudy::enetot

private

Definition at line 72 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and FillHitValHist().

enetotEmN

double ZdcSimHitStudy::enetotEmN

private

Definition at line 70 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and FillHitValHist().

enetotEmP

double ZdcSimHitStudy::enetotEmP

private

Definition at line 71 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and FillHitValHist().

enetotHadN

double ZdcSimHitStudy::enetotHadN

private

Definition at line 70 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and FillHitValHist().

enetotHadP

double ZdcSimHitStudy::enetotHadP

private

Definition at line 71 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and FillHitValHist().

enetotN

double ZdcSimHitStudy::enetotN

private

Definition at line 70 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and FillHitValHist().

enetotP

double ZdcSimHitStudy::enetotP

private

Definition at line 71 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and FillHitValHist().

g4Label

std::string ZdcSimHitStudy::g4Label

private

Definition at line 80 of file ZdcSimHitStudy.h.

Referenced by ZdcSimHitStudy().

genpart_GammaB

MonitorElement* ZdcSimHitStudy::genpart_GammaB

private

Definition at line 117 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_GammaB_counts

MonitorElement* ZdcSimHitStudy::genpart_GammaB_counts

private

Definition at line 127 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_GammaB_energydist

MonitorElement* ZdcSimHitStudy::genpart_GammaB_energydist

private

Definition at line 118 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_GammaF

MonitorElement* ZdcSimHitStudy::genpart_GammaF

private

Definition at line 115 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_GammaF_counts

MonitorElement* ZdcSimHitStudy::genpart_GammaF_counts

private

Definition at line 126 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_GammaF_energydist

MonitorElement* ZdcSimHitStudy::genpart_GammaF_energydist

private

Definition at line 116 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_NeutB

MonitorElement* ZdcSimHitStudy::genpart_NeutB

private

Definition at line 113 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_NeutB_counts

MonitorElement* ZdcSimHitStudy::genpart_NeutB_counts

private

Definition at line 125 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_NeutB_energydist

MonitorElement* ZdcSimHitStudy::genpart_NeutB_energydist

private

Definition at line 114 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_NeutF

MonitorElement* ZdcSimHitStudy::genpart_NeutF

private

Definition at line 111 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_NeutF_counts

MonitorElement* ZdcSimHitStudy::genpart_NeutF_counts

private

Definition at line 124 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_NeutF_energydist

MonitorElement* ZdcSimHitStudy::genpart_NeutF_energydist

private

Definition at line 112 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_Pi0B

MonitorElement* ZdcSimHitStudy::genpart_Pi0B

private

Definition at line 109 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_Pi0B_counts

MonitorElement* ZdcSimHitStudy::genpart_Pi0B_counts

private

Definition at line 123 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_Pi0B_energydist

MonitorElement* ZdcSimHitStudy::genpart_Pi0B_energydist

private

Definition at line 110 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_Pi0F

MonitorElement* ZdcSimHitStudy::genpart_Pi0F

private

Definition at line 107 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_Pi0F_counts

MonitorElement* ZdcSimHitStudy::genpart_Pi0F_counts

private

Definition at line 122 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

genpart_Pi0F_energydist

MonitorElement* ZdcSimHitStudy::genpart_Pi0F_energydist

private

Definition at line 108 of file ZdcSimHitStudy.h.

Referenced by analyze(), and bookHistograms().

meAllZdcNHit_

MonitorElement* ZdcSimHitStudy::meAllZdcNHit_

private

Definition at line 85 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meBadZdcDetHit_

MonitorElement * ZdcSimHitStudy::meBadZdcDetHit_

private

Definition at line 85 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meBadZdcIdHit_

MonitorElement * ZdcSimHitStudy::meBadZdcIdHit_

private

Definition at line 85 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meBadZdcSecHit_

MonitorElement * ZdcSimHitStudy::meBadZdcSecHit_

private

Definition at line 85 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdc10Ene_

MonitorElement * ZdcSimHitStudy::meZdc10Ene_

private

Definition at line 87 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdc10EneP_

MonitorElement* ZdcSimHitStudy::meZdc10EneP_

private

Definition at line 90 of file ZdcSimHitStudy.h.

meZdcChannelHit_

MonitorElement * ZdcSimHitStudy::meZdcChannelHit_

private

Definition at line 88 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcCorEEmNEHadN_

MonitorElement* ZdcSimHitStudy::meZdcCorEEmNEHadN_

private

Definition at line 96 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcCorEEmPEHadP_

MonitorElement* ZdcSimHitStudy::meZdcCorEEmPEHadP_

private

Definition at line 102 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcCorEtotNEtotP_

MonitorElement * ZdcSimHitStudy::meZdcCorEtotNEtotP_

private

Definition at line 102 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcDetectHit_

MonitorElement * ZdcSimHitStudy::meZdcDetectHit_

private

Definition at line 86 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEEMCh_

MonitorElement * ZdcSimHitStudy::meZdcEEMCh_

private

Definition at line 90 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEHadCh_

MonitorElement * ZdcSimHitStudy::meZdcEHadCh_

private

Definition at line 90 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEMEnergyHit_

MonitorElement * ZdcSimHitStudy::meZdcEMEnergyHit_

private

Definition at line 89 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEML10EneP_

MonitorElement * ZdcSimHitStudy::meZdcEML10EneP_

private

Definition at line 90 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEneEmN1_

MonitorElement* ZdcSimHitStudy::meZdcEneEmN1_

private

Definition at line 91 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneEmN2_

MonitorElement * ZdcSimHitStudy::meZdcEneEmN2_

private

Definition at line 91 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneEmN3_

MonitorElement * ZdcSimHitStudy::meZdcEneEmN3_

private

Definition at line 91 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneEmN4_

MonitorElement * ZdcSimHitStudy::meZdcEneEmN4_

private

Definition at line 91 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneEmN5_

MonitorElement * ZdcSimHitStudy::meZdcEneEmN5_

private

Definition at line 91 of file ZdcSimHitStudy.h.

Referenced by bookHistograms().

meZdcEneEmNTot_

MonitorElement * ZdcSimHitStudy::meZdcEneEmNTot_

private

Definition at line 95 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEneEmP1_

MonitorElement* ZdcSimHitStudy::meZdcEneEmP1_

private

Definition at line 97 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneEmP2_

MonitorElement * ZdcSimHitStudy::meZdcEneEmP2_

private

Definition at line 97 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneEmP3_

MonitorElement * ZdcSimHitStudy::meZdcEneEmP3_

private

Definition at line 97 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneEmP4_

MonitorElement * ZdcSimHitStudy::meZdcEneEmP4_

private

Definition at line 97 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneEmP5_

MonitorElement * ZdcSimHitStudy::meZdcEneEmP5_

private

Definition at line 97 of file ZdcSimHitStudy.h.

Referenced by bookHistograms().

meZdcEneEmPTot_

MonitorElement * ZdcSimHitStudy::meZdcEneEmPTot_

private

Definition at line 101 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEneHadN1_

MonitorElement* ZdcSimHitStudy::meZdcEneHadN1_

private

Definition at line 92 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneHadN2_

MonitorElement * ZdcSimHitStudy::meZdcEneHadN2_

private

Definition at line 92 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneHadN3_

MonitorElement * ZdcSimHitStudy::meZdcEneHadN3_

private

Definition at line 92 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneHadN4_

MonitorElement * ZdcSimHitStudy::meZdcEneHadN4_

private

Definition at line 92 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneHadNTot_

MonitorElement* ZdcSimHitStudy::meZdcEneHadNTot_

private

Definition at line 95 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEneHadP1_

MonitorElement* ZdcSimHitStudy::meZdcEneHadP1_

private

Definition at line 98 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneHadP2_

MonitorElement * ZdcSimHitStudy::meZdcEneHadP2_

private

Definition at line 98 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneHadP3_

MonitorElement * ZdcSimHitStudy::meZdcEneHadP3_

private

Definition at line 98 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneHadP4_

MonitorElement * ZdcSimHitStudy::meZdcEneHadP4_

private

Definition at line 98 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneHadPTot_

MonitorElement* ZdcSimHitStudy::meZdcEneHadPTot_

private

Definition at line 101 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEneNTot_

MonitorElement * ZdcSimHitStudy::meZdcEneNTot_

private

Definition at line 95 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEnePTot_

MonitorElement * ZdcSimHitStudy::meZdcEnePTot_

private

Definition at line 101 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEnergyHit_

MonitorElement * ZdcSimHitStudy::meZdcEnergyHit_

private

Definition at line 88 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcEneTEmN1_

MonitorElement* ZdcSimHitStudy::meZdcEneTEmN1_

private

Definition at line 93 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTEmN2_

MonitorElement * ZdcSimHitStudy::meZdcEneTEmN2_

private

Definition at line 93 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTEmN3_

MonitorElement * ZdcSimHitStudy::meZdcEneTEmN3_

private

Definition at line 93 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTEmN4_

MonitorElement * ZdcSimHitStudy::meZdcEneTEmN4_

private

Definition at line 93 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTEmN5_

MonitorElement * ZdcSimHitStudy::meZdcEneTEmN5_

private

Definition at line 93 of file ZdcSimHitStudy.h.

Referenced by bookHistograms().

meZdcEneTEmP1_

MonitorElement* ZdcSimHitStudy::meZdcEneTEmP1_

private

Definition at line 99 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTEmP2_

MonitorElement * ZdcSimHitStudy::meZdcEneTEmP2_

private

Definition at line 99 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTEmP3_

MonitorElement * ZdcSimHitStudy::meZdcEneTEmP3_

private

Definition at line 99 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTEmP4_

MonitorElement * ZdcSimHitStudy::meZdcEneTEmP4_

private

Definition at line 99 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTEmP5_

MonitorElement * ZdcSimHitStudy::meZdcEneTEmP5_

private

Definition at line 99 of file ZdcSimHitStudy.h.

Referenced by bookHistograms().

meZdcEneTHadN1_

MonitorElement* ZdcSimHitStudy::meZdcEneTHadN1_

private

Definition at line 94 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTHadN2_

MonitorElement * ZdcSimHitStudy::meZdcEneTHadN2_

private

Definition at line 94 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTHadN3_

MonitorElement * ZdcSimHitStudy::meZdcEneTHadN3_

private

Definition at line 94 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTHadN4_

MonitorElement * ZdcSimHitStudy::meZdcEneTHadN4_

private

Definition at line 94 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTHadP1_

MonitorElement* ZdcSimHitStudy::meZdcEneTHadP1_

private

Definition at line 100 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTHadP2_

MonitorElement * ZdcSimHitStudy::meZdcEneTHadP2_

private

Definition at line 100 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTHadP3_

MonitorElement * ZdcSimHitStudy::meZdcEneTHadP3_

private

Definition at line 100 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTHadP4_

MonitorElement * ZdcSimHitStudy::meZdcEneTHadP4_

private

Definition at line 100 of file ZdcSimHitStudy.h.

Referenced by bookHistograms(), and FillHitValHist().

meZdcEneTot_

MonitorElement * ZdcSimHitStudy::meZdcEneTot_

private

Definition at line 102 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcETime_

MonitorElement * ZdcSimHitStudy::meZdcETime_

private

Definition at line 86 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcHadEnergyHit_

MonitorElement* ZdcSimHitStudy::meZdcHadEnergyHit_

private

Definition at line 89 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcHadL10EneP_

MonitorElement * ZdcSimHitStudy::meZdcHadL10EneP_

private

Definition at line 89 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcNHit_

MonitorElement* ZdcSimHitStudy::meZdcNHit_

private

Definition at line 86 of file ZdcSimHitStudy.h.

meZdcNHitEM_

MonitorElement* ZdcSimHitStudy::meZdcNHitEM_

private

Definition at line 87 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcNHitHad_

MonitorElement * ZdcSimHitStudy::meZdcNHitHad_

private

Definition at line 87 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcNHitLum_

MonitorElement * ZdcSimHitStudy::meZdcNHitLum_

private

Definition at line 87 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcSectionHit_

MonitorElement* ZdcSimHitStudy::meZdcSectionHit_

private

Definition at line 88 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcSideHit_

MonitorElement * ZdcSimHitStudy::meZdcSideHit_

private

Definition at line 86 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcTimeHit_

MonitorElement * ZdcSimHitStudy::meZdcTimeHit_

private

Definition at line 89 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

meZdcTimeWHit_

MonitorElement * ZdcSimHitStudy::meZdcTimeWHit_

private

Definition at line 88 of file ZdcSimHitStudy.h.

Referenced by analyzeHits(), and bookHistograms().

outFile_

std::string ZdcSimHitStudy::outFile_

private

Definition at line 80 of file ZdcSimHitStudy.h.

Referenced by ZdcSimHitStudy().

tok_gen_

edm::EDGetTokenT<reco::GenParticleCollection> ZdcSimHitStudy::tok_gen_

private

Definition at line 81 of file ZdcSimHitStudy.h.

Referenced by analyze(), and ZdcSimHitStudy().

tok_hits_

edm::EDGetTokenT<edm::PCaloHitContainer> ZdcSimHitStudy::tok_hits_

private

Definition at line 82 of file ZdcSimHitStudy.h.

Referenced by analyze(), and ZdcSimHitStudy().

verbose_

bool ZdcSimHitStudy::verbose_

private

Definition at line 83 of file ZdcSimHitStudy.h.

Referenced by ZdcSimHitStudy().

zdcHits

std::string ZdcSimHitStudy::zdcHits

private

Definition at line 80 of file ZdcSimHitStudy.h.

Referenced by ZdcSimHitStudy().