EtlSimHitsValidation Class Reference

#include <Validation/MtdValidation/plugins/EtlSimHitsValidation.cc>

Inheritance diagram for EtlSimHitsValidation:

Public Member Functions
	EtlSimHitsValidation (const edm::ParameterSet &)
	~EtlSimHitsValidation () 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
bool	hasAbilityToProduceInBeginLumis () const final
bool	hasAbilityToProduceInBeginProcessBlocks () const final
bool	hasAbilityToProduceInBeginRuns () const final
bool	hasAbilityToProduceInEndLumis () const final
bool	hasAbilityToProduceInEndProcessBlocks () const final
bool	hasAbilityToProduceInEndRuns () const final

Static Public Member Functions
static void	fillDescriptions (edm::ConfigurationDescriptions &descriptions)
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 &)

Private Member Functions
void	analyze (const edm::Event &, const edm::EventSetup &) override
void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override

Private Attributes
edm::EDGetTokenT< CrossingFrame< PSimHit > >	etlSimHitsToken_
const std::string	folder_
const float	hitMinEnergy1Dis_
const float	hitMinEnergy2Dis_
MonitorElement *	meHitEnergy_ [4]
MonitorElement *	meHitEta_ [4]
MonitorElement *	meHitEvsEta_ [4]
MonitorElement *	meHitEvsPhi_ [4]
MonitorElement *	meHitPhi_ [4]
MonitorElement *	meHitTime_ [4]
MonitorElement *	meHitTvsE_ [4]
MonitorElement *	meHitTvsEta_ [4]
MonitorElement *	meHitTvsPhi_ [4]
MonitorElement *	meHitX_ [4]
MonitorElement *	meHitXlocal_ [4]
MonitorElement *	meHitY_ [4]
MonitorElement *	meHitYlocal_ [4]
MonitorElement *	meHitZ_ [4]
MonitorElement *	meHitZlocal_ [4]
MonitorElement *	meNhits_ [4]
MonitorElement *	meNtrkPerCell_ [4]
MonitorElement *	meOccupancy_ [4]
edm::ESGetToken< MTDGeometry, MTDDigiGeometryRecord >	mtdgeoToken_
edm::ESGetToken< MTDTopology, MTDTopologyRcd >	mtdtopoToken_

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 >
typedef CacheContexts< T... >	CacheTypes
typedef CacheTypes::GlobalCache	GlobalCache
typedef AbilityChecker< T... >	HasAbility
typedef CacheTypes::LuminosityBlockCache	LuminosityBlockCache
typedef LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >	LuminosityBlockContext
typedef CacheTypes::LuminosityBlockSummaryCache	LuminosityBlockSummaryCache
typedef CacheTypes::RunCache	RunCache
typedef RunContextT< RunCache, GlobalCache >	RunContext
typedef CacheTypes::RunSummaryCache	RunSummaryCache
Protected Member Functions inherited from DQMEDAnalyzer
uint64_t	meId () const
Protected Attributes inherited from DQMEDAnalyzer
edm::EDPutTokenT< DQMToken >	lumiToken_
edm::EDPutTokenT< DQMToken >	runToken_
unsigned int	streamId_

Detailed Description

Description: ETL SIM hits validation

Implementation: [Notes on implementation]

Definition at line 45 of file EtlSimHitsValidation.cc.

Constructor & Destructor Documentation

EtlSimHitsValidation()

EtlSimHitsValidation::EtlSimHitsValidation ( const edm::ParameterSet &  iConfig )

explicit

Definition at line 96 of file EtlSimHitsValidation.cc.

    : folder_(iConfig.getParameter<std::string>("folder")),
      hitMinEnergy1Dis_(iConfig.getParameter<double>("hitMinimumEnergy1Dis")),
      hitMinEnergy2Dis_(iConfig.getParameter<double>("hitMinimumEnergy2Dis")) {
  etlSimHitsToken_ = consumes<CrossingFrame<PSimHit> >(iConfig.getParameter<edm::InputTag>("inputTag"));
  mtdgeoToken_ = esConsumes<MTDGeometry, MTDDigiGeometryRecord>();
  mtdtopoToken_ = esConsumes<MTDTopology, MTDTopologyRcd>();
}

References etlSimHitsToken_, edm::ParameterSet::getParameter(), mtdgeoToken_, and mtdtopoToken_.

~EtlSimHitsValidation()

EtlSimHitsValidation::~EtlSimHitsValidation ( )

override

Definition at line 105 of file EtlSimHitsValidation.cc.

{}

Member Function Documentation

analyze()

void EtlSimHitsValidation::analyze ( const edm::Event &  iEvent, const edm::EventSetup &  iSetup  )

overrideprivatevirtual

Reimplemented from DQMEDAnalyzer.

Definition at line 108 of file EtlSimHitsValidation.cc.

                                                                                      {
  using namespace edm;
  using namespace geant_units::operators;
 
  auto geometryHandle = iSetup.getTransientHandle(mtdgeoToken_);
  const MTDGeometry* geom = geometryHandle.product();
 
  auto topologyHandle = iSetup.getTransientHandle(mtdtopoToken_);
  const MTDTopology* topology = topologyHandle.product();
 
  bool topo1Dis = false;
  bool topo2Dis = false;
  if (topology->getMTDTopologyMode() <= static_cast<int>(MTDTopologyMode::Mode::barphiflat)) {
    topo1Dis = true;
  }
  if (topology->getMTDTopologyMode() > static_cast<int>(MTDTopologyMode::Mode::barphiflat)) {
    topo2Dis = true;
  }
 
  auto etlSimHitsHandle = makeValid(iEvent.getHandle(etlSimHitsToken_));
  MixCollection<PSimHit> etlSimHits(etlSimHitsHandle.product());
 
  std::unordered_map<uint32_t, MTDHit> m_etlHits[4];
  std::unordered_map<uint32_t, std::set<int> > m_etlTrkPerCell[4];
 
  // --- Loop over the ETL SIM hits
 
  int idet = 999;
 
  for (auto const& simHit : etlSimHits) {
    // --- Use only hits compatible with the in-time bunch-crossing
    if (simHit.tof() < 0 || simHit.tof() > 25.)
      continue;
 
    ETLDetId id = simHit.detUnitId();
    if (topo1Dis) {
      if (id.zside() == -1) {
        idet = 0;
      } else if (id.zside() == 1) {
        idet = 2;
      } else {
        continue;
      }
    }
 
    if (topo2Dis) {
      if ((id.zside() == -1) && (id.nDisc() == 1)) {
        idet = 0;
      } else if ((id.zside() == -1) && (id.nDisc() == 2)) {
        idet = 1;
      } else if ((id.zside() == 1) && (id.nDisc() == 1)) {
        idet = 2;
      } else if ((id.zside() == 1) && (id.nDisc() == 2)) {
        idet = 3;
      } else {
        continue;
      }
    }
 
    m_etlTrkPerCell[idet][id.rawId()].insert(simHit.trackId());
 
    auto simHitIt = m_etlHits[idet].emplace(id.rawId(), MTDHit()).first;
 
    // --- Accumulate the energy (in MeV) of SIM hits in the same detector cell
    (simHitIt->second).energy += convertUnitsTo(0.001_MeV, simHit.energyLoss());
 
    // --- Get the time of the first SIM hit in the cell
    if ((simHitIt->second).time == 0 || simHit.tof() < (simHitIt->second).time) {
      (simHitIt->second).time = simHit.tof();
 
      auto hit_pos = simHit.entryPoint();
      (simHitIt->second).x = hit_pos.x();
      (simHitIt->second).y = hit_pos.y();
      (simHitIt->second).z = hit_pos.z();
    }
 
  }  // simHit loop
 
  // ==============================================================================
  //  Histogram filling
  // ==============================================================================
 
  for (int idet = 0; idet < 4; ++idet) {  //two disks per side
    if (((idet == 1) || (idet == 3)) && (topo1Dis == true))
      continue;
    meNhits_[idet]->Fill(m_etlHits[idet].size());
 
    for (auto const& hit : m_etlTrkPerCell[idet]) {
      meNtrkPerCell_[idet]->Fill((hit.second).size());
    }
 
    for (auto const& hit : m_etlHits[idet]) {
      double weight = 1.0;
      if (topo1Dis) {
        if ((hit.second).energy < hitMinEnergy1Dis_)
          continue;
      }
      if (topo2Dis) {
        if ((hit.second).energy < hitMinEnergy2Dis_)
          continue;
      }
      // --- Get the SIM hit global position
      ETLDetId detId(hit.first);
      DetId geoId = detId.geographicalId();
      const MTDGeomDet* thedet = geom->idToDet(geoId);
      if (thedet == nullptr)
        throw cms::Exception("EtlSimHitsValidation") << "GeographicalID: " << std::hex << geoId.rawId() << " ("
                                                     << detId.rawId() << ") is invalid!" << std::dec << std::endl;
 
      Local3DPoint local_point(
          convertMmToCm((hit.second).x), convertMmToCm((hit.second).y), convertMmToCm((hit.second).z));
      const auto& global_point = thedet->toGlobal(local_point);
 
      if (topo2Dis && (detId.discSide() == 1)) {
        weight = -weight;
      }
 
      // --- Fill the histograms
 
      meHitEnergy_[idet]->Fill((hit.second).energy);
      meHitTime_[idet]->Fill((hit.second).time);
      meHitXlocal_[idet]->Fill((hit.second).x);
      meHitYlocal_[idet]->Fill((hit.second).y);
      meHitZlocal_[idet]->Fill((hit.second).z);
      meOccupancy_[idet]->Fill(global_point.x(), global_point.y(), weight);
      meHitX_[idet]->Fill(global_point.x());
      meHitY_[idet]->Fill(global_point.y());
      meHitZ_[idet]->Fill(global_point.z());
      meHitPhi_[idet]->Fill(global_point.phi());
      meHitEta_[idet]->Fill(global_point.eta());
      meHitTvsE_[idet]->Fill((hit.second).energy, (hit.second).time);
      meHitEvsPhi_[idet]->Fill(global_point.phi(), (hit.second).energy);
      meHitEvsEta_[idet]->Fill(global_point.eta(), (hit.second).energy);
      meHitTvsPhi_[idet]->Fill(global_point.phi(), (hit.second).time);
      meHitTvsEta_[idet]->Fill(global_point.eta(), (hit.second).time);
 
    }  // hit loop
 
  }  // idet loop
}

References MTDTopologyMode::barphiflat, geant_units::operators::convertMmToCm(), geant_units::operators::convertUnitsTo(), TauDecayModes::dec, ETLDetId::discSide(), HCALHighEnergyHPDFilter_cfi::energy, etlSimHitsToken_, Exception, dqm::impl::MonitorElement::Fill(), ETLDetId::geographicalId(), relativeConstraints::geom, MTDTopology::getMTDTopologyMode(), edm::EventSetup::getTransientHandle(), hitMinEnergy1Dis_, hitMinEnergy2Dis_, iEvent, edm::makeValid(), meHitEnergy_, meHitEta_, meHitEvsEta_, meHitEvsPhi_, meHitPhi_, meHitTime_, meHitTvsE_, meHitTvsEta_, meHitTvsPhi_, meHitX_, meHitXlocal_, meHitY_, meHitYlocal_, meHitZ_, meHitZlocal_, meNhits_, meNtrkPerCell_, meOccupancy_, mtdgeoToken_, mtdtopoToken_, DetId::rawId(), rpcPointValidation_cfi::simHit, findQualityFiles::size, protons_cff::time, GeomDet::toGlobal(), mps_merge::weight, x, y, z, and ecaldqm::zside().

bookHistograms()

void EtlSimHitsValidation::bookHistograms ( DQMStore::IBooker &  ibook, edm::Run const &  run, edm::EventSetup const &  iSetup  )

overrideprivatevirtual

Implements DQMEDAnalyzer.

Definition at line 250 of file EtlSimHitsValidation.cc.

                                                                       {
  ibook.setCurrentFolder(folder_);
 
  // --- histograms booking
 
  meNhits_[0] = ibook.book1D("EtlNhitsZnegD1",
                             "Number of ETL cells with SIM hits (-Z, Single(topo1D)/First(topo2D) disk);N_{ETL cells}",
                             100,
                             0.,
                             5000.);
  meNhits_[1] = ibook.book1D(
      "EtlNhitsZnegD2", "Number of ETL cells with SIM hits (-Z, Second disk);N_{ETL cells}", 100, 0., 5000.);
  meNhits_[2] = ibook.book1D("EtlNhitsZposD1",
                             "Number of ETL cells with SIM hits (+Z, Single(topo1D)/First(topo2D) disk);N_{ETL cells}",
                             100,
                             0.,
                             5000.);
  meNhits_[3] = ibook.book1D(
      "EtlNhitsZposD2", "Number of ETL cells with SIM hits (+Z, Second Disk);N_{ETL cells}", 100, 0., 5000.);
  meNtrkPerCell_[0] = ibook.book1D("EtlNtrkPerCellZnegD1",
                                   "Number of tracks per ETL sensor (-Z, Single(topo1D)/First(topo2D) disk);N_{trk}",
                                   10,
                                   0.,
                                   10.);
  meNtrkPerCell_[1] =
      ibook.book1D("EtlNtrkPerCellZnegD2", "Number of tracks per ETL sensor (-Z, Second disk);N_{trk}", 10, 0., 10.);
  meNtrkPerCell_[2] = ibook.book1D("EtlNtrkPerCellZposD1",
                                   "Number of tracks per ETL sensor (+Z, Single(topo1D)/First(topo2D) disk);N_{trk}",
                                   10,
                                   0.,
                                   10.);
  meNtrkPerCell_[3] =
      ibook.book1D("EtlNtrkPerCellZposD2", "Number of tracks per ETL sensor (+Z, Second disk);N_{trk}", 10, 0., 10.);
  meHitEnergy_[0] = ibook.book1D(
      "EtlHitEnergyZnegD1", "ETL SIM hits energy (-Z, Single(topo1D)/First(topo2D) disk);E_{SIM} [MeV]", 100, 0., 3.);
  meHitEnergy_[1] =
      ibook.book1D("EtlHitEnergyZnegD2", "ETL SIM hits energy (-Z, Second disk);E_{SIM} [MeV]", 100, 0., 3.);
  meHitEnergy_[2] = ibook.book1D(
      "EtlHitEnergyZposD1", "ETL SIM hits energy (+Z, Single(topo1D)/First(topo2D) disk);E_{SIM} [MeV]", 100, 0., 3.);
  meHitEnergy_[3] =
      ibook.book1D("EtlHitEnergyZposD2", "ETL SIM hits energy (+Z, Second disk);E_{SIM} [MeV]", 100, 0., 3.);
  meHitTime_[0] = ibook.book1D(
      "EtlHitTimeZnegD1", "ETL SIM hits ToA (-Z, Single(topo1D)/First(topo2D) disk);ToA_{SIM} [ns]", 100, 0., 25.);
  meHitTime_[1] = ibook.book1D("EtlHitTimeZnegD2", "ETL SIM hits ToA (-Z, Second disk);ToA_{SIM} [ns]", 100, 0., 25.);
  meHitTime_[2] = ibook.book1D(
      "EtlHitTimeZposD1", "ETL SIM hits ToA (+Z, Single(topo1D)/First(topo2D) disk);ToA_{SIM} [ns]", 100, 0., 25.);
  meHitTime_[3] = ibook.book1D("EtlHitTimeZposD2", "ETL SIM hits ToA (+Z, Second disk);ToA_{SIM} [ns]", 100, 0., 25.);
 
  meHitXlocal_[0] = ibook.book1D("EtlHitXlocalZnegD1",
                                 "ETL SIM local X (-Z, Single(topo1D)/First(topo2D) disk);X_{SIM}^{LOC} [mm]",
                                 100,
                                 -25.,
                                 25.);
  meHitXlocal_[1] =
      ibook.book1D("EtlHitXlocalZnegD2", "ETL SIM local X (-Z, Second disk);X_{SIM}^{LOC} [mm]", 100, -25., 25.);
  meHitXlocal_[2] = ibook.book1D("EtlHitXlocalZposD1",
                                 "ETL SIM local X (+Z, Single(topo1D)/First(topo2D) disk);X_{SIM}^{LOC} [mm]",
                                 100,
                                 -25.,
                                 25.);
  meHitXlocal_[3] =
      ibook.book1D("EtlHitXlocalZposD2", "ETL SIM local X (+Z, Second disk);X_{SIM}^{LOC} [mm]", 100, -25., 25.);
 
  meHitYlocal_[0] = ibook.book1D("EtlHitYlocalZnegD1",
                                 "ETL SIM local Y (-Z, Single(topo1D)/First(topo2D) disk);Y_{SIM}^{LOC} [mm]",
                                 100,
                                 -48.,
                                 48.);
  meHitYlocal_[1] =
      ibook.book1D("EtlHitYlocalZnegD2", "ETL SIM local Y (-Z, Second Disk);Y_{SIM}^{LOC} [mm]", 100, -48., 48.);
  meHitYlocal_[2] = ibook.book1D("EtlHitYlocalZposD1",
                                 "ETL SIM local Y (+Z, Single(topo1D)/First(topo2D) disk);Y_{SIM}^{LOC} [mm]",
                                 100,
                                 -48.,
                                 48.);
  meHitYlocal_[3] =
      ibook.book1D("EtlHitYlocalZposD2", "ETL SIM local Y (+Z, Second disk);Y_{SIM}^{LOC} [mm]", 100, -48., 48.);
  meHitZlocal_[0] = ibook.book1D("EtlHitZlocalZnegD1",
                                 "ETL SIM local Z (-Z, Single(topo1D)/First(topo2D) disk);Z_{SIM}^{LOC} [mm]",
                                 80,
                                 -0.16,
                                 0.16);
  meHitZlocal_[1] =
      ibook.book1D("EtlHitZlocalZnegD2", "ETL SIM local Z (-Z, Second disk);Z_{SIM}^{LOC} [mm]", 80, -0.16, 0.16);
  meHitZlocal_[2] = ibook.book1D("EtlHitZlocalZposD1",
                                 "ETL SIM local Z (+Z, Single(topo1D)/First(topo2D) disk);Z_{SIM}^{LOC} [mm]",
                                 80,
                                 -0.16,
                                 0.16);
  meHitZlocal_[3] =
      ibook.book1D("EtlHitZlocalZposD2", "ETL SIM local Z (+Z, Second disk);Z_{SIM}^{LOC} [mm]", 80, -0.16, 0.16);
 
  meOccupancy_[0] =
      ibook.book2D("EtlOccupancyZnegD1",
                   "ETL SIM hits occupancy (-Z, Single(topo1D)/First(topo2D) disk);X_{SIM} [cm];Y_{SIM} [cm]",
                   135,
                   -135.,
                   135.,
                   135,
                   -135.,
                   135.);
  meOccupancy_[1] = ibook.book2D("EtlOccupancyZnegD2",
                                 "ETL SIM hits occupancy (-Z, Second disk);X_{SIM} [cm];Y_{SIM} [cm]",
                                 135,
                                 -135.,
                                 135.,
                                 135,
                                 -135.,
                                 135.);
  meOccupancy_[2] =
      ibook.book2D("EtlOccupancyZposD1",
                   "ETL SIM hits occupancy (+Z, Single(topo1D)/First(topo2D) disk);X_{SIM} [cm];Y_{SIM} [cm]",
                   135,
                   -135.,
                   135.,
                   135,
                   -135.,
                   135.);
  meOccupancy_[3] = ibook.book2D("EtlOccupancyZposD2",
                                 "ETL SIM hits occupancy (+Z, Second disk);X_{SIM} [cm];Y_{SIM} [cm]",
                                 135,
                                 -135.,
                                 135.,
                                 135,
                                 -135.,
                                 135.);
 
  meHitX_[0] = ibook.book1D(
      "EtlHitXZnegD1", "ETL SIM hits X (+Z, Single(topo1D)/First(topo2D) disk);X_{SIM} [cm]", 100, -130., 130.);
  meHitX_[1] = ibook.book1D("EtlHitXZnegD2", "ETL SIM hits X (-Z, Second disk);X_{SIM} [cm]", 100, -130., 130.);
  meHitX_[2] = ibook.book1D(
      "EtlHitXZposD1", "ETL SIM hits X (+Z, Single(topo1D)/First(topo2D) disk);X_{SIM} [cm]", 100, -130., 130.);
  meHitX_[3] = ibook.book1D("EtlHitXZposD2", "ETL SIM hits X (+Z, Second disk);X_{SIM} [cm]", 100, -130., 130.);
  meHitY_[0] = ibook.book1D(
      "EtlHitYZnegD1", "ETL SIM hits Y (-Z, Single(topo1D)/First(topo2D) disk);Y_{SIM} [cm]", 100, -130., 130.);
  meHitY_[1] = ibook.book1D("EtlHitYZnegD2", "ETL SIM hits Y (-Z, Second disk);Y_{SIM} [cm]", 100, -130., 130.);
  meHitY_[2] = ibook.book1D(
      "EtlHitYZposD1", "ETL SIM hits Y (+Z, Single(topo1D)/First(topo2D) disk);Y_{SIM} [cm]", 100, -130., 130.);
  meHitY_[3] = ibook.book1D("EtlHitYZposD2", "ETL SIM hits Y (+Z, Second disk);Y_{SIM} [cm]", 100, -130., 130.);
  meHitZ_[0] = ibook.book1D(
      "EtlHitZZnegD1", "ETL SIM hits Z (-Z, Single(topo1D)/First(topo2D) disk);Z_{SIM} [cm]", 100, -302., -298.);
  meHitZ_[1] = ibook.book1D("EtlHitZZnegD2", "ETL SIM hits Z (-Z, Second disk);Z_{SIM} [cm]", 100, -304., -300.);
  meHitZ_[2] = ibook.book1D(
      "EtlHitZZposD1", "ETL SIM hits Z (+Z, Single(topo1D)/First(topo2D) disk);Z_{SIM} [cm]", 100, 298., 302.);
  meHitZ_[3] = ibook.book1D("EtlHitZZposD2", "ETL SIM hits Z (+Z, Second disk);Z_{SIM} [cm]", 100, 300., 304.);
 
  meHitPhi_[0] = ibook.book1D(
      "EtlHitPhiZnegD1", "ETL SIM hits #phi (-Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad]", 100, -3.15, 3.15);
  meHitPhi_[1] =
      ibook.book1D("EtlHitPhiZnegD2", "ETL SIM hits #phi (-Z, Second disk);#phi_{SIM} [rad]", 100, -3.15, 3.15);
  meHitPhi_[2] = ibook.book1D(
      "EtlHitPhiZposD1", "ETL SIM hits #phi (+Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad]", 100, -3.15, 3.15);
  meHitPhi_[3] =
      ibook.book1D("EtlHitPhiZposD2", "ETL SIM hits #phi (+Z, Second disk);#phi_{SIM} [rad]", 100, -3.15, 3.15);
  meHitEta_[0] = ibook.book1D(
      "EtlHitEtaZnegD1", "ETL SIM hits #eta (-Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM}", 100, -3.2, -1.56);
  meHitEta_[1] = ibook.book1D("EtlHitEtaZnegD2", "ETL SIM hits #eta (-Z, Second disk);#eta_{SIM}", 100, -3.2, -1.56);
  meHitEta_[2] = ibook.book1D(
      "EtlHitEtaZposD1", "ETL SIM hits #eta (+Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM}", 100, 1.56, 3.2);
  meHitEta_[3] = ibook.book1D("EtlHitEtaZposD2", "ETL SIM hits #eta (+Z, Second disk);#eta_{SIM}", 100, 1.56, 3.2);
 
  meHitTvsE_[0] =
      ibook.bookProfile("EtlHitTvsEZnegD1",
                        "ETL SIM time vs energy (-Z, Single(topo1D)/First(topo2D) disk);E_{SIM} [MeV];T_{SIM} [ns]",
                        50,
                        0.,
                        2.,
                        0.,
                        100.);
  meHitTvsE_[1] = ibook.bookProfile(
      "EtlHitTvsEZnegD2", "ETL SIM time vs energy (-Z, Second disk);E_{SIM} [MeV];T_{SIM} [ns]", 50, 0., 2., 0., 100.);
  meHitTvsE_[2] =
      ibook.bookProfile("EtlHitTvsEZposD1",
                        "ETL SIM time vs energy (+Z, Single(topo1D)/First(topo2D) disk);E_{SIM} [MeV];T_{SIM} [ns]",
                        50,
                        0.,
                        2.,
                        0.,
                        100.);
  meHitTvsE_[3] = ibook.bookProfile(
      "EtlHitTvsEZposD2", "ETL SIM time vs energy (+Z, Second disk);E_{SIM} [MeV];T_{SIM} [ns]", 50, 0., 2., 0., 100.);
  meHitEvsPhi_[0] =
      ibook.bookProfile("EtlHitEvsPhiZnegD1",
                        "ETL SIM energy vs #phi (-Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad];E_{SIM} [MeV]",
                        50,
                        -3.15,
                        3.15,
                        0.,
                        100.);
  meHitEvsPhi_[1] = ibook.bookProfile("EtlHitEvsPhiZnegD2",
                                      "ETL SIM energy vs #phi (-Z, Second disk);#phi_{SIM} [rad];E_{SIM} [MeV]",
                                      50,
                                      -3.15,
                                      3.15,
                                      0.,
                                      100.);
  meHitEvsPhi_[2] =
      ibook.bookProfile("EtlHitEvsPhiZposD1",
                        "ETL SIM energy vs #phi (+Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad];E_{SIM} [MeV]",
                        50,
                        -3.15,
                        3.15,
                        0.,
                        100.);
  meHitEvsPhi_[3] = ibook.bookProfile("EtlHitEvsPhiZposD2",
                                      "ETL SIM energy vs #phi (+Z, Second disk);#phi_{SIM} [rad];E_{SIM} [MeV]",
                                      50,
                                      -3.15,
                                      3.15,
                                      0.,
                                      100.);
  meHitEvsEta_[0] =
      ibook.bookProfile("EtlHitEvsEtaZnegD1",
                        "ETL SIM energy vs #eta (-Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM};E_{SIM} [MeV]",
                        50,
                        -3.2,
                        -1.56,
                        0.,
                        100.);
  meHitEvsEta_[1] = ibook.bookProfile("EtlHitEvsEtaZnegD2",
                                      "ETL SIM energy vs #eta (-Z, Second disk);#eta_{SIM};E_{SIM} [MeV]",
                                      50,
                                      -3.2,
                                      -1.56,
                                      0.,
                                      100.);
  meHitEvsEta_[2] =
      ibook.bookProfile("EtlHitEvsEtaZposD1",
                        "ETL SIM energy vs #eta (+Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM};E_{SIM} [MeV]",
                        50,
                        1.56,
                        3.2,
                        0.,
                        100.);
  meHitEvsEta_[3] = ibook.bookProfile("EtlHitEvsEtaZposD2",
                                      "ETL SIM energy vs #eta (+Z, Second disk);#eta_{SIM};E_{SIM} [MeV]",
                                      50,
                                      1.56,
                                      3.2,
                                      0.,
                                      100.);
  meHitTvsPhi_[0] =
      ibook.bookProfile("EtlHitTvsPhiZnegD1",
                        "ETL SIM time vs #phi (-Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad];T_{SIM} [ns]",
                        50,
                        -3.15,
                        3.15,
                        0.,
                        100.);
  meHitTvsPhi_[1] = ibook.bookProfile("EtlHitTvsPhiZnegD2",
                                      "ETL SIM time vs #phi (-Z, Second disk);#phi_{SIM} [rad];T_{SIM} [ns]",
                                      50,
                                      -3.15,
                                      3.15,
                                      0.,
                                      100.);
  meHitTvsPhi_[2] =
      ibook.bookProfile("EtlHitTvsPhiZposD1",
                        "ETL SIM time vs #phi (+Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad];T_{SIM} [ns]",
                        50,
                        -3.15,
                        3.15,
                        0.,
                        100.);
  meHitTvsPhi_[3] = ibook.bookProfile("EtlHitTvsPhiZposD2",
                                      "ETL SIM time vs #phi (+Z, Second disk);#phi_{SIM} [rad];T_{SIM} [ns]",
                                      50,
                                      -3.15,
                                      3.15,
                                      0.,
                                      100.);
  meHitTvsEta_[0] =
      ibook.bookProfile("EtlHitTvsEtaZnegD1",
                        "ETL SIM time vs #eta (-Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM};T_{SIM} [ns]",
                        50,
                        -3.2,
                        -1.56,
                        0.,
                        100.);
  meHitTvsEta_[1] = ibook.bookProfile(
      "EtlHitTvsEtaZnegD2", "ETL SIM time vs #eta (-Z, Second disk);#eta_{SIM};T_{SIM} [ns]", 50, -3.2, -1.56, 0., 100.);
  meHitTvsEta_[2] =
      ibook.bookProfile("EtlHitTvsEtaZposD1",
                        "ETL SIM time vs #eta (+Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM};T_{SIM} [ns]",
                        50,
                        1.56,
                        3.2,
                        0.,
                        100.);
  meHitTvsEta_[3] = ibook.bookProfile(
      "EtlHitTvsEtaZposD2", "ETL SIM time vs #eta (+Z, Second disk);#eta_{SIM};T_{SIM} [ns]", 50, 1.56, 3.2, 0., 100.);
}

References dqm::implementation::IBooker::book1D(), dqm::implementation::IBooker::book2D(), dqm::implementation::IBooker::bookProfile(), folder_, meHitEnergy_, meHitEta_, meHitEvsEta_, meHitEvsPhi_, meHitPhi_, meHitTime_, meHitTvsE_, meHitTvsEta_, meHitTvsPhi_, meHitX_, meHitXlocal_, meHitY_, meHitYlocal_, meHitZ_, meHitZlocal_, meNhits_, meNtrkPerCell_, meOccupancy_, and dqm::implementation::NavigatorBase::setCurrentFolder().

fillDescriptions()

void EtlSimHitsValidation::fillDescriptions ( edm::ConfigurationDescriptions &  descriptions )

static

Definition at line 546 of file EtlSimHitsValidation.cc.

                                                                                      {
  edm::ParameterSetDescription desc;
 
  desc.add<std::string>("folder", "MTD/ETL/SimHits");
  desc.add<edm::InputTag>("inputTag", edm::InputTag("mix", "g4SimHitsFastTimerHitsEndcap"));
  desc.add<double>("hitMinimumEnergy1Dis", 0.1);    // [MeV]
  desc.add<double>("hitMinimumEnergy2Dis", 0.001);  // [MeV]
 
  descriptions.add("etlSimHits", desc);
}

References edm::ConfigurationDescriptions::add(), submitPVResolutionJobs::desc, HLT_FULL_cff::InputTag, and AlCaHLTBitMon_QueryRunRegistry::string.

Member Data Documentation

etlSimHitsToken_

edm::EDGetTokenT<CrossingFrame<PSimHit> > EtlSimHitsValidation::etlSimHitsToken_

private

Definition at line 63 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and EtlSimHitsValidation().

folder_

const std::string EtlSimHitsValidation::folder_

private

Definition at line 59 of file EtlSimHitsValidation.cc.

Referenced by bookHistograms().

hitMinEnergy1Dis_

const float EtlSimHitsValidation::hitMinEnergy1Dis_

private

Definition at line 60 of file EtlSimHitsValidation.cc.

Referenced by analyze().

hitMinEnergy2Dis_

const float EtlSimHitsValidation::hitMinEnergy2Dis_

private

Definition at line 61 of file EtlSimHitsValidation.cc.

Referenced by analyze().

meHitEnergy_

MonitorElement* EtlSimHitsValidation::meHitEnergy_[4]

private

Definition at line 73 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitEta_

MonitorElement* EtlSimHitsValidation::meHitEta_[4]

private

Definition at line 86 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitEvsEta_

MonitorElement* EtlSimHitsValidation::meHitEvsEta_[4]

private

Definition at line 90 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitEvsPhi_

MonitorElement* EtlSimHitsValidation::meHitEvsPhi_[4]

private

Definition at line 89 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitPhi_

MonitorElement* EtlSimHitsValidation::meHitPhi_[4]

private

Definition at line 85 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitTime_

MonitorElement* EtlSimHitsValidation::meHitTime_[4]

private

Definition at line 74 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitTvsE_

MonitorElement* EtlSimHitsValidation::meHitTvsE_[4]

private

Definition at line 88 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitTvsEta_

MonitorElement* EtlSimHitsValidation::meHitTvsEta_[4]

private

Definition at line 92 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitTvsPhi_

MonitorElement* EtlSimHitsValidation::meHitTvsPhi_[4]

private

Definition at line 91 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitX_

MonitorElement* EtlSimHitsValidation::meHitX_[4]

private

Definition at line 82 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitXlocal_

MonitorElement* EtlSimHitsValidation::meHitXlocal_[4]

private

Definition at line 76 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitY_

MonitorElement* EtlSimHitsValidation::meHitY_[4]

private

Definition at line 83 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitYlocal_

MonitorElement* EtlSimHitsValidation::meHitYlocal_[4]

private

Definition at line 77 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitZ_

MonitorElement* EtlSimHitsValidation::meHitZ_[4]

private

Definition at line 84 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meHitZlocal_

MonitorElement* EtlSimHitsValidation::meHitZlocal_[4]

private

Definition at line 78 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meNhits_

MonitorElement* EtlSimHitsValidation::meNhits_[4]

private

Definition at line 70 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meNtrkPerCell_

MonitorElement* EtlSimHitsValidation::meNtrkPerCell_[4]

private

Definition at line 71 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

meOccupancy_

MonitorElement* EtlSimHitsValidation::meOccupancy_[4]

private

Definition at line 80 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and bookHistograms().

mtdgeoToken_

edm::ESGetToken<MTDGeometry, MTDDigiGeometryRecord> EtlSimHitsValidation::mtdgeoToken_

private

Definition at line 65 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and EtlSimHitsValidation().

mtdtopoToken_

edm::ESGetToken<MTDTopology, MTDTopologyRcd> EtlSimHitsValidation::mtdtopoToken_

private

Definition at line 66 of file EtlSimHitsValidation.cc.

Referenced by analyze(), and EtlSimHitsValidation().