CMS 3D CMS Logo

Public Types | Public Member Functions | Static Public Member Functions | Private Attributes

ecaldqm::ClusterTask Class Reference

#include <ClusterTask.h>

Inheritance diagram for ecaldqm::ClusterTask:
ecaldqm::DQWorkerTask ecaldqm::DQWorker

List of all members.

Public Types

enum  MESets {
  kBCEMap, kBCEMapProjEta, kBCEMapProjPhi, kBCOccupancy,
  kBCOccupancyProjEta, kBCOccupancyProjPhi, kBCSizeMap, kBCSizeMapProjEta,
  kBCSizeMapProjPhi, kBCE, kBCNum, kBCSize,
  kSCE, kSCELow, kSCSeedEnergy, kSCClusterVsSeed,
  kSCSeedOccupancy, kSingleCrystalCluster, kSCNum, kSCNBCs,
  kSCNcrystals, kSCR9, kPi0, kJPsi,
  kZ, kHighMass, nMESets
}

Public Member Functions

void analyze (const void *, Collections)
void beginEvent (const edm::Event &, const edm::EventSetup &)
void beginRun (const edm::Run &, const edm::EventSetup &)
void bookMEs ()
 ClusterTask (const edm::ParameterSet &, const edm::ParameterSet &)
bool filterRunType (const std::vector< short > &)
void runOnBasicClusters (const reco::BasicClusterCollection &, Collections)
void runOnRecHits (const EcalRecHitCollection &, Collections)
void runOnSuperClusters (const reco::SuperClusterCollection &, Collections)
 ~ClusterTask ()

Static Public Member Functions

static void setMEData (std::vector< MEData > &)

Private Attributes

const CaloSubdetectorGeometryebGeometry_
const EcalRecHitCollectionebHits_
const CaloSubdetectorGeometryeeGeometry_
const EcalRecHitCollectioneeHits_
int ievt_
float lowEMax_
int massCalcPrescale_
const CaloTopologytopology_

Detailed Description

Definition at line 15 of file ClusterTask.h.


Member Enumeration Documentation

Enumerator:
kBCEMap 
kBCEMapProjEta 
kBCEMapProjPhi 
kBCOccupancy 
kBCOccupancyProjEta 
kBCOccupancyProjPhi 
kBCSizeMap 
kBCSizeMapProjEta 
kBCSizeMapProjPhi 
kBCE 
kBCNum 
kBCSize 
kSCE 
kSCELow 
kSCSeedEnergy 
kSCClusterVsSeed 
kSCSeedOccupancy 
kSingleCrystalCluster 
kSCNum 
kSCNBCs 
kSCNcrystals 
kSCR9 
kPi0 
kJPsi 
kZ 
kHighMass 
nMESets 

Reimplemented from ecaldqm::DQWorker.

Definition at line 33 of file ClusterTask.h.

                {
      kBCEMap, // profile2d
      kBCEMapProjEta, // profile
      kBCEMapProjPhi, // profile
      kBCOccupancy, // h2f
      kBCOccupancyProjEta, // h1f
      kBCOccupancyProjPhi, // h1f
      kBCSizeMap, // profile2d
      kBCSizeMapProjEta, // profile
      kBCSizeMapProjPhi, // profile
      kBCE, // h1f
      kBCNum, // h1f for EB & EE
      kBCSize, // h1f for EB & EE
      kSCE, // h1f
      kSCELow, // h1f
      kSCSeedEnergy, // h1f
      kSCClusterVsSeed, // h2f
      kSCSeedOccupancy, // h2f
      kSingleCrystalCluster, // h2f
      kSCNum, // h1f
      kSCNBCs, // h1f
      kSCNcrystals, // h1f
      kSCR9, // h1f
      kPi0, // h1f
      kJPsi, // h1f
      kZ, // h1f
      kHighMass, // h1f
      nMESets
    };

Constructor & Destructor Documentation

afs cern ch work a aaltunda public www CMSSW_6_2_7 src DQM EcalBarrelMonitorTasks src ClusterTask cc ecaldqm::ClusterTask::ClusterTask ( const edm::ParameterSet ,
const edm::ParameterSet  
)

Definition at line 20 of file ClusterTask.cc.

References edm::ParameterSet::getUntrackedParameter(), edm::ParameterSet::getUntrackedParameterSet(), ecaldqm::kEBBasicCluster, ecaldqm::kEBRecHit, ecaldqm::kEBSuperCluster, ecaldqm::kEEBasicCluster, ecaldqm::kEERecHit, ecaldqm::kEESuperCluster, and ecaldqm::kRun.

  {
    collectionMask_ = 
      (0x1 << kRun) |
      (0x1 << kEBRecHit) |
      (0x1 << kEERecHit) |
      (0x1 << kEBBasicCluster) |
      (0x1 << kEEBasicCluster) |
      (0x1 << kEBSuperCluster) |
      (0x1 << kEESuperCluster);

    dependencies_.push_back(std::pair<Collections, Collections>(kEBSuperCluster, kEBRecHit));
    dependencies_.push_back(std::pair<Collections, Collections>(kEESuperCluster, kEERecHit));

    edm::ParameterSet const& taskParams(_params.getUntrackedParameterSet(name_));

    lowEMax_ = taskParams.getUntrackedParameter<double>("lowEMax");
    massCalcPrescale_ = taskParams.getUntrackedParameter<int>("massCalcPrescale");
  }

ecaldqm::ClusterTask::~ClusterTask ( )

Definition at line 49 of file ClusterTask.cc.

  {
  }


Member Function Documentation

void ecaldqm::ClusterTask::analyze ( const void *  _p,
Collections  _collection 
) [inline, virtual]

Reimplemented from ecaldqm::DQWorkerTask.

Definition at line 76 of file ClusterTask.h.

References ecaldqm::kEBBasicCluster, ecaldqm::kEBRecHit, ecaldqm::kEBSuperCluster, ecaldqm::kEEBasicCluster, ecaldqm::kEERecHit, ecaldqm::kEESuperCluster, runOnBasicClusters(), runOnRecHits(), and runOnSuperClusters().

                                                                         {
    switch(_collection){
    case kEBRecHit:
    case kEERecHit:
      runOnRecHits(*static_cast<const EcalRecHitCollection*>(_p), _collection);
      break;
    case kEBBasicCluster:
    case kEEBasicCluster:
      runOnBasicClusters(*static_cast<const reco::BasicClusterCollection*>(_p), _collection);
      break;
    case kEBSuperCluster:
    case kEESuperCluster:
      runOnSuperClusters(*static_cast<const reco::SuperClusterCollection*>(_p), _collection);
      break;
    default:
      break;
    }
  }
void ecaldqm::ClusterTask::beginEvent ( const edm::Event ,
const edm::EventSetup  
) [virtual]

Reimplemented from ecaldqm::DQWorkerTask.

Definition at line 73 of file ClusterTask.cc.

References ebHits_, eeHits_, and ievt_.

  {
    ebHits_ = 0;
    eeHits_ = 0;

    ievt_++;
  }

void ecaldqm::ClusterTask::beginRun ( const edm::Run ,
const edm::EventSetup _es 
) [virtual]

Reimplemented from ecaldqm::DQWorker.

Definition at line 54 of file ClusterTask.cc.

References ebGeometry_, DetId::Ecal, EcalBarrel, EcalEndcap, eeGeometry_, Exception, edm::EventSetup::get(), ievt_, edm::ESHandle< T >::product(), and topology_.

  {
    edm::ESHandle<CaloTopology> topoHndl;
    _es.get<CaloTopologyRecord>().get(topoHndl);
    topology_ = topoHndl.product();
    if(!topology_)
      throw cms::Exception("EventSetup") << "CaloTopology missing" << std::endl;

    edm::ESHandle<CaloGeometry> geomHndl;
    _es.get<CaloGeometryRecord>().get(geomHndl);
    ebGeometry_ = geomHndl->getSubdetectorGeometry(DetId::Ecal, EcalBarrel);
    eeGeometry_ = geomHndl->getSubdetectorGeometry(DetId::Ecal, EcalEndcap);
    if(!ebGeometry_ || !eeGeometry_)
      throw cms::Exception("EventSetup") << "CaloSubdetectorGeometry missing" << std::endl;

    ievt_ = 0;
  }

void ecaldqm::ClusterTask::bookMEs ( ) [virtual]

Reimplemented from ecaldqm::DQWorker.

Definition at line 82 of file ClusterTask.cc.

References i, kBCE, kBCNum, kBCSize, kHighMass, kJPsi, kPi0, kSCClusterVsSeed, kSCE, kSCELow, kSCNBCs, kSCNcrystals, kSCNum, kSCR9, kSCSeedEnergy, kZ, lowEMax_, and ecaldqm::DQWorker::MEs_.

  {
    DQWorker::bookMEs();

    MEs_[kBCE]->setAxisTitle("energy (GeV)", 1);
    MEs_[kBCNum]->setAxisTitle("number of clusters", 1);
    MEs_[kBCSize]->setAxisTitle("number of clusters", 1);
    MEs_[kSCE]->setAxisTitle("energy (GeV)", 1);
    MEs_[kSCELow]->setAxisTitle("energy (GeV)", 1);
    MEs_[kSCSeedEnergy]->setAxisTitle("energy (GeV)", 1);
    MEs_[kSCClusterVsSeed]->setAxisTitle("seed crystal energy (GeV)", 1);
    MEs_[kSCClusterVsSeed]->setAxisTitle("cluster energy (GeV)", 2);
    MEs_[kSCNum]->setAxisTitle("number of clusters", 1);
    MEs_[kSCNBCs]->setAxisTitle("cluster size", 1);
    MEs_[kSCNcrystals]->setAxisTitle("cluster size", 1);
    MEs_[kSCR9]->setAxisTitle("R9", 1);
    MEs_[kPi0]->setAxisTitle("mass (GeV)", 1);
    MEs_[kJPsi]->setAxisTitle("mass (GeV)", 1);
    MEs_[kZ]->setAxisTitle("mass (GeV)", 1);
    MEs_[kHighMass]->setAxisTitle("mass (GeV)", 1);

    for(int i(0); i < 2; i++)
      MEs_[kSCELow]->getME(i)->getTH1()->GetXaxis()->SetLimits(0., lowEMax_);
  }
  
bool ecaldqm::ClusterTask::filterRunType ( const std::vector< short > &  _runType) [virtual]

Reimplemented from ecaldqm::DQWorkerTask.

Definition at line 108 of file ClusterTask.cc.

References EcalDCCHeaderBlock::COSMIC, EcalDCCHeaderBlock::COSMICS_GLOBAL, EcalDCCHeaderBlock::COSMICS_LOCAL, EcalDCCHeaderBlock::MTCC, EcalDCCHeaderBlock::PHYSICS_GLOBAL, and EcalDCCHeaderBlock::PHYSICS_LOCAL.

  {
    for(int iFED(0); iFED < 54; iFED++){
      if ( _runType[iFED] == EcalDCCHeaderBlock::COSMIC ||
           _runType[iFED] == EcalDCCHeaderBlock::MTCC ||
           _runType[iFED] == EcalDCCHeaderBlock::COSMICS_GLOBAL ||
           _runType[iFED] == EcalDCCHeaderBlock::PHYSICS_GLOBAL ||
           _runType[iFED] == EcalDCCHeaderBlock::COSMICS_LOCAL ||
           _runType[iFED] == EcalDCCHeaderBlock::PHYSICS_LOCAL ) return true;
    }

    return false;
  }

void ecaldqm::ClusterTask::runOnBasicClusters ( const reco::BasicClusterCollection _bcs,
Collections  _collection 
)

Definition at line 138 of file ClusterTask.cc.

References abs, funct::cos(), dPhi(), alignCSCRings::e, ebGeometry_, ebHits_, EcalBarrel, EcalEndcap, eeGeometry_, eeHits_, edm::SortedCollection< T, SORT >::end(), relval_parameters_module::energy, eta(), edm::SortedCollection< T, SORT >::find(), ievt_, kBCE, kBCEMap, kBCEMapProjEta, kBCEMapProjPhi, kBCNum, kBCOccupancy, kBCOccupancyProjEta, kBCOccupancyProjPhi, kBCSize, kBCSizeMap, kBCSizeMapProjEta, kBCSizeMapProjPhi, EcalDQMBinningService::kEB, ecaldqm::kEBBasicCluster, EcalDQMBinningService::kEEm, EcalDQMBinningService::kEEp, kJPsi, kPi0, create_public_lumi_plots::log, massCalcPrescale_, ecaldqm::DQWorker::MEs_, phi, position, funct::sin(), findQualityFiles::size, and mathSSE::sqrt().

Referenced by analyze().

  {
    using namespace std;

    int nBC[] = {0, 0};
    bool isBarrel(_collection == kEBBasicCluster);

    vector<reco::BasicCluster const*> lowMassCands;

    for(reco::BasicClusterCollection::const_iterator bcItr(_bcs.begin()); bcItr != _bcs.end(); ++bcItr){
      const math::XYZPoint &position(bcItr->position());

      DetId id(bcItr->seed());
      if(id.null()){
        GlobalPoint gp(position.x(), position.y(), position.z());
        const CaloSubdetectorGeometry* subgeom(isBarrel ? ebGeometry_ : eeGeometry_);

        id = subgeom->getClosestCell(gp);
      }

      if(id.null() || (id.subdetId() == EcalBarrel && !isBarrel) || (id.subdetId() == EcalEndcap && isBarrel)) continue;

      float energy(bcItr->energy());

      MEs_[kBCE]->fill(id, energy);

      MEs_[kBCEMap]->fill(id, energy);
      MEs_[kBCEMapProjEta]->fill(id, energy);
      MEs_[kBCEMapProjPhi]->fill(id, energy);

      MEs_[kBCOccupancy]->fill(id);
      MEs_[kBCOccupancyProjEta]->fill(id);
      MEs_[kBCOccupancyProjPhi]->fill(id);

      float size(bcItr->size());

      MEs_[kBCSize]->fill(id, size);

      MEs_[kBCSizeMap]->fill(id, size);
      MEs_[kBCSizeMapProjEta]->fill(id, size);
      MEs_[kBCSizeMapProjPhi]->fill(id, size);

      int zside(position.z() > 0 ? 1 : 0);
      nBC[zside]++;

      if(ievt_ % massCalcPrescale_ != 0) continue;

      if(energy > 10.) continue;

      EcalRecHitCollection::const_iterator hitItr(isBarrel ? ebHits_->find(id) : eeHits_->find(id));
      if(hitItr == (isBarrel ? ebHits_->end() : eeHits_->end())) continue;

      // cuts here must be parametrized
      if(hitItr->energy() < 0.5) continue;

      if(hitItr->energy() / energy > 0.95) continue;

      lowMassCands.push_back(&(*bcItr));
    }

    if(isBarrel){
      MEs_[kBCNum]->fill((unsigned)BinService::kEB + 1, nBC[0] + nBC[1]);
    }else{
      MEs_[kBCNum]->fill((unsigned)BinService::kEEm + 1, nBC[0]);
      MEs_[kBCNum]->fill((unsigned)BinService::kEEp + 1, nBC[1]);
    }

    if(ievt_ % massCalcPrescale_ != 0) return;

    for(vector<reco::BasicCluster const*>::iterator bcItr1(lowMassCands.begin()); bcItr1 != lowMassCands.end(); ++bcItr1){
      reco::BasicCluster const& bc1(**bcItr1);
      float energy1(bc1.energy());
      float px1(energy1 * sin(bc1.position().theta()) * cos(bc1.phi()));
      float py1(energy1 * sin(bc1.position().theta()) * sin(bc1.phi()));
      float pz1(energy1 * cos(bc1.position().theta()));

      for(vector<reco::BasicCluster const*>::iterator bcItr2(lowMassCands.begin()); bcItr2 != lowMassCands.end(); ++bcItr2){
        if(*bcItr1 == *bcItr2) continue;
        reco::BasicCluster const& bc2(**bcItr2);
        float energy2(bc2.energy());
        float px2(energy2 * sin(bc2.position().theta()) * cos(bc2.phi()));
        float py2(energy2 * sin(bc2.position().theta()) * sin(bc2.phi()));
        float pz2(energy2 * cos(bc2.position().theta()));

        float ptpair(sqrt((px1 + px2) * (px1 + px2) + (py1 + py2) * (py1 + py2)));
        if(ptpair < 2.5) continue;

        float epair(energy1 + energy2);
        float pzpair(abs(pz1 + pz2));
        
        if(epair < pzpair + 1.e-10) continue;
        float eta(0.5 * log((epair + pzpair)/(epair - pzpair)));
        float phi(atan2(px1 + px2, py1 + py2));

        float iso(0.);
        for(reco::BasicClusterCollection::const_iterator bcItr(_bcs.begin()); bcItr != _bcs.end(); ++bcItr){
          float dEta(bcItr->eta() - eta);
          float dPhi(bcItr->phi() - phi);
          if(sqrt(dEta * dEta + dPhi * dPhi) < 0.2) iso += bcItr->energy() * sin(bcItr->position().theta());
        }
        if(iso > 0.5) continue;

        float mass(sqrt(epair * epair - pzpair * pzpair - ptpair * ptpair));
        MEs_[kPi0]->fill(mass);
        MEs_[kJPsi]->fill(mass);
      }
    }
  }

void ecaldqm::ClusterTask::runOnRecHits ( const EcalRecHitCollection _hits,
Collections  _collection 
)

Definition at line 123 of file ClusterTask.cc.

References ebHits_, eeHits_, ecaldqm::kEBRecHit, and ecaldqm::kEERecHit.

Referenced by analyze().

  {
    switch(_collection){
    case kEBRecHit:
      ebHits_ = &_hits;
      break;
    case kEERecHit:
      eeHits_ = &_hits;
      break;
    default:
      break;
    }
  }

void ecaldqm::ClusterTask::runOnSuperClusters ( const reco::SuperClusterCollection _scs,
Collections  _collection 
)

Definition at line 248 of file ClusterTask.cc.

References funct::cos(), alignCSCRings::e, EcalClusterTools::e3x3(), ebGeometry_, ebHits_, EcalBarrel, EcalEndcap, eeGeometry_, eeHits_, edm::SortedCollection< T, SORT >::end(), reco::CaloCluster::energy(), relval_parameters_module::energy, lumiContext::fill, edm::SortedCollection< T, SORT >::find(), ievt_, EcalDQMBinningService::kEB, ecaldqm::kEBSuperCluster, EcalDQMBinningService::kEEm, EcalDQMBinningService::kEEp, kHighMass, kSCClusterVsSeed, kSCE, kSCELow, kSCNBCs, kSCNcrystals, kSCNum, kSCR9, kSCSeedEnergy, kSCSeedOccupancy, kSingleCrystalCluster, kZ, lowEMax_, massCalcPrescale_, ecaldqm::DQWorker::MEs_, reco::CaloCluster::phi(), reco::CaloCluster::position(), position, funct::sin(), mathSSE::sqrt(), and topology_.

Referenced by analyze().

  {
    using namespace std;

    const EcalRecHitCollection *hits(0);
    bool isBarrel;
    if(_collection == kEBSuperCluster){
      hits = ebHits_;
      isBarrel = true;
    }else{
      hits = eeHits_;
      isBarrel = false;
    }

    reco::SuperCluster const* leading(0);
    reco::SuperCluster const* subLeading(0);

    int nSC[] = {0, 0};

    for(reco::SuperClusterCollection::const_iterator scItr(_scs.begin()); scItr != _scs.end(); ++scItr){
      const math::XYZPoint &position(scItr->position());

      DetId id(scItr->seed()->seed());
      if(id.null()){
        GlobalPoint gp(position.x(), position.y(), position.z());
        const CaloSubdetectorGeometry* subgeom(isBarrel ? ebGeometry_ : eeGeometry_);

        id = subgeom->getClosestCell(gp);
      }

      if(id.null() || (id.subdetId() == EcalBarrel && !isBarrel) || (id.subdetId() == EcalEndcap && isBarrel)) continue;

      float energy(scItr->energy());

      MEs_[kSCE]->fill(id, energy);
      if(energy < lowEMax_) MEs_[kSCELow]->fill(id, energy);

      MEs_[kSCNBCs]->fill(id, scItr->clustersSize());
      MEs_[kSCNcrystals]->fill(id, scItr->size());

      if(!hits) continue;
      EcalRecHitCollection::const_iterator seedItr(hits->find(id));
      if(seedItr == hits->end()) continue;

      MEs_[kSCSeedEnergy]->fill(id, seedItr->energy());
      MEs_[kSCClusterVsSeed]->fill(id, seedItr->energy(), energy);

      MEs_[kSCSeedOccupancy]->fill(id);

      if(_scs.size() == 1)
        MEs_[kSingleCrystalCluster]->fill(id);

      float e3x3(EcalClusterTools::e3x3(*scItr->seed(), hits, topology_));
      MEs_[kSCR9]->fill(id, e3x3 / energy);

      int zside(position.z() > 0 ? 1 : 0);
      nSC[zside]++;

      if(ievt_ % massCalcPrescale_ != 0) continue;

      float et(energy * sin(scItr->position().theta()));
      if(!leading || et > leading->energy() * sin(leading->position().theta())){
        subLeading = leading;
        leading = &(*scItr);
      }
      else if(!subLeading || et > subLeading->energy() * sin(subLeading->position().theta())){
        subLeading = &(*scItr);
      }
    }

    if(_collection == kEBSuperCluster){
      MEs_[kSCNum]->fill((unsigned)BinService::kEB + 1, nSC[0] + nSC[1]);
    }else{
      MEs_[kSCNum]->fill((unsigned)BinService::kEEm + 1, nSC[0]);
      MEs_[kSCNum]->fill((unsigned)BinService::kEEp + 1, nSC[1]);
    }

    if(ievt_ % massCalcPrescale_ != 0) return;

    // implement isolation & cuts
    if(!leading || !subLeading) return;
    float e(leading->energy() + subLeading->energy());
    float px(leading->energy() * sin(leading->position().theta()) * cos(leading->phi()) + subLeading->energy() * sin(subLeading->position().theta()) * cos(subLeading->phi()));
    float py(leading->energy() * sin(leading->position().theta()) * sin(leading->phi()) + subLeading->energy() * sin(subLeading->position().theta()) * sin(subLeading->phi()));
    float pz(leading->energy() * cos(leading->position().theta()) + subLeading->energy() * cos(subLeading->position().theta()));
    float mass(sqrt(e * e - px * px - py * py - pz * pz));
    MEs_[kZ]->fill(mass);
    MEs_[kHighMass]->fill(mass);

  }

void ecaldqm::ClusterTask::setMEData ( std::vector< MEData > &  _data) [static]

Reimplemented from ecaldqm::DQWorker.

Definition at line 341 of file ClusterTask.cc.

References MonitorElement::DQM_KIND_TH1F, MonitorElement::DQM_KIND_TH2F, MonitorElement::DQM_KIND_TPROFILE, MonitorElement::DQM_KIND_TPROFILE2D, EcalDQMBinningService::AxisSpecs::high, kBCE, kBCEMap, kBCEMapProjEta, kBCEMapProjPhi, kBCNum, kBCOccupancy, kBCOccupancyProjEta, kBCOccupancyProjPhi, kBCSize, kBCSizeMap, kBCSizeMapProjEta, kBCSizeMapProjPhi, EcalDQMBinningService::kEcal2P, EcalDQMBinningService::kEcal3P, kHighMass, kJPsi, kPi0, EcalDQMBinningService::kProjEta, EcalDQMBinningService::kProjPhi, kSCClusterVsSeed, kSCE, kSCELow, kSCNBCs, kSCNcrystals, kSCNum, kSCR9, kSCSeedEnergy, kSCSeedOccupancy, kSingleCrystalCluster, EcalDQMBinningService::kSuperCrystal, EcalDQMBinningService::kUser, kZ, EcalDQMBinningService::AxisSpecs::low, EcalDQMBinningService::AxisSpecs::nbins, and EcalDQMBinningService::nObjType.

  {
    BinService::AxisSpecs xaxis, yaxis, zaxis;

    zaxis.low = 0.;
    zaxis.high = 50.;
    _data[kBCEMap] = MEData("BCEMap", BinService::kEcal3P, BinService::kSuperCrystal, MonitorElement::DQM_KIND_TPROFILE2D, 0, 0, &zaxis);
    _data[kBCEMapProjEta] = MEData("BCEMap", BinService::kEcal3P, BinService::kProjEta, MonitorElement::DQM_KIND_TPROFILE);
    _data[kBCEMapProjPhi] = MEData("BCEMap", BinService::kEcal3P, BinService::kProjPhi, MonitorElement::DQM_KIND_TPROFILE);

    _data[kBCOccupancy] = MEData("BCOccupancy", BinService::kEcal3P, BinService::kSuperCrystal, MonitorElement::DQM_KIND_TH2F);
    _data[kBCOccupancyProjEta] = MEData("BCOccupancy", BinService::kEcal3P, BinService::kProjEta, MonitorElement::DQM_KIND_TH1F);
    _data[kBCOccupancyProjPhi] = MEData("BCOccupancy", BinService::kEcal3P, BinService::kProjPhi, MonitorElement::DQM_KIND_TH1F);

    zaxis.high = 30.;
    _data[kBCSizeMap] = MEData("BCSizeMap", BinService::kEcal3P, BinService::kSuperCrystal, MonitorElement::DQM_KIND_TPROFILE2D, 0, 0, &zaxis);
    _data[kBCSizeMapProjEta] = MEData("BCSizeMap", BinService::kEcal3P, BinService::kProjEta, MonitorElement::DQM_KIND_TPROFILE);
    _data[kBCSizeMapProjPhi] = MEData("BCSizeMap", BinService::kEcal3P, BinService::kProjPhi, MonitorElement::DQM_KIND_TPROFILE);

    xaxis.nbins = 50;
    xaxis.low = 0.;
    xaxis.high = 150.;
    _data[kBCE] = MEData("BCE", BinService::kEcal3P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);

    xaxis.nbins = 20;
    xaxis.low = 0.;
    xaxis.high = 100.;
    _data[kBCNum] = MEData("BCNum", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);

    xaxis.nbins = 50;
    xaxis.low = 0.;
    xaxis.high = 100.;
    _data[kBCSize] = MEData("BCSize", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);

    xaxis.nbins = 50;
    xaxis.low = 0.;
    xaxis.high = 150.;
    _data[kSCE] = MEData("SCE", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);

    xaxis.nbins = 50;
    xaxis.low = 0.;
    xaxis.high = 10.;
    _data[kSCELow] = MEData("SCELow", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);

    xaxis.nbins = 50;
    xaxis.low = 0.;
    xaxis.high = 150.;
    _data[kSCSeedEnergy] = MEData("SCSeedEnergy", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);

    yaxis.nbins = 50;
    yaxis.low = 0.;
    yaxis.high = 150.;
    _data[kSCClusterVsSeed] = MEData("SCClusterVsSeed", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH2F, &xaxis, &yaxis);

    _data[kSCSeedOccupancy] = MEData("SCSeedOccupancy", BinService::kEcal3P, BinService::kSuperCrystal, MonitorElement::DQM_KIND_TH2F);
    _data[kSingleCrystalCluster] = MEData("SCSingleCrystalCluster", BinService::kEcal3P, BinService::kSuperCrystal, MonitorElement::DQM_KIND_TH2F);

    xaxis.nbins = 20;
    xaxis.low = 0.;
    xaxis.high = 20.;
    _data[kSCNum] = MEData("SCNum", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);

    xaxis.nbins = 15;
    xaxis.low = 0.;
    xaxis.high = 15.;
    _data[kSCNBCs] = MEData("SCNBCs", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);
    xaxis.nbins = 50;
    xaxis.low = 0.;
    xaxis.high = 150.;
    _data[kSCNcrystals] = MEData("SCNcrystals", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);

    xaxis.nbins = 50;
    xaxis.low = 0.;
    xaxis.high = 1.2;
    _data[kSCR9] = MEData("SCR9", BinService::kEcal2P, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);


    xaxis.nbins = 50;
    xaxis.low = 0.;
    xaxis.high = 0.5;
    _data[kPi0] = MEData("Pi0", BinService::nObjType, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);
    xaxis.low = 2.9;
    xaxis.high = 3.3;
    _data[kJPsi] = MEData("JPsi", BinService::nObjType, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);
    xaxis.low = 40.;
    xaxis.high = 110.;
    _data[kZ] = MEData("Z", BinService::nObjType, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);
    xaxis.low = 110.;
    xaxis.high = 3000.;
    _data[kHighMass] = MEData("HighMass", BinService::nObjType, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &xaxis);
  }


Member Data Documentation

Definition at line 68 of file ClusterTask.h.

Referenced by beginRun(), runOnBasicClusters(), and runOnSuperClusters().

Definition at line 70 of file ClusterTask.h.

Referenced by beginEvent(), runOnBasicClusters(), runOnRecHits(), and runOnSuperClusters().

Definition at line 69 of file ClusterTask.h.

Referenced by beginRun(), runOnBasicClusters(), and runOnSuperClusters().

Definition at line 70 of file ClusterTask.h.

Referenced by beginEvent(), runOnBasicClusters(), runOnRecHits(), and runOnSuperClusters().

Definition at line 71 of file ClusterTask.h.

Referenced by beginEvent(), beginRun(), runOnBasicClusters(), and runOnSuperClusters().

Definition at line 72 of file ClusterTask.h.

Referenced by bookMEs(), and runOnSuperClusters().

Definition at line 73 of file ClusterTask.h.

Referenced by runOnBasicClusters(), and runOnSuperClusters().

Definition at line 67 of file ClusterTask.h.

Referenced by beginRun(), and runOnSuperClusters().