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Public Member Functions | Private Attributes

EcalSimple2007H4TBAnalyzer Class Reference

#include <EcalSimple2007H4TBAnalyzer.h>

Inheritance diagram for EcalSimple2007H4TBAnalyzer:
edm::EDAnalyzer

List of all members.

Public Member Functions

virtual void analyze (edm::Event const &, edm::EventSetup const &)
virtual void beginRun (edm::Run const &, edm::EventSetup const &)
 EcalSimple2007H4TBAnalyzer (const edm::ParameterSet &)
virtual void endJob ()
 ~EcalSimple2007H4TBAnalyzer ()

Private Attributes

std::string digiCollection_
std::string digiProducer_
std::string eventHeaderCollection_
std::string eventHeaderProducer_
TH2F * h_ampltdc
TH1F * h_bprofx
TH1F * h_bprofy
TH1F * h_e1e25
TH2F * h_e1e25_mapx
TH2F * h_e1e25_mapy
TH1F * h_e1e9
TH2F * h_e1e9_mapx
TH2F * h_e1e9_mapy
TH1F * h_e1x1
TH1F * h_e1x1_center
TH1F * h_e3x3
TH1F * h_e3x3_center
TH1F * h_e5x5
TH1F * h_e5x5_center
TH1F * h_e9e25
TH2F * h_e9e25_mapx
TH2F * h_e9e25_mapy
TH2F * h_mapx [25]
TH2F * h_mapy [25]
TH1F * h_qualx
TH1F * h_qualy
TH1F * h_S6
TH2F * h_Shape_
TH1F * h_slopex
TH1F * h_slopey
TH1F * h_tableIsMoving
std::string hitCollection_
std::string hitProducer_
std::string hodoRecInfoCollection_
std::string hodoRecInfoProducer_
std::string rootfile_
std::string tdcRecInfoCollection_
std::string tdcRecInfoProducer_
const CaloGeometrytheTBGeometry_
EEDetId xtalInBeam_
EBDetId xtalInBeamTmp
EEDetId Xtals5x5 [25]

Detailed Description

Description: <one line="" class="" summary>="">

Implementation: <Notes on="" implementation>="">

Definition at line 45 of file EcalSimple2007H4TBAnalyzer.h.


Constructor & Destructor Documentation

EcalSimple2007H4TBAnalyzer::EcalSimple2007H4TBAnalyzer ( const edm::ParameterSet iConfig) [explicit]

Definition at line 51 of file EcalSimple2007H4TBAnalyzer.cc.

References gather_cfg::cout, digiCollection_, digiProducer_, eventHeaderCollection_, eventHeaderProducer_, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), hitCollection_, hitProducer_, hodoRecInfoCollection_, hodoRecInfoProducer_, rootfile_, tdcRecInfoCollection_, and tdcRecInfoProducer_.

                                                                                       : xtalInBeam_(0)
//========================================================================
{
   //now do what ever initialization is needed
   rootfile_          = iConfig.getUntrackedParameter<std::string>("rootfile","ecalSimpleTBanalysis.root");
   digiCollection_     = iConfig.getParameter<std::string>("digiCollection");
   digiProducer_       = iConfig.getParameter<std::string>("digiProducer");
   hitCollection_     = iConfig.getParameter<std::string>("hitCollection");
   hitProducer_       = iConfig.getParameter<std::string>("hitProducer");
   hodoRecInfoCollection_     = iConfig.getParameter<std::string>("hodoRecInfoCollection");
   hodoRecInfoProducer_       = iConfig.getParameter<std::string>("hodoRecInfoProducer");
   tdcRecInfoCollection_     = iConfig.getParameter<std::string>("tdcRecInfoCollection");
   tdcRecInfoProducer_       = iConfig.getParameter<std::string>("tdcRecInfoProducer");
   eventHeaderCollection_     = iConfig.getParameter<std::string>("eventHeaderCollection");
   eventHeaderProducer_       = iConfig.getParameter<std::string>("eventHeaderProducer");


   std::cout << "EcalSimple2007H4TBAnalyzer: fetching hitCollection: " << hitCollection_.c_str()
        << " produced by " << hitProducer_.c_str() << std::endl;

}
EcalSimple2007H4TBAnalyzer::~EcalSimple2007H4TBAnalyzer ( )

Definition at line 75 of file EcalSimple2007H4TBAnalyzer.cc.

{
  // do anything here that needs to be done at desctruction time
  // (e.g. close files, deallocate resources etc.)
  // Amplitude vs TDC offset
//   if (h_ampltdc)
//   delete h_ampltdc;
  
//   // Reconstructed energies
//   delete h_e1x1;
//   delete h_e3x3; 
//   delete h_e5x5; 
  
//   delete h_bprofx; 
//   delete h_bprofy; 
  
//   delete h_qualx; 
//   delete h_qualy; 
  
//   delete h_slopex; 
//   delete h_slopey; 
  
//   delete h_mapx; 
//   delete h_mapy; 

}

Member Function Documentation

void EcalSimple2007H4TBAnalyzer::analyze ( edm::Event const &  iEvent,
edm::EventSetup const &  iSetup 
) [virtual]

Implements edm::EDAnalyzer.

Definition at line 233 of file EcalSimple2007H4TBAnalyzer.cc.

References EcalMGPASample::adc(), gather_cfg::cout, digiCollection_, digiProducer_, jptDQMConfig_cff::eMax, eventHeaderProducer_, edm::Event::getByLabel(), CaloGeometry::getGeometry(), TruncatedPyramid::getPosition(), h_ampltdc, h_bprofx, h_bprofy, h_e1e25, h_e1e25_mapx, h_e1e25_mapy, h_e1e9, h_e1e9_mapx, h_e1e9_mapy, h_e1x1, h_e1x1_center, h_e3x3, h_e3x3_center, h_e5x5, h_e5x5_center, h_e9e25, h_e9e25_mapx, h_e9e25_mapy, h_mapx, h_mapy, h_qualx, h_qualy, h_S6, h_Shape_, h_slopex, h_slopey, h_tableIsMoving, hitCollection_, hitProducer_, hodoRecInfoCollection_, hodoRecInfoProducer_, i, EBDetId::ic(), DetId::null(), EcalDataFrame::sample(), EcalDataFrame::size(), EBDetId::SMCRYSTALMODE, tdcRecInfoCollection_, tdcRecInfoProducer_, theTBGeometry_, x, xtalInBeam_, xtalInBeamTmp, Xtals5x5, detailsBasic3DVector::y, and EBDetId::zside().

                                                                                           {
//========================================================================

   using namespace edm;
   using namespace cms;



   Handle<EEDigiCollection> pdigis;
   const EEDigiCollection* digis=0;
   //std::cout << "EcalSimple2007H4TBAnalyzer::analyze getting product with label: " << digiProducer_.c_str()<< " prodname: " << digiCollection_.c_str() << endl;
   iEvent.getByLabel( digiProducer_, digiCollection_,pdigis);
   if ( pdigis.isValid() ) {
     digis = pdigis.product(); // get a ptr to the product
     //iEvent.getByLabel( hitProducer_, phits);
   } else {
           edm::LogError("EcalSimple2007H4TBAnalyzerError") << "Error! can't get the product " << digiCollection_;
   }

   // fetch the digis and compute signal amplitude
   Handle<EEUncalibratedRecHitCollection> phits;
   const EEUncalibratedRecHitCollection* hits=0;
   //std::cout << "EcalSimple2007H4TBAnalyzer::analyze getting product with label: " << digiProducer_.c_str()<< " prodname: " << digiCollection_.c_str() << endl;
   iEvent.getByLabel( hitProducer_, hitCollection_,phits);
   if (phits.isValid()) {
     hits = phits.product(); // get a ptr to the product
     //iEvent.getByLabel( hitProducer_, phits);
   } else {
           edm::LogError("EcalSimple2007H4TBAnalyzerError") << "Error! can't get the product " << hitCollection_;
   }

   Handle<EcalTBHodoscopeRecInfo> pHodo;
   const EcalTBHodoscopeRecInfo* recHodo=0;
   //std::cout << "EcalSimple2007H4TBAnalyzer::analyze getting product with label: " << digiProducer_.c_str()<< " prodname: " << digiCollection_.c_str() << endl;
   iEvent.getByLabel( hodoRecInfoProducer_, hodoRecInfoCollection_, pHodo);
   if ( pHodo.isValid() ) {
     recHodo = pHodo.product(); // get a ptr to the product
   } else {
           edm::LogError("EcalSimple2007H4TBAnalyzerError") << "Error! can't get the product " << hodoRecInfoCollection_;
   }

   Handle<EcalTBTDCRecInfo> pTDC;
   const EcalTBTDCRecInfo* recTDC=0;
   //std::cout << "EcalSimple2007H4TBAnalyzer::analyze getting product with label: " << digiProducer_.c_str()<< " prodname: " << digiCollection_.c_str() << endl;
   iEvent.getByLabel( tdcRecInfoProducer_, tdcRecInfoCollection_, pTDC);
   if ( pTDC.isValid() ) {
     recTDC = pTDC.product(); // get a ptr to the product
   } else {
           edm::LogError("EcalSimple2007H4TBAnalyzerError") << "Error! can't get the product " << tdcRecInfoCollection_;
   }

   Handle<EcalTBEventHeader> pEventHeader;
   const EcalTBEventHeader* evtHeader=0;
   //std::cout << "EcalSimple2007H4TBAnalyzer::analyze getting product with label: " << digiProducer_.c_str()<< " prodname: " << digiCollection_.c_str() << endl;
   iEvent.getByLabel( eventHeaderProducer_ , pEventHeader );
   if ( pEventHeader.isValid() ) {
     evtHeader = pEventHeader.product(); // get a ptr to the product
   } else {
           edm::LogError("EcalSimple2007H4TBAnalyzerError") << "Error! can't get the product " << eventHeaderProducer_;
   }
   
   
   if (!hits)
     {
       //       std::cout << "1" << std::endl;
       return;
     }

   if (!recTDC)
     {
       //       std::cout << "2" << std::endl;
       return;
     }

   if (!recHodo)
     {
       //       std::cout << "3" << std::endl;
       return;
     }

   if (!evtHeader)
     {
       //       std::cout << "4" << std::endl;
       return;
     }

   if (hits->size() == 0)
     {
       //       std::cout << "5" << std::endl;
       return;
     }

   //Accessing various event information
   if (evtHeader->tableIsMoving())
     h_tableIsMoving->Fill(evtHeader->eventNumber());

//    std::cout << "event " << evtHeader->eventNumber() 
//           << "\trun number " << evtHeader->runNumber()   
//           << "\tburst number " << evtHeader->burstNumber()   
//           << "\tbeginLV1A " << evtHeader->begBurstLV1A()
//           << "\tendLV1A " << evtHeader->endBurstLV1A()
//           << "\ttime " << evtHeader->date()
//           << "\thas errors " << int(evtHeader->syncError())
//           << std::endl;

//    std::cout << "scaler";
//    for (int iscaler=0;iscaler < 36;iscaler++)
//      std::cout << "\t#" << iscaler << " " <<  evtHeader->scaler(iscaler);
//    std::cout<<std::endl;

   //S6 beam scintillator
   h_S6->Fill(evtHeader->S6ADC());

   if (xtalInBeamTmp.null())
     {
       xtalInBeamTmp = EBDetId(1,evtHeader->crystalInBeam(),EBDetId::SMCRYSTALMODE);
       xtalInBeam_ = EEDetId( 35 - ((xtalInBeamTmp.ic()-1)%20) ,int(int(xtalInBeamTmp.ic())/int(20))+51, -1);
       std::cout<< "Xtal In Beam is " << xtalInBeam_.ic() << xtalInBeam_ << std::endl;
       for (unsigned int icry=0;icry<25;icry++)
         {
           unsigned int row = icry / 5;
           unsigned int column= icry %5;
           int ix=xtalInBeam_.ix()+row-2;
           int iy=xtalInBeam_.iy()+column-2;
           EEDetId tempId(ix, iy, xtalInBeam_.zside());
           //Selecting matrix of xtals used in 2007H4TB
           if (tempId.ix()<16 || tempId.ix()>35 || tempId.iy()<51 || tempId.iy()>75)
             Xtals5x5[icry]=EEDetId(0);
           else
             {
               Xtals5x5[icry]=tempId;
               const CaloCellGeometry* cell=theTBGeometry_->getGeometry(Xtals5x5[icry]);
               if (!cell) 
                 continue;
               const TruncatedPyramid* tp ( dynamic_cast<const TruncatedPyramid*>(cell) ) ;
               std::cout << "** Xtal in the matrix **** row " << row  << ", column " << column << ", xtal " << Xtals5x5[icry] << " Position " << tp->getPosition(0.) << std::endl;
             }
         }
     }
   else 
     if (xtalInBeamTmp != EBDetId(1,evtHeader->crystalInBeam(),EBDetId::SMCRYSTALMODE)) //run analysis only on first xtal in beam
       return;

   //Avoid moving table events
   if (evtHeader->tableIsMoving())
     {
       std::cout << "Table is moving" << std::endl;
       return;
     }


   
   // Searching for max amplitude xtal alternative to use xtalInBeam_
   EEDetId maxHitId(0); 
   float maxHit= -999999.;
   for(EEUncalibratedRecHitCollection::const_iterator ithit = hits->begin(); ithit != hits->end(); ++ithit) 
     {
       if (ithit->amplitude()>=maxHit)
         {
           maxHit=ithit->amplitude();
           maxHitId=ithit->id();
         }
       
     }   
   if (maxHitId==EEDetId(0))
     {
       std::cout << "No maxHit found" << std::endl;
       return;
     }

    
   //Filling the digis shape for the xtalInBeam
   double samples_save[10]; for(int i=0; i < 10; ++i) samples_save[i]=0.0;
   
   double eMax = 0.;
   for ( EEDigiCollection::const_iterator digiItr= digis->begin();digiItr != digis->end(); 
         ++digiItr ) 
     {          
       if ( EEDetId((*digiItr).id()) != xtalInBeam_ )
         continue;
       
       EEDataFrame myDigi = (*digiItr);
       for (int sample = 0; sample < myDigi.size(); ++sample)
         {
           double analogSample = myDigi.sample(sample).adc();
           samples_save[sample] = analogSample;
           //  std::cout << analogSample << " ";
           if ( eMax < analogSample )
             {
               eMax = analogSample;
             }
         }
       // std::cout << std::endl;
     }

   for(int i =0; i < 10; ++i) 
     h_Shape_->Fill(double(i)+recTDC->offset(),samples_save[i]);



   // Taking amplitudes in 5x5
   double amplitude[25];
   double amplitude3x3=0;  
   double amplitude5x5=0;  
   for (unsigned int icry=0;icry<25;icry++)
     {
       if (!Xtals5x5[icry].null())
         {
           amplitude[icry]=(hits->find(Xtals5x5[icry]))->amplitude();
           amplitude5x5 += amplitude[icry];
           // Is in 3x3?
           if ( icry == 6  || icry == 7  || icry == 8 ||
                icry == 11 || icry == 12 || icry ==13 ||
                icry == 16 || icry == 17 || icry ==18   )
             {
               amplitude3x3+=amplitude[icry];
             }
         }
     }

   //Filling amplitudes
   h_e1x1->Fill(amplitude[12]);
   h_e3x3->Fill(amplitude3x3);
   h_e5x5->Fill(amplitude5x5);

   h_e1e9->Fill(amplitude[12]/amplitude3x3);
   h_e1e25->Fill(amplitude[12]/amplitude5x5);
   h_e9e25->Fill(amplitude3x3/amplitude5x5);

   //Checking stability of amplitude vs TDC
   if (recTDC)
     h_ampltdc->Fill(recTDC->offset(),amplitude[12]);

   //Various amplitudes as a function of hodoscope coordinates
   if (recHodo)
     {
       float x=recHodo->posX();
       float y=recHodo->posY();
       float xslope=recHodo->slopeX();
       float yslope=recHodo->slopeY();
       float xqual=recHodo->qualX();
       float yqual=recHodo->qualY();
       
       //Filling beam profiles
       h_bprofx->Fill(x);
       h_bprofy->Fill(y);
       h_qualx->Fill(xqual);
       h_qualy->Fill(yqual);
       h_slopex->Fill(xslope);
       h_slopey->Fill(yslope);

       //Fill central events

       
       if ( fabs(x + 2.5) < 2.5 && fabs(y + 0.5) < 2.5)
         {
           h_e1x1_center->Fill(amplitude[12]);
           h_e3x3_center->Fill(amplitude3x3);
           h_e5x5_center->Fill(amplitude5x5);
         }

       for (unsigned int icry=0;icry<25;icry++)
         {       
           h_mapx[icry]->Fill(x,amplitude[icry]);
           h_mapy[icry]->Fill(y,amplitude[icry]);
         }

       h_e1e9_mapx->Fill(x,amplitude[12]/amplitude3x3);
       h_e1e9_mapy->Fill(y,amplitude[12]/amplitude3x3);

       h_e1e25_mapx->Fill(x,amplitude[12]/amplitude5x5);
       h_e1e25_mapy->Fill(y,amplitude[12]/amplitude5x5);

       h_e9e25_mapx->Fill(x,amplitude3x3/amplitude5x5);
       h_e9e25_mapy->Fill(y,amplitude3x3/amplitude5x5);
     }

}
void EcalSimple2007H4TBAnalyzer::beginRun ( edm::Run const &  ,
edm::EventSetup const &  iSetup 
) [virtual]

Reimplemented from edm::EDAnalyzer.

Definition at line 105 of file EcalSimple2007H4TBAnalyzer.cc.

References alignCSCRings::e, edm::EventSetup::get(), h_ampltdc, h_bprofx, h_bprofy, h_e1e25, h_e1e25_mapx, h_e1e25_mapy, h_e1e9, h_e1e9_mapx, h_e1e9_mapy, h_e1x1, h_e1x1_center, h_e3x3, h_e3x3_center, h_e5x5, h_e5x5_center, h_e9e25, h_e9e25_mapx, h_e9e25_mapy, h_mapx, h_mapy, h_qualx, h_qualy, h_S6, h_Shape_, h_slopex, h_slopey, h_tableIsMoving, and theTBGeometry_.

                                                                                {
//========================================================================

  edm::ESHandle<CaloGeometry> pG;
  iSetup.get<CaloGeometryRecord>().get(pG);   

  
  theTBGeometry_ =  &(*pG);
//  const std::vector<DetId>& validIds=theTBGeometry_->getValidDetIds(DetId::Ecal,EcalEndcap);
//   std::cout << "Found " << validIds.size() << " channels in the geometry" << std::endl;
//   for (unsigned int i=0;i<validIds.size();++i)
//     std::cout << EEDetId(validIds[i]) << std::endl;

// Amplitude vs TDC offset
  h_ampltdc = new TH2F("h_ampltdc","Max Amplitude vs TDC offset", 100,0.,1.,1000, 0., 4000.);

  // Reconstructed energies
  h_tableIsMoving = new TH1F("h_tableIsMoving","TableIsMoving", 100000, 0., 100000.);

  h_e1x1 = new TH1F("h_e1x1","E1x1 energy", 1000, 0., 4000.);
  h_e3x3 = new TH1F("h_e3x3","E3x3 energy", 1000, 0., 4000.);
  h_e5x5 = new TH1F("h_e5x5","E5x5 energy", 1000, 0., 4000.);

  h_e1x1_center = new TH1F("h_e1x1_center","E1x1 energy", 1000, 0., 4000.);
  h_e3x3_center = new TH1F("h_e3x3_center","E3x3 energy", 1000, 0., 4000.);
  h_e5x5_center = new TH1F("h_e5x5_center","E5x5 energy", 1000, 0., 4000.);

  h_e1e9 = new TH1F("h_e1e9","E1/E9 ratio", 600, 0., 1.2);
  h_e1e25 = new TH1F("h_e1e25","E1/E25 ratio", 600, 0., 1.2);
  h_e9e25 = new TH1F("h_e9e25","E9/E25 ratio", 600, 0., 1.2);

  h_S6 = new TH1F("h_S6","Amplitude S6", 1000, 0., 4000.);

  h_bprofx = new TH1F("h_bprofx","Beam Profile X",100,-20.,20.);
  h_bprofy = new TH1F("h_bprofy","Beam Profile Y",100,-20.,20.);

  h_qualx = new TH1F("h_qualx","Beam Quality X",5000,0.,5.);
  h_qualy = new TH1F("h_qualy","Beam Quality X",5000,0.,5.);

  h_slopex = new TH1F("h_slopex","Beam Slope X",500, -5e-4 , 5e-4 );
  h_slopey = new TH1F("h_slopey","Beam Slope Y",500, -5e-4 , 5e-4 );

  char hname[50];
  char htitle[50];
  for (unsigned int icry=0;icry<25;icry++)
    {       
      sprintf(hname,"h_mapx_%d",icry);
      sprintf(htitle,"Max Amplitude vs X %d",icry);
      h_mapx[icry] = new TH2F(hname,htitle,80,-20,20,1000,0.,4000.);
      sprintf(hname,"h_mapy_%d",icry);
      sprintf(htitle,"Max Amplitude vs Y %d",icry);
      h_mapy[icry] = new TH2F(hname,htitle,80,-20,20,1000,0.,4000.);
    }
  
  h_e1e9_mapx = new TH2F("h_e1e9_mapx","E1/E9 vs X",80,-20,20,600,0.,1.2);
  h_e1e9_mapy = new TH2F("h_e1e9_mapy","E1/E9 vs Y",80,-20,20,600,0.,1.2);

  h_e1e25_mapx = new TH2F("h_e1e25_mapx","E1/E25 vs X",80,-20,20,600,0.,1.2);
  h_e1e25_mapy = new TH2F("h_e1e25_mapy","E1/E25 vs Y",80,-20,20,600,0.,1.2);

  h_e9e25_mapx = new TH2F("h_e9e25_mapx","E9/E25 vs X",80,-20,20,600,0.,1.2);
  h_e9e25_mapy = new TH2F("h_e9e25_mapy","E9/E25 vs Y",80,-20,20,600,0.,1.2);

  h_Shape_ = new TH2F("h_Shape_","Xtal in Beam Shape",250,0,10,350,0,3500);

}
void EcalSimple2007H4TBAnalyzer::endJob ( void  ) [virtual]

Reimplemented from edm::EDAnalyzer.

Definition at line 174 of file EcalSimple2007H4TBAnalyzer.cc.

References f, h_ampltdc, h_bprofx, h_bprofy, h_e1e25, h_e1e25_mapx, h_e1e25_mapy, h_e1e9, h_e1e9_mapx, h_e1e9_mapy, h_e1x1, h_e1x1_center, h_e3x3, h_e3x3_center, h_e5x5, h_e5x5_center, h_e9e25, h_e9e25_mapx, h_e9e25_mapy, h_mapx, h_mapy, h_qualx, h_qualy, h_S6, h_Shape_, h_slopex, h_slopey, h_tableIsMoving, and rootfile_.

                                   {
//========================================================================

  TFile f(rootfile_.c_str(),"RECREATE");

  // Amplitude vs TDC offset
  h_ampltdc->Write(); 

  // Reconstructed energies
  h_e1x1->Write(); 
  h_e3x3->Write(); 
  h_e5x5->Write(); 

  h_e1x1_center->Write(); 
  h_e3x3_center->Write(); 
  h_e5x5_center->Write(); 

  h_e1e9->Write(); 
  h_e1e25->Write(); 
  h_e9e25->Write(); 

  h_S6->Write(); 
  h_bprofx->Write(); 
  h_bprofy->Write(); 

  h_qualx->Write(); 
  h_qualy->Write(); 

  h_slopex->Write(); 
  h_slopey->Write(); 
  
  h_Shape_->Write();

  for (unsigned int icry=0;icry<25;icry++)
    {       
      h_mapx[icry]->Write(); 
      h_mapy[icry]->Write(); 
    }

  h_e1e9_mapx->Write(); 
  h_e1e9_mapy->Write(); 

  h_e1e25_mapx->Write(); 
  h_e1e25_mapy->Write(); 

  h_e9e25_mapx->Write(); 
  h_e9e25_mapy->Write(); 

  h_tableIsMoving->Write();

  f.Close();
}

Member Data Documentation

Definition at line 56 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 57 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 64 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by EcalSimple2007H4TBAnalyzer().

Definition at line 65 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 68 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 87 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 88 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 83 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 102 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 103 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 82 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 99 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 100 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 74 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 78 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 75 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 79 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 76 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 80 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 84 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 105 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 106 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 96 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 97 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 90 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 91 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 86 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 70 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 93 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 94 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 73 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), beginRun(), and endJob().

Definition at line 58 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 59 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 60 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 61 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 55 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by EcalSimple2007H4TBAnalyzer(), and endJob().

Definition at line 62 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 63 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and EcalSimple2007H4TBAnalyzer().

Definition at line 112 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze(), and beginRun().

Definition at line 108 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze().

Definition at line 109 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze().

Definition at line 110 of file EcalSimple2007H4TBAnalyzer.h.

Referenced by analyze().