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Public Member Functions | Private Member Functions | Private Attributes

HcalNoiseMonitor Class Reference

#include <HcalNoiseMonitor.h>

Inheritance diagram for HcalNoiseMonitor:
HcalBaseDQMonitor edm::EDAnalyzer

List of all members.

Public Member Functions

void analyze (edm::Event const &e, edm::EventSetup const &s)
void beginRun (const edm::Run &run, const edm::EventSetup &c)
void cleanup ()
 HcalNoiseMonitor (const edm::ParameterSet &ps)
void reset ()
void setup ()
void unpack (const FEDRawData &raw, const HcalElectronicsMap &emap)
 ~HcalNoiseMonitor ()

Private Member Functions

double CalculateRMS8Max (double Charge[10])
double DualNominalFitSingleTry (double Charge[10], int Offset, int Distance)
double PerformDualNominalFit (double Charge[10])
double PerformLinearFit (double Charge[10])
double PerformNominalFit (double Charge[10])
TriangleFitResult PerformTriangleFit (double Charge[10])
void ReadHcalPulse ()

Private Attributes

std::vector< double > CumulativeIdealPulse
MonitorElementhBadCountHPD
MonitorElementhBadE2E10RBX
MonitorElementhBadNoOtherCountHPD
MonitorElementhBadZeroRBX
edm::InputTag hbheDigiLabel_
edm::InputTag hbheRechitLabel_
MonitorElementhE2OverE10Digi
MonitorElementhE2OverE10Digi5
MonitorElementhE2OverE10RBX
EtaPhiHists hFailIsolationEtaPhi
EtaPhiHists hFailLinearEtaPhi
EtaPhiHists hFailRMSMaxEtaPhi
EtaPhiHists hFailTriangleEtaPhi
MonitorElementhHcalNoiseCategory
MonitorElementhHPDHitCount
MonitorElementhLambdaLinearVsTotalCharge
MonitorElementhLambdaRMS8MaxVsTotalCharge
MonitorElementhLinearChi2
MonitorElementhLinearTestStatistics
edm::InputTag hltresultsLabel_
MonitorElementhMaxZeros
MonitorElementhNominalChi2
MonitorElementhRBXHitCount
MonitorElementhRMS8OverMax
MonitorElementhRMS8OverMaxTestStatistics
MonitorElementhTotalZeros
MonitorElementhTriangleLeftSlopeVsTS4
MonitorElementhTriangleRightSlopeVsTS4
MonitorElementhTS4TS5RelativeDifference
MonitorElementhTS4TS5RelativeDifferenceVsCharge
double mE2E10MinEnergy
int mMaxADCZeros
double mMaxE2E10
int mMaxHPDHitCount
int mMaxHPDNoOtherHitCount
double mMinE2E10
double mTotalZeroMinEnergy
int mTrianglePeakTS
edm::InputTag noiseLabel_
int period_
edm::InputTag rawdataLabel_
std::vector< std::string > triggers_

Detailed Description

Definition at line 13 of file HcalNoiseMonitor.h.


Constructor & Destructor Documentation

HcalNoiseMonitor::HcalNoiseMonitor ( const edm::ParameterSet ps)

Definition at line 28 of file HcalNoiseMonitor.cc.

References HcalBaseDQMonitor::AllowedCalibTypes_, HcalBaseDQMonitor::debug_, HcalBaseDQMonitor::enableCleanup_, edm::ParameterSet::getUntrackedParameter(), hbheDigiLabel_, hbheRechitLabel_, hltresultsLabel_, HcalBaseDQMonitor::makeDiagnostics_, mE2E10MinEnergy, HcalBaseDQMonitor::mergeRuns_, mMaxADCZeros, mMaxE2E10, mMaxHPDHitCount, mMaxHPDNoOtherHitCount, mMinE2E10, mTotalZeroMinEnergy, mTrianglePeakTS, HcalBaseDQMonitor::NLumiBlocks_, noiseLabel_, HcalBaseDQMonitor::Online_, period_, HcalBaseDQMonitor::prefixME_, rawdataLabel_, HcalBaseDQMonitor::skipOutOfOrderLS_, HcalBaseDQMonitor::subdir_, and triggers_.

{
   Online_                = ps.getUntrackedParameter<bool>("online",false);
   mergeRuns_             = ps.getUntrackedParameter<bool>("mergeRuns",false);
   enableCleanup_         = ps.getUntrackedParameter<bool>("enableCleanup",false);
   debug_                 = ps.getUntrackedParameter<int>("debug",0);
   prefixME_              = ps.getUntrackedParameter<std::string>("subSystemFolder","Hcal/");
   if(prefixME_.substr(prefixME_.size()-1,prefixME_.size())!="/")
      prefixME_.append("/");
   subdir_                = ps.getUntrackedParameter<std::string>("TaskFolder","NoiseMonitor_Hcal");
   if(subdir_.size()>0 && subdir_.substr(subdir_.size()-1,subdir_.size())!="/")
      subdir_.append("/");
   subdir_=prefixME_+subdir_;
   AllowedCalibTypes_     = ps.getUntrackedParameter<std::vector<int> > ("AllowedCalibTypes");
   skipOutOfOrderLS_      = ps.getUntrackedParameter<bool>("skipOutOfOrderLS",false);
   NLumiBlocks_           = ps.getUntrackedParameter<int>("NLumiBlocks",4000);
   makeDiagnostics_       = ps.getUntrackedParameter<bool>("makeDiagnostics",false);

   triggers_=ps.getUntrackedParameter<std::vector<std::string> >("nzsHLTnames");
      //["HLT_HcalPhiSym","HLT_HcalNoise_8E29]
   period_=ps.getUntrackedParameter<int>("NoiseeventPeriod",4096); //4096
   rawdataLabel_          = ps.getUntrackedParameter<edm::InputTag>("RawDataLabel");
   hltresultsLabel_       = ps.getUntrackedParameter<edm::InputTag>("HLTResultsLabel");
   hbheDigiLabel_         = ps.getUntrackedParameter<edm::InputTag>("hbheDigiLabel");
   hbheRechitLabel_       = ps.getUntrackedParameter<edm::InputTag>("hbheRechitLabel");
   noiseLabel_            = ps.getUntrackedParameter<edm::InputTag>("noiseLabel");

   mTrianglePeakTS        = 4;   // for now...

   mE2E10MinEnergy        = ps.getUntrackedParameter<double>("E2E10MinEnergy");
   mMinE2E10              = ps.getUntrackedParameter<double>("MinE2E10");
   mMaxE2E10              = ps.getUntrackedParameter<double>("MaxE2E10");
   mMaxHPDHitCount        = ps.getUntrackedParameter<int>("MaxHPDHitCount");
   mMaxHPDNoOtherHitCount = ps.getUntrackedParameter<int>("MaxHPDNoOtherHitCount");
   mMaxADCZeros           = ps.getUntrackedParameter<int>("MaxADCZeros");
   mTotalZeroMinEnergy    = ps.getUntrackedParameter<double>("TotalZeroMinEnergy");
}
HcalNoiseMonitor::~HcalNoiseMonitor ( )

Definition at line 66 of file HcalNoiseMonitor.cc.

{}

Member Function Documentation

void HcalNoiseMonitor::analyze ( edm::Event const &  e,
edm::EventSetup const &  s 
) [virtual]

Reimplemented from HcalBaseDQMonitor.

Definition at line 207 of file HcalNoiseMonitor.cc.

References HcalCoderDb::adc2fC(), reco::HcalNoiseRBX::allChargeHighest2TS(), reco::HcalNoiseRBX::allChargeTotal(), reco::HcalNoiseHPD::big5ChargeHighest2TS(), reco::HcalNoiseHPD::big5ChargeTotal(), reco::HcalNoiseHPD::bigChargeHighest2TS(), reco::HcalNoiseHPD::bigChargeTotal(), CalculateRMS8Max(), gather_cfg::cout, HcalBaseDQMonitor::dbe_, HcalBaseDQMonitor::debug_, EtaPhiHists::depth, alignCSCRings::e, MonitorElement::Fill(), edm::EventSetup::get(), edm::Event::getByLabel(), hBadCountHPD, hBadE2E10RBX, hBadNoOtherCountHPD, hBadZeroRBX, hbheDigiLabel_, HcalCaloFlagLabels::HBHEFlatNoise, HcalCaloFlagLabels::HBHEIsolatedNoise, hbheRechitLabel_, HcalCaloFlagLabels::HBHESpikeNoise, HcalCaloFlagLabels::HBHETriangleNoise, hE2OverE10Digi, hE2OverE10Digi5, hE2OverE10RBX, hFailIsolationEtaPhi, hFailLinearEtaPhi, hFailRMSMaxEtaPhi, hFailTriangleEtaPhi, hHcalNoiseCategory, hHPDHitCount, hLambdaLinearVsTotalCharge, hLambdaRMS8MaxVsTotalCharge, hLinearChi2, hLinearTestStatistics, hMaxZeros, hNominalChi2, reco::HcalNoiseRBX::HPDs(), hRBXHitCount, hRMS8OverMax, hRMS8OverMaxTestStatistics, hTotalZeros, hTriangleLeftSlopeVsTS4, hTriangleRightSlopeVsTS4, hTS4TS5RelativeDifference, hTS4TS5RelativeDifferenceVsCharge, i, reco::HcalNoiseHPD::idnumber(), reco::HcalNoiseRBX::idnumber(), HcalDetId::ieta(), TriangleFitResult::LeftSlope, create_public_lumi_plots::log, reco::HcalNoiseRBX::maxZeros(), mE2E10MinEnergy, mMaxADCZeros, mMaxE2E10, mMaxHPDHitCount, mMaxHPDNoOtherHitCount, mMinE2E10, mTotalZeroMinEnergy, noiseLabel_, NULL, reco::HcalNoiseRBX::numRecHits(), reco::HcalNoiseHPD::numRecHits(), HcalCalibrations::pedestal(), PerformLinearFit(), PerformNominalFit(), PerformTriangleFit(), reco::HcalNoiseHPD::recHitEnergy(), reco::HcalNoiseRBX::recHitEnergy(), TriangleFitResult::RightSlope, and reco::HcalNoiseRBX::totalZeros().

{
   edm::Handle<HBHEDigiCollection> hHBHEDigis;
   iEvent.getByLabel(edm::InputTag(hbheDigiLabel_),hHBHEDigis);

   edm::ESHandle<HcalDbService> hConditions;
   iSetup.get<HcalDbRecord>().get(hConditions);

   edm::Handle<HBHERecHitCollection> hRecHits;
   iEvent.getByLabel(edm::InputTag(hbheRechitLabel_), hRecHits);

   edm::Handle<reco::HcalNoiseRBXCollection> hRBXCollection;
   iEvent.getByLabel(edm::InputTag(noiseLabel_),hRBXCollection);

   HcalBaseDQMonitor::analyze(iEvent, iSetup);

   if(dbe_ == NULL)
   {
      if(debug_ > 0)
         std::cout << "HcalNoiseMonitor::processEvent DQMStore not instantiated!!!"<< std::endl;
      return;
   }

   // loop over digis
   for(HBHEDigiCollection::const_iterator iter = hHBHEDigis->begin(); iter != hHBHEDigis->end(); iter++)
   {
      HcalDetId id = iter->id();
      const HcalCalibrations &Calibrations = hConditions->getHcalCalibrations(id);
      const HcalQIECoder *ChannelCoder = hConditions->getHcalCoder(id);
      const HcalQIEShape *Shape = hConditions->getHcalShape();
      HcalCoderDb Coder(*ChannelCoder, *Shape);
      CaloSamples Tool;
      Coder.adc2fC(*iter, Tool);

      // int ieta = id.ieta();
      // int iphi = id.iphi();
      // int depth = id.depth();

      double Charge[10] = {0};
      for(int i = 0; i < iter->size(); i++)
         Charge[i] = Tool[i] - Calibrations.pedestal(iter->sample(i).capid());

      double TotalCharge = 0;
      for(int i = 0; i < 10; i++)
         TotalCharge = TotalCharge + Charge[i];

      if(TotalCharge > 20)
      {
         double NominalChi2 = 10000000;
         NominalChi2 = PerformNominalFit(Charge);
         
         double LinearChi2 = PerformLinearFit(Charge);
         double RMS8Max = CalculateRMS8Max(Charge);
         TriangleFitResult TriangleResult = PerformTriangleFit(Charge);
      
         double TS4LeftSlope = 100000;
         double TS4RightSlope = 100000;
         
         if(TriangleResult.LeftSlope > 1e-5)
            TS4LeftSlope = Charge[4] / fabs(TriangleResult.LeftSlope);
         if(TriangleResult.RightSlope < -1e-5)
            TS4RightSlope = Charge[4] / fabs(TriangleResult.RightSlope);

         if(TS4LeftSlope < -1000 || TS4LeftSlope > 1000)
            TS4LeftSlope = 1000;
         if(TS4RightSlope < -1000 || TS4RightSlope > 1000)
            TS4RightSlope = 1000;

         hNominalChi2->Fill(NominalChi2);
         hLinearChi2->Fill(LinearChi2);
         hLinearTestStatistics->Fill(log(LinearChi2) - log(NominalChi2));
         hRMS8OverMax->Fill(RMS8Max);
         hRMS8OverMaxTestStatistics->Fill(log(RMS8Max) - log(NominalChi2));

         hLambdaLinearVsTotalCharge->Fill(log(LinearChi2) - log(NominalChi2), TotalCharge);
         hLambdaRMS8MaxVsTotalCharge->Fill(log(RMS8Max) - log(NominalChi2), TotalCharge);
         hTriangleLeftSlopeVsTS4->Fill(TS4LeftSlope, Charge[4]);
         hTriangleRightSlopeVsTS4->Fill(TS4RightSlope, Charge[4]);
      }

      if(Charge[4] + Charge[5] > 1e-5)
      {
         hTS4TS5RelativeDifference->Fill((Charge[4] - Charge[5]) / (Charge[4] + Charge[5]));
         hTS4TS5RelativeDifferenceVsCharge->Fill(TotalCharge, (Charge[4] - Charge[5]) / (Charge[4] + Charge[5]));
      }
   }

   // loop over rechits - noise bits (fit-based, isolation)
   for(HBHERecHitCollection::const_iterator iter = hRecHits->begin(); iter != hRecHits->end(); iter++)
   {
      HcalDetId id = iter->id();

      int ieta = id.ieta();
      int iphi = id.iphi();
      int depth = id.depth();

      if(iter->flagField(HcalCaloFlagLabels::HBHEFlatNoise) == 1)
         hFailLinearEtaPhi.depth[depth-1]->Fill(ieta, iphi);

      if(iter->flagField(HcalCaloFlagLabels::HBHESpikeNoise) == 1)
         hFailRMSMaxEtaPhi.depth[depth-1]->Fill(ieta, iphi);
      
      if(iter->flagField(HcalCaloFlagLabels::HBHETriangleNoise) == 1)
         hFailTriangleEtaPhi.depth[depth-1]->Fill(ieta, iphi);

      if(iter->flagField(HcalCaloFlagLabels::HBHEIsolatedNoise) == 1)
         hFailIsolationEtaPhi.depth[depth-1]->Fill(ieta, iphi);
   }

   // Code analagous to Yifei's
   for(reco::HcalNoiseRBXCollection::const_iterator rbx = hRBXCollection->begin();
      rbx != hRBXCollection->end(); rbx++)
   {
      const reco::HcalNoiseRBX RBX = *rbx;

      int NumberRBXHits = RBX.numRecHits(1.5);
      double RBXEnergy = RBX.recHitEnergy(1.5);
      double RBXE2 = RBX.allChargeHighest2TS();
      double RBXE10 = RBX.allChargeTotal();

      std::vector<reco::HcalNoiseHPD> HPDs = RBX.HPDs();
      
      int RBXID = RBX.idnumber();

      if(RBXEnergy > mTotalZeroMinEnergy && RBX.totalZeros() >= mMaxADCZeros)
         hBadZeroRBX->Fill(RBXID);
      if(RBXEnergy > mE2E10MinEnergy && RBXE10 > 1e-5 && (RBXE2 / RBXE10 > mMaxE2E10 || RBXE2 / RBXE10 < mMinE2E10))
         hBadE2E10RBX->Fill(RBXID);
      for(std::vector<reco::HcalNoiseHPD>::const_iterator hpd = HPDs.begin(); hpd != HPDs.end(); hpd++)
      {
         reco::HcalNoiseHPD HPD = *hpd;
         int HPDHitCount = HPD.numRecHits(1.5);
         if(HPDHitCount >= mMaxHPDHitCount)
            hBadCountHPD->Fill(HPD.idnumber());
         if(HPDHitCount == NumberRBXHits && HPDHitCount >= mMaxHPDNoOtherHitCount)
            hBadNoOtherCountHPD->Fill(HPD.idnumber());
      }
      
      if(NumberRBXHits == 0 || RBXEnergy <= 10)
         continue;

      hRBXHitCount->Fill(NumberRBXHits);

      hMaxZeros->Fill(RBX.maxZeros());
      hTotalZeros->Fill(RBX.totalZeros());
   
      double HighestHPDEnergy = 0;
      int HighestHPDHits = 0;

      for(std::vector<reco::HcalNoiseHPD>::const_iterator hpd = HPDs.begin(); hpd != HPDs.end(); hpd++)
      {
         reco::HcalNoiseHPD HPD = *hpd;

         if(HPD.recHitEnergy(1.5) > HighestHPDEnergy)
         {
            HighestHPDEnergy = HPD.recHitEnergy(1.5);
            HighestHPDHits = HPD.numRecHits(1.5);
         }

         if(HPD.numRecHits(5) < 1)
            continue;

         if(HPD.bigChargeTotal() > 1e-5)
            hE2OverE10Digi->Fill(HPD.bigChargeHighest2TS() / HPD.bigChargeTotal());
         if(HPD.big5ChargeTotal() > 1e-5)
            hE2OverE10Digi5->Fill(HPD.big5ChargeHighest2TS() / HPD.big5ChargeTotal());

         hHPDHitCount->Fill(HPD.numRecHits(1.5));
      }

      int NoiseCategory = 0;
      bool IsRBXNoise = false;
      //      bool IsHPDNoise = false;
      //      bool IsHPDIonFeedback = false;
      //      bool IsHPDDischarge = false;

      if(RBXEnergy > 1e-5 && HighestHPDEnergy / RBXEnergy > 0.98)
      {
        //         IsHPDNoise = true;

         if(HighestHPDHits >= 9)
         {
           //            IsHPDDischarge = true;
            NoiseCategory = 7;
         }
         else
         {
           //            IsHPDIonFeedback = true;
            NoiseCategory = 8;
         }
      }
      else
      {
         IsRBXNoise = true;
         NoiseCategory = 1;

         if(RBXE10 > 1e-5)
         {
            if(RBXE2 / RBXE10 < 0.33)
               NoiseCategory = 2;
            else if(RBXE2 / RBXE10 < 0.8)
               NoiseCategory = 3;
            else if(RBXE2 / RBXE10 > 0.8 && NumberRBXHits > 10)
               NoiseCategory = 4;
            else if(RBXE2 / RBXE10 > 0.8 && NumberRBXHits < 10)  // [hic]
               NoiseCategory = 5;
         }
      }

      hHcalNoiseCategory->Fill(NoiseCategory);

      if(IsRBXNoise == true && RBXE10 > 1e-5)
         hE2OverE10RBX->Fill(RBXE2 / RBXE10);
   }

   return;
}
void HcalNoiseMonitor::beginRun ( const edm::Run run,
const edm::EventSetup c 
) [virtual]

Reimplemented from HcalBaseDQMonitor.

Definition at line 81 of file HcalNoiseMonitor.cc.

References gather_cfg::cout, HcalBaseDQMonitor::debug_, HcalBaseDQMonitor::mergeRuns_, reset(), setup(), and HcalBaseDQMonitor::tevt_.

{
   if(debug_ > 1)
      std::cout <<"HcalNoiseMonitor::beginRun"<< std::endl;

   HcalBaseDQMonitor::beginRun(run,c);

   if(tevt_ == 0)
      setup();

   if(mergeRuns_ == false)
      reset();

   return;
}
double HcalNoiseMonitor::CalculateRMS8Max ( double  Charge[10]) [private]

Definition at line 687 of file HcalNoiseMonitor.cc.

References alignCSCRings::e, i, python::multivaluedict::sort(), and mathSSE::sqrt().

Referenced by analyze().

{
   //
   // CalculateRMS8Max
   //
   // returns "RMS" divided by the largest charge in the time slices
   //    "RMS" is calculated using all but the two largest time slices.
   //    The "RMS" is not quite the actual RMS (see note below), but the value is only
   //    used for determining max values, and is not quoted as the actual RMS anywhere.
   //

   int DigiSize = 10;

   // Copy Charge vector again, since we are passing references around
   std::vector<double> TempCharge(Charge, Charge + 10);

   // Sort TempCharge vector from smallest to largest charge
   sort(TempCharge.begin(), TempCharge.end());

   double Total = 0;
   double Total2 = 0;
   for(int i = 0; i < DigiSize - 2; i++)
   {
      Total = Total + TempCharge[i];
      Total2 = Total2 + TempCharge[i] * TempCharge[i];
   }

   // This isn't quite the RMS (both Total2 and Total*Total need to be
   // divided by an extra (DigiSize-2) within the sqrt to get the RMS.)
   // We're only using this value for relative comparisons, though; we
   // aren't explicitly interpreting it as the RMS.  It might be nice
   // to either change the calculation or rename the variable in the future, though.

   double RMS = sqrt(Total2 - Total * Total / (DigiSize - 2));

   double RMS8Max = 99999;
   if(TempCharge[DigiSize-1] > 1e-5)
      RMS8Max = RMS / TempCharge[DigiSize-1];
   if(RMS8Max < 1e-5)   // protection against zero
      RMS8Max = 1e-5;

   return RMS8Max;
}
void HcalNoiseMonitor::cleanup ( void  ) [virtual]
double HcalNoiseMonitor::DualNominalFitSingleTry ( double  Charge[10],
int  Offset,
int  Distance 
) [private]

Definition at line 539 of file HcalNoiseMonitor.cc.

References CumulativeIdealPulse, alignCSCRings::e, and j.

Referenced by PerformDualNominalFit().

{
   //
   // Does a fit to dual signal pulse hypothesis given offset and distance of the two target pulses
   //
   // The only parameters to fit here are the two pulse heights of in-time and out-of-time components
   //    since offset is given
   // The calculation here is based from writing down the Chi2 formula and minimize against the two parameters,
   //    ie., Chi2 = Sum{((T[i] - a1 * F1[i] - a2 * F2[i]) / (Sigma[i]))^2}, where T[i] is the input pulse shape,
   //    and F1[i], F2[i] are the two ideal pulse components
   //

   int DigiSize = 10;

   if(Offset < 0 || Offset + 250 >= (int)CumulativeIdealPulse.size())
      return 1000000;
   if(CumulativeIdealPulse[Offset+250] - CumulativeIdealPulse[Offset] < 1e-5)
      return 1000000;

   static std::vector<double> F1;
   static std::vector<double> F2;

   F1.resize(DigiSize);
   F2.resize(DigiSize);

   double SumF1F1 = 0;
   double SumF1F2 = 0;
   double SumF2F2 = 0;
   double SumTF1 = 0;
   double SumTF2 = 0;

   double Error = 0;

   for(int j = 0; j < DigiSize; j++)
   {
      // this is the TS value for in-time component - no problem we can do a subtraction directly
      F1[j] = CumulativeIdealPulse[Offset+j*25+25] - CumulativeIdealPulse[Offset+j*25];

      // However for the out-of-time component the index might go out-of-bound.
      // Let's protect against this.

      int OffsetTemp = Offset + j * 25 + Distance;
      
      double C1 = 0;   // lower-indexed value in the cumulative pulse shape
      double C2 = 0;   // higher-indexed value in the cumulative pulse shape
      
      if(OffsetTemp + 25 < (int)CumulativeIdealPulse.size() && OffsetTemp + 25 >= 0)
         C1 = CumulativeIdealPulse[OffsetTemp+25];
      if(OffsetTemp + 25 >= (int)CumulativeIdealPulse.size())
         C1 = CumulativeIdealPulse[CumulativeIdealPulse.size()-1];
      if(OffsetTemp < (int)CumulativeIdealPulse.size() && OffsetTemp >= 0)
         C2 = CumulativeIdealPulse[OffsetTemp];
      if(OffsetTemp >= (int)CumulativeIdealPulse.size())
         C2 = CumulativeIdealPulse[CumulativeIdealPulse.size()-1];
      F2[j] = C1 - C2;

      Error = Charge[j];
      if(Error < 1)
         Error = 1;

      SumF1F1 += F1[j] * F1[j] / Error;
      SumF1F2 += F1[j] * F2[j] / Error; 
      SumF2F2 += F2[j] * F2[j] / Error;
      SumTF1  += F1[j] * Charge[j] / Error; 
      SumTF2  += F2[j] * Charge[j] / Error; 
   }

   double Height = (SumF1F2 * SumTF2 - SumF2F2 * SumTF1) / (SumF1F2 * SumF1F2 - SumF1F1 * SumF2F2);
   double Height2 = (SumF1F2 * SumTF1 - SumF1F1 * SumTF2) / (SumF1F2 * SumF1F2 - SumF1F1 * SumF2F2);

   double Chi2 = 0;
   for(int j = 0; j < DigiSize; j++)
   {
      double Error = Charge[j];
      if(Error < 1)
         Error = 1;

      double Residual = Height * F1[j] + Height2 * F2[j] - Charge[j];  
      Chi2 += Residual * Residual / Error;                             
   } 

   // Safety protection in case of zero
   if(Chi2 < 1e-5)
      Chi2 = 1e-5;

   return Chi2;
}
double HcalNoiseMonitor::PerformDualNominalFit ( double  Charge[10]) [private]

Definition at line 491 of file HcalNoiseMonitor.cc.

References CumulativeIdealPulse, DualNominalFitSingleTry(), i, and gen::k.

{
   //
   // Perform dual nominal fit and returns the chi2
   //
   // In this function we do a scan over possible "distance" (number of time slices between two components)
   //    and overall offset for the two components; first coarse, then finer
   // All the fitting is done in the DualNominalFitSingleTry function
   //                  
   
   double OverallMinimumChi2 = 1000000;

   int AvailableDistance[] = {-100, -75, -50, 50, 75, 100};

   // loop over possible pulse distances between two components
   for(int k = 0; k < 6; k++)
   {
      double SingleMinimumChi2 = 1000000;
      int MinOffset = 0;

      // scan coarsely through different offsets and find the minimum
      for(int i = 0; i + 250 < (int)CumulativeIdealPulse.size(); i += 10)
      {
         double Chi2 = DualNominalFitSingleTry(Charge, i, AvailableDistance[k]);

         if(Chi2 < SingleMinimumChi2)
         {
            SingleMinimumChi2 = Chi2;
            MinOffset = i;
         }
      }

      // around the minimum, scan finer for better a better minimum
      for(int i = MinOffset - 15; i + 250 < (int)CumulativeIdealPulse.size() && i < MinOffset + 15; i++)
      {
         double Chi2 = DualNominalFitSingleTry(Charge, i, AvailableDistance[k]);
         if(Chi2 < SingleMinimumChi2)
            SingleMinimumChi2 = Chi2;
      }

      // update overall minimum chi2
      if(SingleMinimumChi2 < OverallMinimumChi2)
         OverallMinimumChi2 = SingleMinimumChi2;
   }

   return OverallMinimumChi2;
}
double HcalNoiseMonitor::PerformLinearFit ( double  Charge[10]) [private]

Definition at line 627 of file HcalNoiseMonitor.cc.

References alignCSCRings::e, and i.

Referenced by analyze().

{
   //
   // Performs a straight-line fit over all time slices, and returns the chi2 value
   //
   // The calculation here is based from writing down the formula for chi2 and minimize
   //    with respect to the parameters in the fit, ie., slope and intercept of the straight line
   // By doing two differentiation, we will get two equations, and the best parameters are determined by these
   //

   int DigiSize = 10;

   double SumTS2OverTi = 0;
   double SumTSOverTi = 0;
   double SumOverTi = 0;
   double SumTiTS = 0;
   double SumTi = 0;

   double Error2 = 0;
   for(int i = 0; i < DigiSize; i++)
   {
      Error2 = Charge[i];
      if(Charge[i] < 1)
         Error2 = 1;

      SumTS2OverTi += 1.* i * i / Error2;
      SumTSOverTi  += 1.* i / Error2;
      SumOverTi    += 1. / Error2;
      SumTiTS      += Charge[i] * i / Error2;
      SumTi        += Charge[i] / Error2;
   }

   double CM1 = SumTS2OverTi;   // Coefficient in front of slope in equation 1
   double CM2 = SumTSOverTi;   // Coefficient in front of slope in equation 2
   double CD1 = SumTSOverTi;   // Coefficient in front of intercept in equation 1
   double CD2 = SumOverTi;   // Coefficient in front of intercept in equation 2
   double C1 = SumTiTS;   // Constant coefficient in equation 1
   double C2 = SumTi;   // Constant coefficient in equation 2

   double Slope = (C1 * CD2 - C2 * CD1) / (CM1 * CD2 - CM2 * CD1);
   double Intercept = (C1 * CM2 - C2 * CM1) / (CD1 * CM2 - CD2 * CM1);

   // now that the best parameters are found, calculate chi2 from those
   double Chi2 = 0;
   for(int i = 0; i < DigiSize; i++)
   {
      double Deviation = Slope * i + Intercept - Charge[i];
      double Error2 = Charge[i];
      if(Charge[i] < 1)
         Error2 = 1;
      Chi2 += Deviation * Deviation / Error2;  
   }

   // safety protection in case of perfect fit
   if(Chi2 < 1e-5)
      Chi2 = 1e-5;

   return Chi2;
}
double HcalNoiseMonitor::PerformNominalFit ( double  Charge[10]) [private]

Definition at line 425 of file HcalNoiseMonitor.cc.

References CumulativeIdealPulse, alignCSCRings::e, F(), i, and j.

Referenced by analyze().

{
   //
   // Performs a fit to the ideal pulse shape.  Returns best chi2
   //
   // A scan over different timing offset (for the ideal pulse) is carried out,
   //    and for each offset setting a one-parameter fit is performed
   //

   int DigiSize = 10;

   double MinimumChi2 = 100000;

   double F = 0;

   double SumF2 = 0;
   double SumTF = 0;
   double SumT2 = 0;

   for(int i = 0; i + 250 < (int)CumulativeIdealPulse.size(); i++)
   {
      if(CumulativeIdealPulse[i+250] - CumulativeIdealPulse[i] < 1e-5)
         continue;

      SumF2 = 0;
      SumTF = 0;
      SumT2 = 0;

      for(int j = 0; j < DigiSize; j++)
      {
         // get ideal pulse component for this time slice....
         F = CumulativeIdealPulse[i+j*25+25] - CumulativeIdealPulse[i+j*25];

         double Error2 = Charge[j];
         if(Error2 < 1)
            Error2 = 1;

         // ...and increment various summations
         SumF2 += F * F / Error2;
         SumTF += F * Charge[j] / Error2;
         SumT2 += Charge[j] * Charge[j] / Error2;
      }

      /* chi2= sum((Charge[j]-aF)^2/|Charge[j]|
         ( |Charge[j]| = assumed sigma^2 for Charge[j]; a bit wonky for Charge[j]<1 )
         chi2 = sum(|Charge[j]|) - 2*sum(aF*Charge[j]/|Charge[j]|) +sum( a^2*F^2/|Charge[j]|)
         chi2 minimimized when d(chi2)/da = 0:
         a = sum(F*Charge[j])/sum(F^2)
         ...
         chi2= sum(|Q[j]|) - sum(Q[j]/|Q[j]|*F)*sum(Q[j]/|Q[j]|*F)/sum(F^2/|Q[j]|), where Q = Charge
         chi2 = SumT2 - SumTF*SumTF/SumF2
      */
      
      double Chi2 = SumT2 - SumTF * SumTF / SumF2;

      if(Chi2 < MinimumChi2)
         MinimumChi2 = Chi2;
   }

   // safety protection in case of perfect fit - don't want the log(...) to explode
   if(MinimumChi2 < 1e-5)
      MinimumChi2 = 1e-5;

   return MinimumChi2;
}
TriangleFitResult HcalNoiseMonitor::PerformTriangleFit ( double  Charge[10]) [private]

Definition at line 731 of file HcalNoiseMonitor.cc.

References TriangleFitResult::Chi2, i, TriangleFitResult::LeftSlope, mTrianglePeakTS, query::result, and TriangleFitResult::RightSlope.

Referenced by analyze().

{
   //
   // Perform a "triangle fit", and extract the slopes
   //
   // Left-hand side and right-hand side are not correlated to each other - do them separately
   //

   TriangleFitResult result;
   result.Chi2 = 0;
   result.LeftSlope = 0;
   result.RightSlope = 0;

   int DigiSize = 10;

   // right side, starting from TS4
   double MinimumRightChi2 = 1000000;
   double Numerator = 0;
   double Denominator = 0;

   for(int iTS = mTrianglePeakTS + 2; iTS <= DigiSize; iTS++)   // the place where first TS center in flat line
   {
      // fit a straight line to the triangle part
      Numerator = 0;
      Denominator = 0;

      for(int i = mTrianglePeakTS + 1; i < iTS; i++)
      {
         Numerator += (i - mTrianglePeakTS) * (Charge[i] - Charge[mTrianglePeakTS]);
         Denominator += (i - mTrianglePeakTS) * (i - mTrianglePeakTS);
      }

      double BestSlope = Numerator / Denominator;
      if(BestSlope > 0)
         BestSlope = 0;

      // check if the slope is reasonable
      if(iTS != DigiSize)
      {
         if(BestSlope > -1 * Charge[mTrianglePeakTS] / (iTS - mTrianglePeakTS))
            BestSlope = -1 * Charge[mTrianglePeakTS] / (iTS - mTrianglePeakTS);
         if(BestSlope < -1 * Charge[mTrianglePeakTS] / (iTS - 1 - mTrianglePeakTS))
            BestSlope = -1 * Charge[mTrianglePeakTS] / (iTS - 1 - mTrianglePeakTS);
      }
      else
      {
         if(BestSlope < -1 * Charge[mTrianglePeakTS] / (iTS - 1 - mTrianglePeakTS)) 
            BestSlope = -1 * Charge[mTrianglePeakTS] / (iTS - 1 - mTrianglePeakTS);
      }

      // calculate partial chi2

      // The shape I'm fitting is more like a tent than a triangle.
      // After the end of triangle edge assume a flat line

      double Chi2 = 0;
      for(int i = mTrianglePeakTS + 1; i < iTS; i++)
         Chi2 += (Charge[mTrianglePeakTS] - Charge[i] + (i - mTrianglePeakTS) * BestSlope)
            * (Charge[mTrianglePeakTS] - Charge[i] + (i - mTrianglePeakTS) * BestSlope);
      for(int i = iTS; i < DigiSize; i++)    // Assumes fit line = 0 for iTS > fit
         Chi2 += Charge[i] * Charge[i];

      if(Chi2 < MinimumRightChi2)
      {
         MinimumRightChi2 = Chi2;
         result.RightSlope = BestSlope;
      }
   }   // end of right-hand side loop

   // left side
   double MinimumLeftChi2 = 1000000;

   for(int iTS = 0; iTS < (int)mTrianglePeakTS; iTS++)   // the first time after linear fit ends
   {
      // fit a straight line to the triangle part
      Numerator = 0;
      Denominator = 0;
      for(int i = iTS; i < (int)mTrianglePeakTS; i++)
      {
         Numerator = Numerator + (i - mTrianglePeakTS) * (Charge[i] - Charge[mTrianglePeakTS]);
         Denominator = Denominator + (i - mTrianglePeakTS) * (i - mTrianglePeakTS);
      }

      double BestSlope = Numerator / Denominator;
      if(BestSlope < 0)
         BestSlope = 0;

      // check slope
      if(iTS != 0)
      {
         if(BestSlope > Charge[mTrianglePeakTS] / (mTrianglePeakTS - iTS))
            BestSlope = Charge[mTrianglePeakTS] / (mTrianglePeakTS - iTS);
         if(BestSlope < Charge[mTrianglePeakTS] / (mTrianglePeakTS + 1 - iTS))
            BestSlope = Charge[mTrianglePeakTS] / (mTrianglePeakTS + 1 - iTS);
      }
      else
      {
         if(BestSlope > Charge[mTrianglePeakTS] / (mTrianglePeakTS - iTS))
            BestSlope = Charge[mTrianglePeakTS] / (mTrianglePeakTS - iTS);
      }

      // calculate minimum chi2
      double Chi2 = 0;
      for(int i = 0; i < iTS; i++)
         Chi2 += Charge[i] * Charge[i];
      for(int i = iTS; i < (int)mTrianglePeakTS; i++)
         Chi2 += (Charge[mTrianglePeakTS] - Charge[i] + (i - mTrianglePeakTS) * BestSlope)
            * (Charge[mTrianglePeakTS] - Charge[i] + (i - mTrianglePeakTS) * BestSlope);

      if(MinimumLeftChi2 > Chi2)
      {
         MinimumLeftChi2 = Chi2;
         result.LeftSlope = BestSlope;
      }
   }   // end of left-hand side loop

   result.Chi2 = MinimumLeftChi2 + MinimumRightChi2;

   return result;
}
void HcalNoiseMonitor::ReadHcalPulse ( ) [private]

Definition at line 852 of file HcalNoiseMonitor.cc.

References HcalPulseShape::at(), CumulativeIdealPulse, HcalPulseShapes::hbShape(), and i.

Referenced by setup().

{
   std::vector<double> PulseShape;

   HcalPulseShapes Shapes;
   HcalPulseShapes::Shape HPDShape = Shapes.hbShape();

   PulseShape.reserve(350);
   for(int i = 0; i < 200; i++)
      PulseShape.push_back(HPDShape.at(i));
   PulseShape.insert(PulseShape.begin(), 150, 0);   // Safety margin of a lot of zeros in the beginning

   CumulativeIdealPulse.reserve(350);
   CumulativeIdealPulse.clear();
   CumulativeIdealPulse.push_back(0);
   for(unsigned int i = 1; i < PulseShape.size(); i++)
      CumulativeIdealPulse.push_back(CumulativeIdealPulse[i-1] + PulseShape[i]);
}
void HcalNoiseMonitor::reset ( void  ) [virtual]

Reimplemented from HcalBaseDQMonitor.

Definition at line 68 of file HcalNoiseMonitor.cc.

Referenced by beginRun().

{
}
void HcalNoiseMonitor::setup ( void  ) [virtual]

Reimplemented from HcalBaseDQMonitor.

Definition at line 98 of file HcalNoiseMonitor.cc.

References DQMStore::book1D(), DQMStore::book2D(), gather_cfg::cout, HcalBaseDQMonitor::dbe_, HcalBaseDQMonitor::debug_, hBadCountHPD, hBadE2E10RBX, hBadNoOtherCountHPD, hBadZeroRBX, hE2OverE10Digi, hE2OverE10Digi5, hE2OverE10RBX, hFailIsolationEtaPhi, hFailLinearEtaPhi, hFailRMSMaxEtaPhi, hFailTriangleEtaPhi, hHcalNoiseCategory, hHPDHitCount, hLambdaLinearVsTotalCharge, hLambdaRMS8MaxVsTotalCharge, hLinearChi2, hLinearTestStatistics, hMaxZeros, hNominalChi2, hRBXHitCount, hRMS8OverMax, hRMS8OverMaxTestStatistics, hTotalZeros, hTriangleLeftSlopeVsTS4, hTriangleRightSlopeVsTS4, hTS4TS5RelativeDifference, hTS4TS5RelativeDifferenceVsCharge, ReadHcalPulse(), MonitorElement::setAxisTitle(), MonitorElement::setBinLabel(), DQMStore::setCurrentFolder(), HcalBaseDQMonitor::SetupEtaPhiHists(), and HcalBaseDQMonitor::subdir_.

Referenced by beginRun().

{
   HcalBaseDQMonitor::setup();

   if(debug_ > 1)
      std::cout << "<HcalNoiseMonitor::setup> Creating histograms" << std::endl;

   if(dbe_)
   {
      dbe_->setCurrentFolder(subdir_);

      // Fit-based
      dbe_->setCurrentFolder(subdir_ + "DoubleChi2/");

      hNominalChi2 = dbe_->book1D("Nominal_fit_chi2", "Nominal fit chi2, total charge > 20 fC", 100, 0, 200);
      hNominalChi2->setAxisTitle("Nominal fit #chi^{2}", 1);

      hLinearChi2 = dbe_->book1D("Linear_fit_chi2", "Linear fit chi2, total charge > 20 fC", 100, 0, 200);
      hLinearChi2->setAxisTitle("Linear fit #chi^{2}", 1);
      
      hLinearTestStatistics = dbe_->book1D("Lambda_linear", "#Lambda_{linear}, total charge > 20 fC", 100, -10, 10);
      hLinearTestStatistics->setAxisTitle("#Lambda_{linear}", 1);

      hRMS8OverMax = dbe_->book1D("RMS8_over_Max", "RMS8/max, total charge > 20 fC", 100, 0, 2);
      hRMS8OverMax->setAxisTitle("RMS8/max", 1);

      hRMS8OverMaxTestStatistics = dbe_->book1D("Lambda_RMS8_over_max", "#Lambda_{RMS8/Max}, total charge > 20 fC",
         100, -30, 10);
      hRMS8OverMaxTestStatistics->setAxisTitle("#Lambda_{RMS8/Max}", 1);

      hLambdaLinearVsTotalCharge = dbe_->book2D("Lambda_linear_vs_total_charge", "#Lambda_{Linear}",
         50, -5, 5, 25, 0, 500);
      hLambdaLinearVsTotalCharge->setAxisTitle("#Lambda_{linear}", 1);
      hLambdaLinearVsTotalCharge->setAxisTitle("Total charge", 2);

      hLambdaRMS8MaxVsTotalCharge = dbe_->book2D("Lambda_RMS8Max_vs_total_charge", "#Lambda_{RMS8/Max}",
         50, -15, 5, 25, 0, 500);
      hLambdaRMS8MaxVsTotalCharge->setAxisTitle("#Lambda_{RMS8/Max}", 1);
      hLambdaRMS8MaxVsTotalCharge->setAxisTitle("Total charge", 2);

      hTriangleLeftSlopeVsTS4 = dbe_->book2D("Triangle_fit_left_slope",
         "Triangle fit left distance vs. TS4", 50, 0, 10, 25, 0, 500);
      hTriangleLeftSlopeVsTS4->setAxisTitle("Left slope", 1);
      hTriangleLeftSlopeVsTS4->setAxisTitle("Peak time slice", 2);

      hTriangleRightSlopeVsTS4 = dbe_->book2D("Triangle_fit_right_slope",
         "Triangle fit right distance vs. peak time slice", 50, 0, 10, 25, 0, 500);
      hTriangleRightSlopeVsTS4->setAxisTitle("Left slope", 1);
      hTriangleRightSlopeVsTS4->setAxisTitle("Peak time slice", 2);

      SetupEtaPhiHists(hFailLinearEtaPhi, "Fail_linear_Eta_Phi_Map", "");
      SetupEtaPhiHists(hFailRMSMaxEtaPhi, "Fail_RMS8Max_Eta_Phi_Map", "");
      SetupEtaPhiHists(hFailTriangleEtaPhi, "Fail_triangle_Eta_Phi_Map", "");

      // High-level isolation filter
      dbe_->setCurrentFolder(subdir_ + "IsolationVariable/");

      SetupEtaPhiHists(hFailIsolationEtaPhi, "Fail_isolation_Eta_Phi_Map", "");
      
      // TS4 vs. TS5 variable
      dbe_->setCurrentFolder(subdir_ + "TS4TS5Variable/");
      
      hTS4TS5RelativeDifference = dbe_->book1D("TS4_TS5_relative_difference",
         "(TS4-TS5)/(TS4+TS5), total charge > 20 fC", 100, -1, 1);
      hTS4TS5RelativeDifference->setAxisTitle("(TS4 - TS5) / (TS4 + TS5)", 1);

      hTS4TS5RelativeDifferenceVsCharge = dbe_->book2D("TS4_TS5_relative_difference_charge",
         "(TS4-TS5)/(TS4+TS5) vs. Charge", 25, 0, 400, 75, -1, 1);
      hTS4TS5RelativeDifferenceVsCharge->setAxisTitle("Charge", 1);
      hTS4TS5RelativeDifferenceVsCharge->setAxisTitle("(TS4 - TS5) / (TS4 + TS5)", 2);

      // Noise summary object
      dbe_->setCurrentFolder(subdir_ + "NoiseMonitoring/");
   
      hMaxZeros = dbe_->book1D("Max_Zeros", "Max zeros", 15, -0.5, 14.5);
      
      hTotalZeros = dbe_->book1D("Total_Zeros", "Total zeros", 15, -0.5, 14.5);
      
      hE2OverE10Digi = dbe_->book1D("E2OverE10Digi", "E2/E10 of the highest digi in an HPD", 100, 0, 2);
      
      hE2OverE10Digi5 = dbe_->book1D("E2OverE10Digi5", "E2/E10 of the highest 5 digi in an HPD", 100, 0, 2);
      
      hE2OverE10RBX = dbe_->book1D("E2OverE10RBX", "E2/E10 of RBX", 100, 0, 2);
      
      hHPDHitCount = dbe_->book1D("HPDHitCount", "HPD hit count (1.5 GeV)", 19, -0.5, 18.5);
      
      hRBXHitCount = dbe_->book1D("RBXHitCount", "Number of hits in RBX", 74, -0.5, 73.5);

      hHcalNoiseCategory = dbe_->book1D("Hcal_noise_category", "Hcal noise category", 10, 0.5, 10.5);
      hHcalNoiseCategory->setBinLabel(1, "RBX noise", 1);
      hHcalNoiseCategory->setBinLabel(2, "RBX pedestal flatter", 1);
      hHcalNoiseCategory->setBinLabel(3, "RBX pedestal sharper", 1);
      hHcalNoiseCategory->setBinLabel(4, "RBX flash large hit count", 1);
      hHcalNoiseCategory->setBinLabel(5, "RBX flash small hit count", 1);
      hHcalNoiseCategory->setBinLabel(7, "HPD discharge", 1);
      hHcalNoiseCategory->setBinLabel(8, "HPD ion feedback", 1);

      hBadZeroRBX = dbe_->book1D("BadZeroRBX", "RBX with bad ADC zero counts", 72, 0.5, 72.5);
      hBadCountHPD = dbe_->book1D("BadCountHPD", "HPD with bad hit counts", 72 * 4, 0.5, 72 * 4 + 0.5);
      hBadNoOtherCountHPD = dbe_->book1D("BadNoOtherCountHPD", "HPD with bad \"no other\" hit counts", 72 * 4, 0.5, 72 * 4 + 0.5);
      hBadE2E10RBX = dbe_->book1D("BadE2E10RBX", "RBX with bad E2/E10 value", 72, 0.5, 72.5);
   }

   ReadHcalPulse();

   return;
}
void HcalNoiseMonitor::unpack ( const FEDRawData raw,
const HcalElectronicsMap emap 
)

Member Data Documentation

std::vector<double> HcalNoiseMonitor::CumulativeIdealPulse [private]

Definition at line 84 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 86 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 85 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 83 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 46 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

Definition at line 47 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

Definition at line 76 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 77 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 78 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 67 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 62 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 63 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 64 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 81 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 79 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 57 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 58 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 52 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 53 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 45 of file HcalNoiseMonitor.h.

Referenced by HcalNoiseMonitor().

Definition at line 74 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 51 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 80 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 54 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 55 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 75 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 59 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 60 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 70 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 71 of file HcalNoiseMonitor.h.

Referenced by analyze(), and setup().

Definition at line 34 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

Definition at line 39 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

double HcalNoiseMonitor::mMaxE2E10 [private]

Definition at line 36 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

Definition at line 37 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

Definition at line 38 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

double HcalNoiseMonitor::mMinE2E10 [private]

Definition at line 35 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

Definition at line 40 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

Definition at line 33 of file HcalNoiseMonitor.h.

Referenced by HcalNoiseMonitor(), and PerformTriangleFit().

Definition at line 48 of file HcalNoiseMonitor.h.

Referenced by analyze(), and HcalNoiseMonitor().

Definition at line 30 of file HcalNoiseMonitor.h.

Referenced by HcalNoiseMonitor().

Definition at line 44 of file HcalNoiseMonitor.h.

Referenced by HcalNoiseMonitor().

std::vector<std::string> HcalNoiseMonitor::triggers_ [private]

Definition at line 29 of file HcalNoiseMonitor.h.

Referenced by HcalNoiseMonitor().