#include <HcalZDCMonitor.h>
$DATE: 2010/02/04 $Revision:
Definition at line 19 of file HcalZDCMonitor.h.
HcalZDCMonitor::HcalZDCMonitor | ( | ) |
Definition at line 3 of file HcalZDCMonitor.cc.
{ }
HcalZDCMonitor::~HcalZDCMonitor | ( | ) |
Definition at line 5 of file HcalZDCMonitor.cc.
{ }
void HcalZDCMonitor::endLuminosityBlock | ( | void | ) |
Reimplemented from HcalBaseMonitor.
Definition at line 439 of file HcalZDCMonitor.cc.
References h_2D_charge, h_2D_RecHitEnergy, h_2D_RecHitTime, h_2D_TSMean, h_ZDCM_EM_Charge, h_ZDCM_EM_RecHitEnergy, h_ZDCM_EM_RecHitTiming, h_ZDCM_EM_TSMean, h_ZDCM_HAD_Charge, h_ZDCM_HAD_RecHitEnergy, h_ZDCM_HAD_RecHitTiming, h_ZDCM_HAD_TSMean, h_ZDCP_EM_Charge, h_ZDCP_EM_RecHitEnergy, h_ZDCP_EM_RecHitTiming, h_ZDCP_EM_TSMean, h_ZDCP_HAD_Charge, h_ZDCP_HAD_RecHitEnergy, h_ZDCP_HAD_RecHitTiming, h_ZDCP_HAD_TSMean, i, and MonitorElement::setBinContent().
Referenced by ZDCMonitorModule::endLuminosityBlock(), and ZDCMonitorModule::endRun().
{ for (int i = 0; i < 5; ++i) { // EM Channels // ZDC Plus h_2D_charge->setBinContent(1, i + 1, h_ZDCP_EM_Charge[i]->getMean()); h_2D_TSMean->setBinContent(1, i + 1, h_ZDCP_EM_TSMean[i]->getMean()); h_2D_RecHitEnergy->setBinContent(1, i + 1, h_ZDCP_EM_RecHitEnergy[i]->getMean()); h_2D_RecHitTime->setBinContent(1, i + 1, h_ZDCP_EM_RecHitTiming[i]->getMean()); // ZDC Minus h_2D_charge->setBinContent(2, i + 1, h_ZDCM_EM_Charge[i]->getMean()); h_2D_TSMean->setBinContent(2, i + 1, h_ZDCM_EM_TSMean[i]->getMean()); h_2D_RecHitEnergy->setBinContent(2, i + 1, h_ZDCM_EM_RecHitEnergy[i]->getMean()); h_2D_RecHitTime->setBinContent(2, i + 1, h_ZDCM_EM_RecHitTiming[i]->getMean()); } for (int i = 0; i < 4; ++i) { // HAD channels // ZDC Plus h_2D_charge->setBinContent(1, i + 6, h_ZDCP_HAD_Charge[i]->getMean()); h_2D_TSMean->setBinContent(1, i + 6, h_ZDCP_HAD_TSMean[i]->getMean()); h_2D_RecHitEnergy->setBinContent(1, i + 6, h_ZDCP_HAD_RecHitEnergy[i]->getMean()); h_2D_RecHitTime->setBinContent(1, i + 6, h_ZDCP_HAD_RecHitTiming[i]->getMean()); // ZDC Minus //h_ZDCM_HAD_Pulse[i]->Scale(10. / h_ZDCM_HAD_Pulse[i]->getEntries()); h_2D_charge->setBinContent(2, i + 6, h_ZDCM_HAD_Charge[i]->getMean()); h_2D_TSMean->setBinContent(2, i + 6, h_ZDCM_HAD_TSMean[i]->getMean()); h_2D_RecHitEnergy->setBinContent(2, i + 6, h_ZDCM_HAD_RecHitEnergy[i]->getMean()); h_2D_RecHitTime->setBinContent(2, i + 6, h_ZDCM_HAD_RecHitTiming[i]->getMean()); } } // void HcalZDCMonitor::endLuminosityBlock()
double HcalZDCMonitor::getTime | ( | std::vector< double > | fData, |
unsigned int | ts_min, | ||
unsigned int | ts_max, | ||
double & | fSum | ||
) | [private] |
Definition at line 415 of file HcalZDCMonitor.cc.
Referenced by processEvent().
{ double weightedTime = 0.; double SumT = 0.; double Time = -999.; double digiThreshf = 99.5; for (unsigned int ts=ts_min; ts<=ts_max; ++ts) { if (fData[ts] > digiThreshf){ weightedTime += ts * fData[ts]; SumT += fData[ts]; } } if (SumT > 0.) { Time = weightedTime / SumT; } fSum = SumT; return Time; } //double HcalZDCMonitor::getTime()
void HcalZDCMonitor::processEvent | ( | const ZDCDigiCollection & | digi, |
const ZDCRecHitCollection & | rechit | ||
) |
Definition at line 245 of file HcalZDCMonitor.cc.
References ecalMGPA::adc(), edm::SortedCollection< T, SORT >::begin(), gather_cfg::cout, HcalBaseMonitor::cpu_timer, edm::SortedCollection< T, SORT >::end(), MonitorElement::Fill(), HcalBaseMonitor::fVerbosity, getTime(), h_2D_saturation, h_ZDCM_EM_Charge, h_ZDCM_EM_Pulse, h_ZDCM_EM_RecHitEnergy, h_ZDCM_EM_RecHitTiming, h_ZDCM_EM_TSMean, h_ZDCM_HAD_Charge, h_ZDCM_HAD_Pulse, h_ZDCM_HAD_RecHitEnergy, h_ZDCM_HAD_RecHitTiming, h_ZDCM_HAD_TSMean, h_ZDCP_EM_Charge, h_ZDCP_EM_Pulse, h_ZDCP_EM_RecHitEnergy, h_ZDCP_EM_RecHitTiming, h_ZDCP_EM_TSMean, h_ZDCP_HAD_Charge, h_ZDCP_HAD_Pulse, h_ZDCP_HAD_RecHitEnergy, h_ZDCP_HAD_RecHitTiming, h_ZDCP_HAD_TSMean, i, ievt_, meEVT_, edm::CPUTimer::reset(), HcalBaseMonitor::showTiming, edm::SortedCollection< T, SORT >::size(), and edm::CPUTimer::start().
Referenced by ZDCMonitorModule::analyze().
{ if (fVerbosity > 0) std::cout << "<HcalZDCMonitor::processEvent> Processing Event..." << std::endl; if (showTiming) { cpu_timer.reset(); cpu_timer.start(); } ++ievt_; meEVT_->Fill(ievt_); //-------------------------------------- // ZDC Digi part //-------------------------------------- double fSum = 0.; std::vector<double> fData; double digiThresh = 99.5; //corresponds to 40 ADC counts //int digiThreshADC = 40; int digiSaturation = 127; //double ZDCQIEConst = 2.6; for (ZDCDigiCollection::const_iterator digi_iter = digi.begin(); digi_iter != digi.end(); ++digi_iter) { const ZDCDataFrame digi = (const ZDCDataFrame) (*digi_iter); //HcalZDCDetId id(digi_iter->id()); int iSide = digi_iter->id().zside(); int iSection = digi_iter->id().section(); int iChannel = digi_iter->id().channel(); unsigned int fTS = digi_iter->size(); while (fData.size()<fTS) fData.push_back(-999); while (fData.size()>fTS) fData.pop_back(); // delete last elements fSum = 0.; bool saturated = false; for (unsigned int i = 0; i < fTS; ++i) { //fData[i]=digi[i].nominal_fC() * ZDCQIEConst; fData[i]=digi[i].nominal_fC(); if (digi[i].adc()==digiSaturation){ saturated=true; } } double fTSMean = getTime(fData, 4, 6, fSum); // tsmin = 4, tsmax = 6. //std::cout << "Side= " << iSide << " Section= " << iSection << " Channel= " << iChannel << "\tCharge\t" << fSum <<std::endl; if (saturated==true){ h_2D_saturation->Fill(iSide==1?0:1,iSection==1?iChannel-1:iChannel+4,1); } if (iSection == 1) { // EM if (iSide == 1) { // Plus for (unsigned int i = 0; i < fTS; ++i) { if (fData[i] > digiThresh) h_ZDCP_EM_Pulse[iChannel - 1]->Fill(i, fData[i]); } if (fSum > digiThresh) { h_ZDCP_EM_Charge[iChannel - 1]->Fill(fSum); h_ZDCP_EM_TSMean[iChannel - 1]->Fill(fTSMean); //std::cout<< "fSum " << fSum << " fTSMean " << fTSMean <<std::endl; } } // Plus if (iSide == -1) { // Minus for (unsigned int i = 0; i < fTS; ++i) { if (fData[i] > digiThresh) h_ZDCM_EM_Pulse[iChannel - 1]->Fill(i, fData[i]); } if (fSum > digiThresh) { h_ZDCM_EM_Charge[iChannel - 1]->Fill(fSum); h_ZDCM_EM_TSMean[iChannel - 1]->Fill(fTSMean); } } // Minus }// EM else if (iSection == 2) { // HAD if (iSide == 1) { // Plus for (unsigned int i = 0; i < fTS; ++i) { if (fData[i] > digiThresh) h_ZDCP_HAD_Pulse[iChannel - 1]->Fill(i, fData[i]); } if (fSum > digiThresh) { h_ZDCP_HAD_Charge[iChannel - 1]->Fill(fSum); h_ZDCP_HAD_TSMean[iChannel - 1]->Fill(fTSMean); } } // Plus if (iSide == -1) { // Minus for (unsigned int i = 0; i < fTS; ++i) { if (fData[i] > digiThresh) h_ZDCM_HAD_Pulse[iChannel - 1]->Fill(i, fData[i]); } if (fSum > digiThresh) { h_ZDCM_HAD_Charge[iChannel - 1]->Fill(fSum); h_ZDCM_HAD_TSMean[iChannel - 1]->Fill(fTSMean); } }// Minus } // HAD } // loop on zdc digi collection //-------------------------------------- // ZDC RecHit part //-------------------------------------- for (ZDCRecHitCollection::const_iterator rechit_iter = rechit.begin(); rechit_iter != rechit.end(); ++rechit_iter) { HcalZDCDetId id(rechit_iter->id()); int Side = (rechit_iter->id()).zside(); int Section = (rechit_iter->id()).section(); int Channel = (rechit_iter->id()).channel(); //std::cout << "RecHitEnergy " << zhit->energy() << " RecHitTime " << zhit->time() << std::endl; if(Section==1) { //EM if (Side ==1 ){ // Plus h_ZDCP_EM_RecHitEnergy[Channel-1]->Fill(rechit_iter->energy()); h_ZDCP_EM_RecHitTiming[Channel-1]->Fill(rechit_iter->time()); } if (Side == -1 ){ //Minus h_ZDCM_EM_RecHitEnergy[Channel-1]->Fill(rechit_iter->energy()); h_ZDCM_EM_RecHitTiming[Channel-1]->Fill(rechit_iter->time()); } } //EM else if(Section==2) { //HAD if (Side ==1 ){ //Plus h_ZDCP_HAD_RecHitEnergy[Channel-1]->Fill(rechit_iter->energy()); h_ZDCP_HAD_RecHitTiming[Channel-1]->Fill(rechit_iter->time()); } if (Side == -1 ){ //Minus h_ZDCM_HAD_RecHitEnergy[Channel-1]->Fill(rechit_iter->energy()); h_ZDCM_HAD_RecHitTiming[Channel-1]->Fill(rechit_iter->time()); } } // HAD } // loop on rechits } // end of event processing
void HcalZDCMonitor::reset | ( | void | ) |
void HcalZDCMonitor::setup | ( | const edm::ParameterSet & | ps, |
DQMStore * | dbe | ||
) | [virtual] |
Reimplemented from HcalBaseMonitor.
Definition at line 10 of file HcalZDCMonitor.cc.
References HcalBaseMonitor::baseFolder_, DQMStore::book1D(), DQMStore::book2D(), DQMStore::bookInt(), gather_cfg::cout, HcalBaseMonitor::cpu_timer, MonitorElement::Fill(), HcalBaseMonitor::fVerbosity, h_2D_charge, h_2D_RecHitEnergy, h_2D_RecHitTime, h_2D_saturation, h_2D_TSMean, h_ZDCM_EM_Charge, h_ZDCM_EM_Pulse, h_ZDCM_EM_RecHitEnergy, h_ZDCM_EM_RecHitTiming, h_ZDCM_EM_TSMean, h_ZDCM_HAD_Charge, h_ZDCM_HAD_Pulse, h_ZDCM_HAD_RecHitEnergy, h_ZDCM_HAD_RecHitTiming, h_ZDCM_HAD_TSMean, h_ZDCP_EM_Charge, h_ZDCP_EM_Pulse, h_ZDCP_EM_RecHitEnergy, h_ZDCP_EM_RecHitTiming, h_ZDCP_EM_TSMean, h_ZDCP_HAD_Charge, h_ZDCP_HAD_Pulse, h_ZDCP_HAD_RecHitEnergy, h_ZDCP_HAD_RecHitTiming, h_ZDCP_HAD_TSMean, i, ievt_, HcalBaseMonitor::m_dbe, meEVT_, mergeVDriftHistosByStation::name, edm::CPUTimer::reset(), HcalBaseMonitor::rootFolder_, MonitorElement::setAxisTitle(), MonitorElement::setBinLabel(), DQMStore::setCurrentFolder(), HcalBaseMonitor::showTiming, edm::CPUTimer::start(), and indexGen::title.
Referenced by ZDCMonitorModule::ZDCMonitorModule().
{ HcalBaseMonitor::setup(ps, dbe); baseFolder_ = rootFolder_ + "ZDCMonitor_Hcal"; if (showTiming) { cpu_timer.reset(); cpu_timer.start(); } if (fVerbosity > 0) std::cout << "<HcalZDCMonitor::setup> Setting up histograms" << std::endl; if (fVerbosity > 1) std::cout << "<HcalZDCMonitor::setup> Getting variable values from cfg files" << std::endl; // Set initial event # to 0 ievt_ = 0; //Histograms if (m_dbe) { if (fVerbosity > 1) std::cout << "<HcalZDCMonitor::setup> Setting up Histograms" << std::endl; m_dbe->setCurrentFolder(baseFolder_); meEVT_ = m_dbe->bookInt("ZDC Event Number"); meEVT_->Fill(ievt_); char name[128]; char title[128]; h_2D_charge = m_dbe->book2D("2D_DigiCharge", "Digi Charge (fC)", 2, 0, 2, 9, 0, 9); h_2D_charge->setBinLabel(1,"ZDC+",1); h_2D_charge->setBinLabel(2,"ZDC-",1); h_2D_charge->setBinLabel(1,"EM1",2); h_2D_charge->setBinLabel(2,"EM2",2); h_2D_charge->setBinLabel(3,"EM3",2); h_2D_charge->setBinLabel(4,"EM4",2); h_2D_charge->setBinLabel(5,"EM5",2); h_2D_charge->setBinLabel(6,"HAD1",2); h_2D_charge->setBinLabel(7,"HAD2",2); h_2D_charge->setBinLabel(8,"HAD3",2); h_2D_charge->setBinLabel(9,"HAD4",2); h_2D_TSMean = m_dbe->book2D("2D_DigiTiming", "Digi Timing", 2, 0, 2, 9, 0, 9); h_2D_TSMean->setBinLabel(1,"ZDC+",1); h_2D_TSMean->setBinLabel(2,"ZDC-",1); h_2D_TSMean->setBinLabel(1,"EM1",2); h_2D_TSMean->setBinLabel(2,"EM2",2); h_2D_TSMean->setBinLabel(3,"EM3",2); h_2D_TSMean->setBinLabel(4,"EM4",2); h_2D_TSMean->setBinLabel(5,"EM5",2); h_2D_TSMean->setBinLabel(6,"HAD1",2); h_2D_TSMean->setBinLabel(7,"HAD2",2); h_2D_TSMean->setBinLabel(8,"HAD3",2); h_2D_TSMean->setBinLabel(9,"HAD4",2); h_2D_RecHitEnergy = m_dbe->book2D("2D_RecHitEnergy", "Rechit Energy", 2, 0, 2, 9, 0, 9); h_2D_RecHitEnergy->setBinLabel(1,"ZDC+",1); h_2D_RecHitEnergy->setBinLabel(2,"ZDC-",1); h_2D_RecHitEnergy->setBinLabel(1,"EM1",2); h_2D_RecHitEnergy->setBinLabel(2,"EM2",2); h_2D_RecHitEnergy->setBinLabel(3,"EM3",2); h_2D_RecHitEnergy->setBinLabel(4,"EM4",2); h_2D_RecHitEnergy->setBinLabel(5,"EM5",2); h_2D_RecHitEnergy->setBinLabel(6,"HAD1",2); h_2D_RecHitEnergy->setBinLabel(7,"HAD2",2); h_2D_RecHitEnergy->setBinLabel(8,"HAD3",2); h_2D_RecHitEnergy->setBinLabel(9,"HAD4",2); h_2D_RecHitTime = m_dbe->book2D("2D_RecHitTime", "Rechit Timing", 2, 0, 2, 9, 0, 9); h_2D_RecHitTime->setBinLabel(1,"ZDC+",1); h_2D_RecHitTime->setBinLabel(2,"ZDC-",1); h_2D_RecHitTime->setBinLabel(1,"EM1",2); h_2D_RecHitTime->setBinLabel(2,"EM2",2); h_2D_RecHitTime->setBinLabel(3,"EM3",2); h_2D_RecHitTime->setBinLabel(4,"EM4",2); h_2D_RecHitTime->setBinLabel(5,"EM5",2); h_2D_RecHitTime->setBinLabel(6,"HAD1",2); h_2D_RecHitTime->setBinLabel(7,"HAD2",2); h_2D_RecHitTime->setBinLabel(8,"HAD3",2); h_2D_RecHitTime->setBinLabel(9,"HAD4",2); h_2D_saturation = m_dbe->book2D("h_2D_QIE", "Saturation Check", 2, 0, 2, 9, 0, 9); h_2D_saturation->setBinLabel(1,"ZDC+",1); h_2D_saturation->setBinLabel(2,"ZDC-",1); h_2D_saturation->setBinLabel(1,"EM1",2); h_2D_saturation->setBinLabel(2,"EM2",2); h_2D_saturation->setBinLabel(3,"EM3",2); h_2D_saturation->setBinLabel(4,"EM4",2); h_2D_saturation->setBinLabel(5,"EM5",2); h_2D_saturation->setBinLabel(6,"HAD1",2); h_2D_saturation->setBinLabel(7,"HAD2",2); h_2D_saturation->setBinLabel(8,"HAD3",2); h_2D_saturation->setBinLabel(9,"HAD4",2); m_dbe->setCurrentFolder(baseFolder_ + "/Digis"); for (int i = 0; i < 5; ++i) { // pulse Plus Side sprintf(title, "h_ZDCP_EMChan_%i_Pulse", i + 1); sprintf(name, "ZDC Plus EM Section Pulse for channel %i", i + 1); h_ZDCP_EM_Pulse[i] = m_dbe->book1D(title, name, 10, -0.5, 9.5); h_ZDCP_EM_Pulse[i]->setAxisTitle("Time Slice id",1); h_ZDCP_EM_Pulse[i]->setAxisTitle("Pulse Height",2); // pulse Minus Side sprintf(title, "h_ZDCM_EMChan_%i_Pulse", i + 1); sprintf(name, "ZDC Minus EM Section Pulse for channel %i", i + 1); h_ZDCM_EM_Pulse[i] = m_dbe->book1D(title, name, 10, -0.5, 9.5); h_ZDCM_EM_Pulse[i]->setAxisTitle("Time Slice id",1); h_ZDCM_EM_Pulse[i]->setAxisTitle("Pulse Height",2); // integrated charge over 10 time samples sprintf(title, "h_ZDCP_EMChan_%i_Charge", i + 1); sprintf(name, "ZDC Plus EM Section Charge for channel %i", i + 1); h_ZDCP_EM_Charge[i] = m_dbe->book1D(title, name, 1000, 0., 30000.); h_ZDCP_EM_Charge[i]->setAxisTitle("Charge (fC)",1); h_ZDCP_EM_Charge[i]->setAxisTitle("Events",2); // integrated charge over 10 time samples sprintf(title, "h_ZDCM_EMChan_%i_Charge", i + 1); sprintf(name, "ZDC Minus EM Section Charge for channel %i", i + 1); h_ZDCM_EM_Charge[i] = m_dbe->book1D(title, name, 1000, 0., 30000.); h_ZDCM_EM_Charge[i]->setAxisTitle("Charge (fC)",1); h_ZDCM_EM_Charge[i]->setAxisTitle("Events",2); // charge weighted time slice sprintf(title, "h_ZDCP_EMChan_%i_TSMean", i + 1); sprintf(name, "ZDC Plus EM Section TSMean for channel %i", i + 1); h_ZDCP_EM_TSMean[i] = m_dbe->book1D(title, name, 100, -0.5, 9.5); h_ZDCP_EM_TSMean[i]->setAxisTitle("Timing",1); h_ZDCP_EM_TSMean[i]->setAxisTitle("Events",2); // charge weighted time slice sprintf(title, "h_ZDCM_EMChan_%i_TSMean", i + 1); sprintf(name, "ZDC Minus EM Section TSMean for channel %i", i + 1); h_ZDCM_EM_TSMean[i] = m_dbe->book1D(title, name, 100, -0.5, 9.5); h_ZDCM_EM_TSMean[i]->setAxisTitle("Timing",1); h_ZDCM_EM_TSMean[i]->setAxisTitle("Events",2); } for (int i = 0; i < 4; ++i) { // pulse Plus Side sprintf(title, "h_ZDCP_HADChan_%i_Pulse", i + 1); sprintf(name, "ZDC Plus HAD Section Pulse for channel %i", i + 1); h_ZDCP_HAD_Pulse[i] = m_dbe->book1D(title, name, 10, -0.5, 9.5); h_ZDCP_HAD_Pulse[i]->setAxisTitle("Time Slice id",1); h_ZDCP_HAD_Pulse[i]->setAxisTitle("Pulse Height",2); // pulse Minus Side sprintf(title, "h_ZDCM_HADChan_%i_Pulse", i + 1); sprintf(name, "ZDC Minus HAD Section Pulse for channel %i", i + 1); h_ZDCM_HAD_Pulse[i] = m_dbe->book1D(title, name, 10, -0.5, 9.5); h_ZDCP_HAD_Pulse[i]->setAxisTitle("Time Slice id",1); h_ZDCP_HAD_Pulse[i]->setAxisTitle("Pulse Height",2); // integrated charge over 10 time samples sprintf(title, "h_ZDCP_HADChan_%i_Charge", i + 1); sprintf(name, "ZDC Plus HAD Section Charge for channel %i", i + 1); h_ZDCP_HAD_Charge[i] = m_dbe->book1D(title, name, 1000, 0., 30000.); h_ZDCP_HAD_Charge[i]->setAxisTitle("Charge (fC)",1); h_ZDCP_HAD_Charge[i]->setAxisTitle("Events",2); // integrated charge over 10 time samples sprintf(title, "h_ZDCM_HADChan_%i_Charge", i + 1); sprintf(name, "ZDC Minus HAD Section Charge for channel %i", i + 1); h_ZDCM_HAD_Charge[i] = m_dbe->book1D(title, name, 1000, 0., 30000.); h_ZDCM_HAD_Charge[i]->setAxisTitle("Charge (fC)",1); h_ZDCM_HAD_Charge[i]->setAxisTitle("Events",2); // charge weighted time slice sprintf(title, "h_ZDCP_HADChan_%i_TSMean", i + 1); sprintf(name, "ZDC Plus HAD Section TSMean for channel %i", i + 1); h_ZDCP_HAD_TSMean[i] = m_dbe->book1D(title, name, 100, -0.5, 9.5); h_ZDCP_HAD_TSMean[i]->setAxisTitle("Timing",1); h_ZDCP_HAD_TSMean[i]->setAxisTitle("Events",2); // charge weighted time slice sprintf(title, "h_ZDCM_HADChan_%i_TSMean", i + 1); sprintf(name, "ZDC Minus HAD Section TSMean for channel %i", i + 1); h_ZDCM_HAD_TSMean[i] = m_dbe->book1D(title, name, 100, -0.5, 9.5); h_ZDCM_HAD_TSMean[i]->setAxisTitle("Timing",1); h_ZDCM_HAD_TSMean[i]->setAxisTitle("Events",2); } m_dbe->setCurrentFolder(baseFolder_ + "/RecHits"); for (int i = 0; i < 5; ++i) { //RecHitEnergy Plus Side sprintf(title,"h_ZDCP_EMChan_%i_RecHit_Energy",i+1); sprintf(name,"ZDC EM Section Rechit Energy for channel %i",i+1); h_ZDCP_EM_RecHitEnergy[i] = m_dbe->book1D(title, name, 1010, -100., 10000.); h_ZDCP_EM_RecHitEnergy[i]->setAxisTitle("Energy (GeV)",1); h_ZDCP_EM_RecHitEnergy[i]->setAxisTitle("Events",2); //RecHitEnergy Minus Side sprintf(title,"h_ZDCM_EMChan_%i_RecHit_Energy",i+1); sprintf(name,"ZDC EM Section Rechit Energy for channel %i",i+1); h_ZDCM_EM_RecHitEnergy[i] = m_dbe->book1D(title, name, 1010, -100., 10000.); h_ZDCM_EM_RecHitEnergy[i]->setAxisTitle("Energy (GeV)",1); h_ZDCM_EM_RecHitEnergy[i]->setAxisTitle("Events",2); //RecHit Timing Plus Side sprintf(title,"h_ZDCP_EMChan_%i_RecHit_Timing",i+1); sprintf(name,"ZDC EM Section Rechit Timing for channel %i",i+1); h_ZDCP_EM_RecHitTiming[i] = m_dbe->book1D(title, name, 100, -100., 100.); h_ZDCP_EM_RecHitTiming[i]->setAxisTitle("RecHit Time",1); h_ZDCP_EM_RecHitTiming[i]->setAxisTitle("Events",2); //RecHit Timing Minus Side sprintf(title,"h_ZDCM_EMChan_%i_RecHit_Timing",i+1); sprintf(name,"ZDC EM Section Rechit Timing for channel %i",i+1); h_ZDCM_EM_RecHitTiming[i] = m_dbe->book1D(title, name, 100, -100., 100.); h_ZDCM_EM_RecHitTiming[i]->setAxisTitle("RecHit Time",1); h_ZDCM_EM_RecHitTiming[i]->setAxisTitle("Events",2); } for (int i = 0; i < 4; ++i) { //RecHitEnergy Plus Side sprintf(title,"h_ZDCP_HADChan_%i_RecHit_Energy",i+1); sprintf(name,"ZDC HAD Section Rechit Energy for channel %i",i+1); h_ZDCP_HAD_RecHitEnergy[i] = m_dbe->book1D(title, name, 1010, -100., 10000.); h_ZDCP_HAD_RecHitEnergy[i]->setAxisTitle("Energy (GeV)",1); h_ZDCP_HAD_RecHitEnergy[i]->setAxisTitle("Events",2); //RecHitEnergy Minus Side sprintf(title,"h_ZDCM_HADChan_%i_RecHit_Energy",i+1); sprintf(name,"ZDC HAD Section Rechit Energy for channel %i",i+1); h_ZDCM_HAD_RecHitEnergy[i] = m_dbe->book1D(title, name, 1010, -100., 10000.); h_ZDCM_HAD_RecHitEnergy[i]->setAxisTitle("Energy (GeV)",1); h_ZDCM_HAD_RecHitEnergy[i]->setAxisTitle("Events",2); //RecHit Timing Plus Side sprintf(title,"h_ZDCP_HADChan_%i_RecHit_Timing",i+1); sprintf(name,"ZDC HAD Section Rechit Timing for channel %i",i+1); h_ZDCP_HAD_RecHitTiming[i] = m_dbe->book1D(title, name, 100, -100., 100.); h_ZDCP_HAD_RecHitTiming[i]->setAxisTitle("RecHit Time",1); h_ZDCP_HAD_RecHitTiming[i]->setAxisTitle("Events",2); //RecHit Timing Minus Side sprintf(title,"h_ZDCM_HADChan_%i_RecHit_Timing",i+1); sprintf(name,"ZDC HAD Section Rechit Timing for channel %i",i+1); h_ZDCM_HAD_RecHitTiming[i] = m_dbe->book1D(title, name, 100, -100., 100.); h_ZDCM_HAD_RecHitTiming[i]->setAxisTitle("RecHit Time",1); h_ZDCM_HAD_RecHitTiming[i]->setAxisTitle("Events",2); } } return; }
HcalCalibrations HcalZDCMonitor::calibs_ [private] |
Definition at line 46 of file HcalZDCMonitor.h.
const HcalQIECoder* HcalZDCMonitor::channelCoder_ [private] |
Definition at line 45 of file HcalZDCMonitor.h.
bool HcalZDCMonitor::checkZDC_ [private] |
Definition at line 40 of file HcalZDCMonitor.h.
MonitorElement* HcalZDCMonitor::h_2D_charge [private] |
Definition at line 51 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), and setup().
MonitorElement* HcalZDCMonitor::h_2D_RecHitEnergy [private] |
Definition at line 53 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), and setup().
MonitorElement* HcalZDCMonitor::h_2D_RecHitTime [private] |
Definition at line 54 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), and setup().
MonitorElement* HcalZDCMonitor::h_2D_saturation [private] |
Definition at line 50 of file HcalZDCMonitor.h.
Referenced by processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_2D_TSMean [private] |
Definition at line 52 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_EM_Charge[5] [private] |
Definition at line 58 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_EM_Pulse[5] [private] |
Definition at line 56 of file HcalZDCMonitor.h.
Referenced by processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_EM_RecHitEnergy[5] [private] |
Definition at line 68 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_EM_RecHitTiming[5] [private] |
Definition at line 70 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_EM_TSMean[5] [private] |
Definition at line 60 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_HAD_Charge[4] [private] |
Definition at line 64 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_HAD_Pulse[4] [private] |
Definition at line 62 of file HcalZDCMonitor.h.
Referenced by processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_HAD_RecHitEnergy[4] [private] |
Definition at line 72 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_HAD_RecHitTiming[4] [private] |
Definition at line 74 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCM_HAD_TSMean[4] [private] |
Definition at line 66 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_EM_Charge[5] [private] |
Definition at line 57 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_EM_Pulse[5] [private] |
Definition at line 55 of file HcalZDCMonitor.h.
Referenced by processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_EM_RecHitEnergy[5] [private] |
Definition at line 67 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_EM_RecHitTiming[5] [private] |
Definition at line 69 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_EM_TSMean[5] [private] |
Definition at line 59 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_HAD_Charge[4] [private] |
Definition at line 63 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_HAD_Pulse[4] [private] |
Definition at line 61 of file HcalZDCMonitor.h.
Referenced by processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_HAD_RecHitEnergy[4] [private] |
Definition at line 71 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_HAD_RecHitTiming[4] [private] |
Definition at line 73 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
MonitorElement* HcalZDCMonitor::h_ZDCP_HAD_TSMean[4] [private] |
Definition at line 65 of file HcalZDCMonitor.h.
Referenced by endLuminosityBlock(), processEvent(), and setup().
int HcalZDCMonitor::ievt_ [private] |
Reimplemented from HcalBaseMonitor.
Definition at line 47 of file HcalZDCMonitor.h.
Referenced by processEvent(), and setup().
MonitorElement* HcalZDCMonitor::meEVT_ [private] |
Reimplemented from HcalBaseMonitor.
Definition at line 49 of file HcalZDCMonitor.h.
Referenced by processEvent(), and setup().
int HcalZDCMonitor::NumBadZDC [private] |
Definition at line 41 of file HcalZDCMonitor.h.
MonitorElement* HcalZDCMonitor::ProblemsVsLB_ZDC [private] |
Definition at line 42 of file HcalZDCMonitor.h.
const HcalQIEShape* HcalZDCMonitor::shape_ [private] |
Definition at line 44 of file HcalZDCMonitor.h.