CMS 3D CMS Logo

Classes | Public Member Functions | Private Types | Private Member Functions | Private Attributes

HcalLedAnalysis Class Reference

#include <HcalLedAnalysis.h>

List of all members.

Classes

struct  CALIBBUNCH

Public Member Functions

 HcalLedAnalysis (const edm::ParameterSet &ps)
 Constructor.
void LedDone ()
void LedSampleAnalysis ()
void LedSetup (const std::string &m_outputFileROOT)
void processLedEvent (const HBHEDigiCollection &hbhe, const HODigiCollection &ho, const HFDigiCollection &hf, const HcalCalibDigiCollection calib, const HcalDbService &cond)
 ~HcalLedAnalysis ()
 Destructor.

Private Types

typedef std::pair< TH1F
*, std::pair< std::map< int,
std::vector< double >
>, std::vector< TH1F * > > > 
LEDBUNCH

Private Member Functions

float BinsizeCorr (float time)
void GetLedConst (std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)
void LedHBHEHists (const HcalDetId &detid, const HBHEDataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
void LedHFHists (const HcalDetId &detid, const HFDataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
void LedHOHists (const HcalDetId &detid, const HODataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
void LedTrendings (std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)
void ProcessCalibEvent (int fiberChan, HcalCalibDetId calibId, const HcalCalibDataFrame digi)
void SetupLEDHists (int id, const HcalDetId detid, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)

Private Attributes

std::map< HcalCalibDetId,
CALIBBUNCH >::iterator 
_meca
std::map< HcalDetId, std::map
< int, float > >::iterator 
_meee
std::map< HcalDetId, std::map
< int, LEDBUNCH > >::iterator 
_meol
std::map< HcalCalibDetId,
CALIBBUNCH
calibHists
int evt
int evt_curr
struct {
   TH1F *   ALLLEDS
   TH1F *   CHI2
   TH1F *   LEDMEAN
   TH1F *   LEDRMS
   std::map< HcalDetId, std::map
< int, LEDBUNCH > >   LEDTRENDS
hbHists
struct {
   TH1F *   ALLLEDS
   TH1F *   CHI2
   TH1F *   LEDMEAN
   TH1F *   LEDRMS
   std::map< HcalDetId, std::map
< int, LEDBUNCH > >   LEDTRENDS
hfHists
struct {
   TH1F *   ALLLEDS
   TH1F *   CHI2
   TH1F *   LEDMEAN
   TH1F *   LEDRMS
   std::map< HcalDetId, std::map
< int, LEDBUNCH > >   LEDTRENDS
hoHists
std::map< HcalDetId, std::map
< int, float > > 
m_AllPedVals
const HcalQIECoderm_coder
int m_endTS
TFile * m_file
int m_fitflag
int m_hiSaveflag
std::ofstream m_logFile
int m_nevtsample
std::ofstream m_outFile
std::string m_outputFileROOT
std::string m_outputFileText
std::string m_outputFileX
std::ofstream m_outputFileXML
const HcalPedestalm_ped
const HcalQIEShapem_shape
int m_startTS
bool m_usecalib
char output [100]
int sample
std::vector< bool > state

Detailed Description

Definition at line 32 of file HcalLedAnalysis.h.


Member Typedef Documentation

typedef std::pair<TH1F*,std::pair<std::map<int, std::vector<double> >,std::vector<TH1F*> > > HcalLedAnalysis::LEDBUNCH [private]

Definition at line 68 of file HcalLedAnalysis.h.


Constructor & Destructor Documentation

HcalLedAnalysis::HcalLedAnalysis ( const edm::ParameterSet ps)

Constructor.

Definition at line 12 of file HcalLedAnalysis.cc.

References gather_cfg::cout, edm::ParameterSet::getUntrackedParameter(), gen::k, and convertSQLitetoXML_cfg::output.

{
  // init
  evt=0;
  sample=0;
  m_file=0;
  // output files
  for(int k=0;k<4;k++) state.push_back(true); // 4 cap-ids (do we care?)
  m_outputFileText = ps.getUntrackedParameter<string>("outputFileText", "");
  m_outputFileX = ps.getUntrackedParameter<string>("outputFileXML","");
  if ( m_outputFileText.size() != 0 ) {
    cout << "Hcal LED results will be saved to " << m_outputFileText.c_str() << endl;
    m_outFile.open(m_outputFileText.c_str());
  } 
  m_outputFileROOT = ps.getUntrackedParameter<string>("outputFileHist", "");
  if ( m_outputFileROOT.size() != 0 ) {
    cout << "Hcal LED histograms will be saved to " << m_outputFileROOT.c_str() << endl;
  }

  m_nevtsample = ps.getUntrackedParameter<int>("nevtsample",9999999);
  if(m_nevtsample<1)m_nevtsample=9999999;
  m_hiSaveflag = ps.getUntrackedParameter<int>("hiSaveflag",0);
  if(m_hiSaveflag<0)m_hiSaveflag=0;
  if(m_hiSaveflag>0)m_hiSaveflag=1;
  m_fitflag = ps.getUntrackedParameter<int>("analysisflag",2);
  if(m_fitflag<0)m_fitflag=0;
  if(m_fitflag>4)m_fitflag=4;
  m_startTS = ps.getUntrackedParameter<int>("firstTS", 0);
  if(m_startTS<0) m_startTS=0;
  m_endTS = ps.getUntrackedParameter<int>("lastTS", 9);
  m_usecalib = ps.getUntrackedParameter<bool>("usecalib",false);
  m_logFile.open("HcalLedAnalysis.log");

  int runNum = ps.getUntrackedParameter<int>("runNumber",999999);

  // histogram booking
  hbHists.ALLLEDS = new TH1F("HBHE All LEDs","HB/HE All Leds",10,0,9);
  hbHists.LEDRMS= new TH1F("HBHE All LED RMS","HB/HE All LED RMS",100,0,3);
  hbHists.LEDMEAN= new TH1F("HBHE All LED Means","HB/HE All LED Means",100,0,9);
  hbHists.CHI2= new TH1F("HBHE Chi2 by ndf for Landau fit","HB/HE Chi2/ndf Landau",200,0.,50.);

  hoHists.ALLLEDS = new TH1F("HO All LEDs","HO All Leds",10,0,9);
  hoHists.LEDRMS= new TH1F("HO All LED RMS","HO All LED RMS",100,0,3);
  hoHists.LEDMEAN= new TH1F("HO All LED Means","HO All LED Means",100,0,9);
  hoHists.CHI2= new TH1F("HO Chi2 by ndf for Landau fit","HO Chi2/ndf Landau",200,0.,50.);

  hfHists.ALLLEDS = new TH1F("HF All LEDs","HF All Leds",10,0,9);
  hfHists.LEDRMS= new TH1F("HF All LED RMS","HF All LED RMS",100,0,3);
  hfHists.LEDMEAN= new TH1F("HF All LED Means","HF All LED Means",100,0,9);
  hfHists.CHI2= new TH1F("HF Chi2 by ndf for Landau fit","HF Chi2/ndf Landau",200,0.,50.);

  //XML file header
  m_outputFileXML.open(m_outputFileX.c_str());
  sprintf(output, "<?xml version='1.0' encoding='UTF-8'?>");
  m_outputFileXML << output << endl;
  sprintf(output, "<ROOT>");
  m_outputFileXML << output << endl << endl;
  sprintf(output, "  <HEADER>");
  m_outputFileXML << output << endl;
  sprintf(output, "    <TYPE>");
  m_outputFileXML << output << endl;
  sprintf(output, "      <EXTENSION_TABLE_NAME>HCAL_LED_TIMING</EXTENSION_TABLE_NAME>");
  m_outputFileXML << output << endl;
  sprintf(output, "      <NAME>HCAL LED Timing</NAME>");
  m_outputFileXML << output << endl;
  sprintf(output, "    </TYPE>");
  m_outputFileXML << output << endl;
  sprintf(output, "    <RUN>");
  m_outputFileXML << output << endl;
  sprintf(output, "      <RUN_TYPE>hcal-led-timing-test</RUN_TYPE>");
  m_outputFileXML << output << endl;
  sprintf(output, "      <RUN_NUMBER>%06i</RUN_NUMBER>", runNum);
  m_outputFileXML << output << endl;
  sprintf(output, "      <RUN_BEGIN_TIMESTAMP>2007-07-09 00:00:00.0</RUN_BEGIN_TIMESTAMP>");
  m_outputFileXML << output << endl;
  sprintf(output, "      <COMMENT_DESCRIPTION></COMMENT_DESCRIPTION>");
  m_outputFileXML << output << endl;
  sprintf(output, "    </RUN>");
  m_outputFileXML << output << endl;
  sprintf(output, "  </HEADER>");
  m_outputFileXML << output << endl;
  sprintf(output, "<!-- Tags secton -->");
  m_outputFileXML << output << endl;
  sprintf(output, "  <ELEMENTS>");
  m_outputFileXML << output << endl;
  sprintf(output, "    <DATA_SET id='-1'/>");
  m_outputFileXML << output << endl;
  sprintf(output, "      <IOV id='1'>");
  m_outputFileXML << output << endl;
  sprintf(output, "        <INTERVAL_OF_VALIDITY_BEGIN>2147483647</INTERVAL_OF_VALIDITY_BEGIN>");
  m_outputFileXML << output << endl;
  sprintf(output, "        <INTERVAL_OF_VALIDITY_END>0</INTERVAL_OF_VALIDITY_END>");
  m_outputFileXML << output << endl;
  sprintf(output, "      </IOV>");
  m_outputFileXML << output << endl;
  sprintf(output, "      <TAG id='2' mode='auto'>");
  m_outputFileXML << output << endl;
  sprintf(output, "        <TAG_NAME>laser_led_%06i<TAG_NAME>", runNum);
  m_outputFileXML << output << endl;
  sprintf(output, "        <DETECTOR_NAME>HCAL</DETECTOR_NAME>");
  m_outputFileXML << output << endl;
  sprintf(output, "        <COMMENT_DESCRIPTION></COMMENT_DESCRIPTION>");
  m_outputFileXML << output << endl;
  sprintf(output, "      </TAG>");
  m_outputFileXML << output << endl;
  sprintf(output, "  </ELEMENTS>");
  m_outputFileXML << output << endl;
  sprintf(output, "  <MAPS>");
  m_outputFileXML << output << endl;
  sprintf(output, "      <TAG idref ='2'>");
  m_outputFileXML << output << endl;
  sprintf(output, "        <IOV idref='1'>");
  m_outputFileXML << output << endl;
  sprintf(output, "          <DATA_SET idref='-1' />");
  m_outputFileXML << output << endl;
  sprintf(output, "        </IOV>");
  m_outputFileXML << output << endl;
  sprintf(output, "      </TAG>");
  m_outputFileXML << output << endl;
  sprintf(output, "  </MAPS>");
  m_outputFileXML << output << endl;


}
HcalLedAnalysis::~HcalLedAnalysis ( )

Destructor.

All done, clean up!!

Definition at line 138 of file HcalLedAnalysis.cc.

References i.

                                 {
  for(_meol=hbHists.LEDTRENDS.begin(); _meol!=hbHists.LEDTRENDS.end(); _meol++){
    for(int i=0; i<15; i++) _meol->second[i].first->Delete();
  }
  for(_meol=hoHists.LEDTRENDS.begin(); _meol!=hoHists.LEDTRENDS.end(); _meol++){
    for(int i=0; i<15; i++) _meol->second[i].first->Delete();
  }
  for(_meol=hfHists.LEDTRENDS.begin(); _meol!=hfHists.LEDTRENDS.end(); _meol++){
    for(int i=0; i<15; i++) _meol->second[i].first->Delete();
  }
  hbHists.ALLLEDS->Delete();
  hbHists.LEDRMS->Delete();
  hbHists.LEDMEAN->Delete();
  hbHists.CHI2->Delete();

  hoHists.ALLLEDS->Delete();
  hoHists.LEDRMS->Delete();
  hoHists.LEDMEAN->Delete();
  hoHists.CHI2->Delete();

  hfHists.ALLLEDS->Delete();
  hfHists.LEDRMS->Delete();
  hfHists.LEDMEAN->Delete();
  hfHists.CHI2->Delete();
}

Member Function Documentation

float HcalLedAnalysis::BinsizeCorr ( float  time) [private]

Definition at line 885 of file HcalLedAnalysis.cc.

References i.

                                             {

// this is the bin size correction to be applied for laser data (from Andy),
// it comes from a pulse shape measured from TB04 data (from Jordan)
// This should eventually be replaced with the more thorough treatment from Phil

  float corrtime=0.;
  static const float tstrue[32]={0.003, 0.03425, 0.06548, 0.09675, 0.128,
 0.15925, 0.1905, 0.22175, 0.253, 0.28425, 0.3155, 0.34675, 0.378, 0.40925,
 0.4405, 0.47175, 0.503, 0.53425, 0.5655, 0.59675, 0.628, 0.65925, 0.6905,
 0.72175, 0.753, 0.78425, 0.8155, 0.84675, 0.878, 0.90925, 0.9405, 0.97175};
  static const float tsreco[32]={-0.00422, 0.01815, 0.04409, 0.07346, 0.09799,
 0.12192, 0.15072, 0.18158, 0.21397, 0.24865, 0.28448, 0.31973, 0.35449,
 0.39208, 0.43282, 0.47244, 0.5105, 0.55008, 0.58827, 0.62828, 0.6717, 0.70966,
 0.74086, 0.77496, 0.80843, 0.83472, 0.86044, 0.8843, 0.90674, 0.92982,
 0.95072, 0.9726};

 int inttime=(int)time;
 float restime=time-inttime;
 for(int i=0; i<=32; i++) {
   float lolim=0.; float uplim=1.; float tsdown; float tsup;
   if(i>0){
     lolim=tsreco[i-1];
     tsdown=tstrue[i-1];
   }
   else tsdown=tstrue[31]-1.;
   if(i<32){
     uplim=tsreco[i];
     tsup=tstrue[i];
   }
   else tsup=tstrue[0]+1.;
   if(restime>=lolim && restime<uplim){
      corrtime=(tsdown*(uplim-restime)+tsup*(restime-lolim)) / (uplim-lolim);
    }
  }
  corrtime+=inttime;

 return corrtime;
}
void HcalLedAnalysis::GetLedConst ( std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT) [private]

Definition at line 155 of file CastorLedAnalysis.cc.

References HcalDetId::depth(), cond::rpcobgas::detid, i, HcalDetId::ietaAbs(), HcalDetId::iphi(), j, convertSQLitetoXML_cfg::output, DetId::rawId(), mathSSE::sqrt(), HcalDetId::subdet(), and HcalDetId::zside().

                                                                            {
  double time2=0; double time1=0; double time3=0; double time4=0;
  double dtime2=0; double dtime1=0; double dtime3=0; double dtime4=0;

  if (m_outputFileText!=""){
    if(m_fitflag==0 || m_fitflag==2) m_outFile<<"Det Eta,Phi,D   Mean    Error"<<std::endl;
    else if(m_fitflag==1 || m_fitflag==3) m_outFile<<"Det Eta,Phi,D   Peak    Error"<<std::endl;
    else if(m_fitflag==4) m_outFile<<"Det Eta,Phi,D   Mean    Error      Peak    Error       MeanEv  Error       PeakEv  Error"<<std::endl;
  }
  for(_meol=toolT.begin(); _meol!=toolT.end(); _meol++){
// scale the LED pulse to 1 event
    _meol->second[10].first->Scale(1./evt_curr);
    if(m_fitflag==0 || m_fitflag==4){
      time1 = _meol->second[10].first->GetMean();
      dtime1 = _meol->second[10].first->GetRMS()/sqrt((float)evt_curr*(m_endTS-m_startTS+1));
    }
    if(m_fitflag==1 || m_fitflag==4){
// put proper errors
      for(int j=0; j<10; j++) _meol->second[10].first->SetBinError(j+1,_meol->second[j].first->GetRMS()/sqrt((float)evt_curr));
    }
    if(m_fitflag==1 || m_fitflag==3 || m_fitflag==4){
      _meol->second[10].first->Fit("landau","Q");
//      _meol->second[10].first->Fit("gaus","Q");
      TF1 *fit = _meol->second[10].first->GetFunction("landau");
//      TF1 *fit = _meol->second[10].first->GetFunction("gaus");
      time2=fit->GetParameter(1);
      dtime2=fit->GetParError(1);
    }
    if(m_fitflag==2 || m_fitflag==4){
      time3 = _meol->second[12].first->GetMean();
      dtime3 = _meol->second[12].first->GetRMS()/sqrt((float)_meol->second[12].first->GetEntries());
    }
    if(m_fitflag==3 || m_fitflag==4){
      time4 = _meol->second[13].first->GetMean();
      dtime4 = _meol->second[13].first->GetRMS()/sqrt((float)_meol->second[13].first->GetEntries());
    }
    for (int i=0; i<10; i++){
      _meol->second[i].first->GetXaxis()->SetTitle("Pulse height (fC)");
      _meol->second[i].first->GetYaxis()->SetTitle("Counts");
//      if(m_hiSaveflag>0)_meol->second[i].first->Write();
    }
    _meol->second[10].first->GetXaxis()->SetTitle("Time slice");
    _meol->second[10].first->GetYaxis()->SetTitle("Averaged pulse (fC)");
    if(m_hiSaveflag>0)_meol->second[10].first->Write();
    _meol->second[10].second.first[0].push_back(time1);
    _meol->second[10].second.first[1].push_back(dtime1);
    _meol->second[11].second.first[0].push_back(time2);
    _meol->second[11].second.first[1].push_back(dtime2);
    _meol->second[12].first->GetXaxis()->SetTitle("Mean TS");
    _meol->second[12].first->GetYaxis()->SetTitle("Counts");
    if(m_fitflag==2 && m_hiSaveflag>0)_meol->second[12].first->Write();
    _meol->second[12].second.first[0].push_back(time3);
    _meol->second[12].second.first[1].push_back(dtime3);
    _meol->second[13].first->GetXaxis()->SetTitle("Peak TS");
    _meol->second[13].first->GetYaxis()->SetTitle("Counts");
    if(m_fitflag>2 && m_hiSaveflag>0)_meol->second[13].first->Write();
    _meol->second[13].second.first[0].push_back(time4);
    _meol->second[13].second.first[1].push_back(dtime4);
    _meol->second[14].first->GetXaxis()->SetTitle("Peak TS error");
    _meol->second[14].first->GetYaxis()->SetTitle("Counts");
    if(m_fitflag>2 && m_hiSaveflag>0)_meol->second[14].first->Write();
    _meol->second[15].first->GetXaxis()->SetTitle("Chi2/NDF");
    _meol->second[15].first->GetYaxis()->SetTitle("Counts");
    if(m_fitflag>2 && m_hiSaveflag>0)_meol->second[15].first->Write();
    _meol->second[16].first->GetXaxis()->SetTitle("Integrated Signal");
    _meol->second[16].first->Write();


// Ascii printout (need to modify to include new info)
    HcalDetId detid = _meol->first;

    if (m_outputFileText!=""){
      if(m_fitflag==0) {
        m_outFile<<detid<<"   "<<time1<<" "<<dtime1<<std::endl;
        sprintf(output, "  <DATA_SET>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <VERSION>version:1</VERSION>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <CHANNEL>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <EXTENSION_TABLE_NAME>HCAL_CHANNELS</EXTENSION_TABLE_NAME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <ETA>%2i</ETA>", detid.ietaAbs() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <PHI>%2i</PHI>", detid.iphi() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <DEPTH>%2i</DEPTH>", detid.depth() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <Z>%2i</Z>", detid.zside() );
        m_outputFileXML << output << endl;
        if(detid.subdet() == 1) sprintf(output, "      <DETECTOR_NAME>HB</DETECTOR_NAME>");
        if(detid.subdet() == 2) sprintf(output, "      <DETECTOR_NAME>HE</DETECTOR_NAME>");
        if(detid.subdet() == 3) sprintf(output, "      <DETECTOR_NAME>HO</DETECTOR_NAME>");
        if(detid.subdet() == 4) sprintf(output, "      <DETECTOR_NAME>HF</DETECTOR_NAME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <HCAL_CHANNEL_ID>%10i</HCAL_CHANNEL_ID>", detid.rawId() );
        m_outputFileXML << output << endl;
        sprintf(output, "    </CHANNEL>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <DATA>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <MEAN_TIME>%7f</MEAN_TIME>", time1);
        m_outputFileXML << output << endl;
        sprintf(output, "      <OFFSET_TIME> 0</OFFSET_TIME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <ERROR_STAT>%7f</ERROR_STAT>", dtime1);
        m_outputFileXML << output << endl;
        sprintf(output, "      <ANALYSIS_FLAG>%2i</ANALYSIS_FLAG>", m_fitflag+1);
        m_outputFileXML << output << endl;
        sprintf(output, "      <STATUS_WORD>  0</STATUS_WORD>");
        m_outputFileXML << output << endl;
        sprintf(output, "    </DATA>");
        m_outputFileXML << output << endl;
        sprintf(output, "  </DATA_SET>");
        m_outputFileXML << output << endl;

        }
      else if(m_fitflag==1){
        m_outFile<<detid<<"   "<<time2<<" "<<dtime2<<std::endl;
        sprintf(output, "  <DATA_SET>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <VERSION>version:1</VERSION>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <CHANNEL>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <EXTENSION_TABLE_NAME>HCAL_CHANNELS</EXTENSION_TABLE_NAME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <ETA>%2i</ETA>", detid.ietaAbs() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <PHI>%2i</PHI>", detid.iphi() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <DEPTH>%2i</DEPTH>", detid.depth() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <Z>%2i</Z>", detid.zside() );
        m_outputFileXML << output << endl;
        if(detid.subdet() == 1) sprintf(output, "      <DETECTOR_NAME>HB</DETECTOR_NAME>");
        if(detid.subdet() == 2) sprintf(output, "      <DETECTOR_NAME>HE</DETECTOR_NAME>");
        if(detid.subdet() == 3) sprintf(output, "      <DETECTOR_NAME>HO</DETECTOR_NAME>");
        if(detid.subdet() == 4) sprintf(output, "      <DETECTOR_NAME>HF</DETECTOR_NAME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <HCAL_CHANNEL_ID>%10i</HCAL_CHANNEL_ID>", detid.rawId() );
        m_outputFileXML << output << endl;
        sprintf(output, "    </CHANNEL>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <DATA>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <MEAN_TIME>%7f</MEAN_TIME>", time2);
        m_outputFileXML << output << endl;
        sprintf(output, "      <OFFSET_TIME> 0</OFFSET_TIME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <ERROR_STAT>%7f</ERROR_STAT>", dtime2);
        m_outputFileXML << output << endl;
        sprintf(output, "      <ANALYSIS_FLAG>%2i</ANALYSIS_FLAG>", m_fitflag+1);
        m_outputFileXML << output << endl;
        sprintf(output, "      <STATUS_WORD>  0</STATUS_WORD>");
        m_outputFileXML << output << endl;
        sprintf(output, "    </DATA>");
        m_outputFileXML << output << endl;
        sprintf(output, "  </DATA_SET>");
        m_outputFileXML << output << endl;
        }

      else if(m_fitflag==2){
        m_outFile<<detid<<"   "<<time3<<" "<<dtime3<<std::endl;
        sprintf(output, "  <DATA_SET>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <VERSION>version:1</VERSION>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <CHANNEL>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <EXTENSION_TABLE_NAME>HCAL_CHANNELS</EXTENSION_TABLE_NAME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <ETA>%2i</ETA>", detid.ietaAbs() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <PHI>%2i</PHI>", detid.iphi() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <DEPTH>%2i</DEPTH>", detid.depth() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <Z>%2i</Z>", detid.zside() );
        m_outputFileXML << output << endl;
        if(detid.subdet() == 1) sprintf(output, "      <DETECTOR_NAME>HB</DETECTOR_NAME>");
        if(detid.subdet() == 2) sprintf(output, "      <DETECTOR_NAME>HE</DETECTOR_NAME>");
        if(detid.subdet() == 3) sprintf(output, "      <DETECTOR_NAME>HO</DETECTOR_NAME>");
        if(detid.subdet() == 4) sprintf(output, "      <DETECTOR_NAME>HF</DETECTOR_NAME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <HCAL_CHANNEL_ID>%10i</HCAL_CHANNEL_ID>", detid.rawId() );
        m_outputFileXML << output << endl;
        sprintf(output, "    </CHANNEL>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <DATA>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <MEAN_TIME>%7f</MEAN_TIME>", time3);
        m_outputFileXML << output << endl;
        sprintf(output, "      <OFFSET_TIME> 0</OFFSET_TIME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <ERROR_STAT>%7f</ERROR_STAT>", dtime3);
        m_outputFileXML << output << endl;
        sprintf(output, "      <ANALYSIS_FLAG>%2i</ANALYSIS_FLAG>", m_fitflag+1);
        m_outputFileXML << output << endl;
        sprintf(output, "      <STATUS_WORD>  0</STATUS_WORD>");
        m_outputFileXML << output << endl;
        sprintf(output, "    </DATA>");
        m_outputFileXML << output << endl;
        sprintf(output, "  </DATA_SET>");
        m_outputFileXML << output << endl;
        }
      else if(m_fitflag==3){
        m_outFile<<detid<<"   "<<time4<<" "<<dtime4<<std::endl;
        sprintf(output, "  <DATA_SET>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <VERSION>version:1</VERSION>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <CHANNEL>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <EXTENSION_TABLE_NAME>HCAL_CHANNELS</EXTENSION_TABLE_NAME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <ETA>%2i</ETA>", detid.ietaAbs() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <PHI>%2i</PHI>", detid.iphi() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <DEPTH>%2i</DEPTH>", detid.depth() );
        m_outputFileXML << output << endl;
        sprintf(output, "      <Z>%2i</Z>", detid.zside() );
        m_outputFileXML << output << endl;
        if(detid.subdet() == 1) sprintf(output, "      <DETECTOR_NAME>HB</DETECTOR_NAME>");
        if(detid.subdet() == 2) sprintf(output, "      <DETECTOR_NAME>HE</DETECTOR_NAME>");
        if(detid.subdet() == 3) sprintf(output, "      <DETECTOR_NAME>HO</DETECTOR_NAME>");
        if(detid.subdet() == 4) sprintf(output, "      <DETECTOR_NAME>HF</DETECTOR_NAME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <HCAL_CHANNEL_ID>%10i</HCAL_CHANNEL_ID>", detid.rawId() );
        m_outputFileXML << output << endl;
        sprintf(output, "    </CHANNEL>");
        m_outputFileXML << output << endl;
        sprintf(output, "    <DATA>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <MEAN_TIME>%7f</MEAN_TIME>", time4);
        m_outputFileXML << output << endl;
        sprintf(output, "      <OFFSET_TIME> 0</OFFSET_TIME>");
        m_outputFileXML << output << endl;
        sprintf(output, "      <ERROR_STAT>%7f</ERROR_STAT>", dtime4);
        m_outputFileXML << output << endl;
        sprintf(output, "      <ANALYSIS_FLAG>%2i</ANALYSIS_FLAG>", m_fitflag+1);
        m_outputFileXML << output << endl;
        sprintf(output, "      <STATUS_WORD>  0</STATUS_WORD>");
        m_outputFileXML << output << endl;
        sprintf(output, "    </DATA>");
        m_outputFileXML << output << endl;
        sprintf(output, "  </DATA_SET>");
        m_outputFileXML << output << endl;
        }

      else if(m_fitflag==4){
        m_outFile<<detid<<"   "<<time1<<" "<<dtime1<<"   "<<time2<<" "<<dtime2<<"   "<<time3<<" "<<dtime3<<"   "<<time4<<" "<<dtime4<<std::endl;
        }
    }
  }
}
void HcalLedAnalysis::LedDone ( )

Definition at line 508 of file HcalLedAnalysis.cc.

References gather_cfg::cout.

Referenced by HcalLedAnalyzer::endJob().

{

// First process the last sample (remaining events).
  if(evt%m_nevtsample!=0) LedSampleAnalysis();

// Now do the end of run analysis: trending histos
  if(sample>1 && m_fitflag!=4){
    m_file->cd();
    m_file->cd("HBHE");
    LedTrendings(hbHists.LEDTRENDS);
    m_file->cd();
    m_file->cd("HO");
    LedTrendings(hoHists.LEDTRENDS);
    m_file->cd();
    m_file->cd("HF");
    LedTrendings(hfHists.LEDTRENDS);
  }

  // Write other histograms.
  // HB
  m_file->cd();
  m_file->cd("HBHE");
  hbHists.ALLLEDS->Write();
  hbHists.LEDRMS->Write();
  hbHists.LEDMEAN->Write();
  // HO
  m_file->cd();
  m_file->cd("HO");
  hoHists.ALLLEDS->Write();
  hoHists.LEDRMS->Write();
  hoHists.LEDMEAN->Write();
  // HF
  m_file->cd();
  m_file->cd("HF");
  hfHists.ALLLEDS->Write();
  hfHists.LEDRMS->Write();
  hfHists.LEDMEAN->Write();
  // Calib
  m_file->cd();
  m_file->cd("Calib");
  for(_meca=calibHists.begin(); _meca!=calibHists.end(); _meca++){
    _meca->second.avePulse->Write();
    _meca->second.integPulse->Write();
  }

  // Write the histo file and close it
//  m_file->Write();
  m_file->Close();
  cout << "Hcal histograms written to " << m_outputFileROOT.c_str() << endl;
}
void HcalLedAnalysis::LedHBHEHists ( const HcalDetId detid,
const HBHEDataFrame ledDigi,
std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT,
const HcalDbService cond 
) [private]

Definition at line 681 of file HcalLedAnalysis.cc.

References ecalMGPA::adc(), first, HcalDbService::getHcalCoder(), HcalDbService::getHcalShape(), HcalDbService::getPedestal(), i, gen::k, and HBHEDataFrame::size().

                                                                                                                                                            {

  map<int,LEDBUNCH> _mei;
  _meol = toolT.find(detid);
  _mei = _meol->second;

  // Reset the histos if we're at the end of a 'bunch'
  if((evt-1)%m_nevtsample==0 && state[0]){
    for(int k=0; k<(int)state.size();k++) state[k]=false;
    for(int i=0; i<16; i++) _mei[i].first->Reset();
  }

  // Most of this is borrowed from HcalSimpleReconstructor, so thanks Jeremy/Phil


  int maxTS = -1;
  float max_fC = 0;
  float ta = 0;
  m_coder = cond.getHcalCoder(detid);
  m_ped = cond.getPedestal(detid);
  m_shape = cond.getHcalShape();
  for (int TS = m_startTS; TS < m_endTS && TS < ledDigi.size(); TS++){
    int capid = ledDigi[TS].capid();
    int adc = ledDigi[TS].adc();
    double fC = m_coder->charge(*m_shape,adc,capid);
    ta = (fC - m_ped->getValue(capid));
    //cout << "DetID: " << detid << "  CapID: " << capid << "  ADC: " << adc << "  fC: " << fC << endl;
    _mei[TS].first->Fill(ta);
    _mei[10].first->AddBinContent(TS+1,ta);  // This is average pulse, could probably do better (Profile?)
    if(m_fitflag>1){
      if(TS==m_startTS)_mei[11].first->Reset();
      _mei[11].first->SetBinContent(TS+1,ta);
    }
    // keep track of max TS and max amplitude (in fC)
    if (ta > max_fC){
      max_fC = ta;
      maxTS = TS;
    }
  }

  // Now we have a sample with pedestals subtracted and in units of fC
  // If we are using a weighted mean (m_fitflag = 2) to extraxt timing
  // we now want to use Phil's timing correction.  This is not necessary
  // if we are performing a Landau fit (m_fitflag = 3)

  float sum=0.;
  for(int i=0; i<10; i++)sum=sum+_mei[11].first->GetBinContent(i+1);
  if(sum>100){
    if(m_fitflag==2 || m_fitflag==4){
      float timmean=_mei[11].first->GetMean();  // let's use Phil's way instead
      float timmeancorr=BinsizeCorr(timmean);
      _mei[12].first->Fill(timmeancorr);
    }
    _mei[16].first->Fill(_mei[11].first->Integral()); // Integrated charge (may be more usfull to convert to Energy first?)
    if(m_fitflag==3 || m_fitflag==4){
      _mei[11].first->Fit("landau","Q");
      TF1 *fit = _mei[11].first->GetFunction("landau");
      _mei[13].first->Fill(fit->GetParameter(1));
      _mei[14].first->Fill(fit->GetParError(1));
      _mei[15].first->Fill(fit->GetChisquare()/fit->GetNDF());
    }
  }

}
void HcalLedAnalysis::LedHFHists ( const HcalDetId detid,
const HFDataFrame ledDigi,
std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT,
const HcalDbService cond 
) [private]

Definition at line 811 of file HcalLedAnalysis.cc.

References ecalMGPA::adc(), first, HcalDbService::getHcalCoder(), HcalDbService::getHcalShape(), HcalDbService::getPedestal(), i, gen::k, and HFDataFrame::size().

                                                                                                                                                         {

  map<int,LEDBUNCH> _mei;
  _meol = toolT.find(detid);
  _mei = _meol->second;
  // Rest the histos if we're at the end of a 'bunch'
  if((evt-1)%m_nevtsample==0 && state[0]){
    for(int k=0; k<(int)state.size();k++) state[k]=false;
    for(int i=0; i<16; i++) _mei[i].first->Reset();
  }

  // now we have the signal in fC, let's get rid of that darn pedestal
  // Most of this is borrowed from HcalSimpleReconstructor, so thanks Jeremy/Phil

  int maxTS = -1;
  float max_fC = 0;
  float ta = 0;
  m_coder = cond.getHcalCoder(detid);
  m_ped = cond.getPedestal(detid);
  m_shape = cond.getHcalShape();
  //cout << "New Digi!!!!!!!!!!!!!!!!!!!!!!" << endl;
  for (int TS = m_startTS; TS < m_endTS && TS < ledDigi.size(); TS++){
    int capid = ledDigi[TS].capid();
    // BE CAREFUL: this is assuming peds are stored in ADCs
    int adc = (int)(ledDigi[TS].adc() - m_ped->getValue(capid));
    if (adc < 0){ adc = 0; }  // to prevent negative adcs after ped subtraction, which should really only happen
                              // if you're using the wrong peds.
    double fC = m_coder->charge(*m_shape,adc,capid);
    //ta = (fC - m_ped->getValue(capid));
    ta = fC;
    //cout << "DetID: " << detid << "  CapID: " << capid << "  ADC: " << adc << "  Ped: " << m_ped->getValue(capid) << "  fC: " << fC << endl;
    _mei[TS].first->Fill(ta);
    _mei[10].first->AddBinContent(TS+1,ta);  // This is average pulse, could probably do better (Profile?)
    if(m_fitflag>1){
      if(TS==m_startTS)_mei[11].first->Reset();
      _mei[11].first->SetBinContent(TS+1,ta);
    }

    // keep track of max TS and max amplitude (in fC)
    if (ta > max_fC){
      max_fC = ta;
      maxTS = TS;
    }
  }

  // Now we have a sample with pedestals subtracted and in units of fC
  // If we are using a weighted mean (m_fitflag = 2) to extraxt timing
  // we now want to use Phil's timing correction.  This is not necessary
  // if we are performing a Landau fit (m_fitflag = 3)

  float sum=0.;
  for(int i=0; i<10; i++)sum=sum+_mei[11].first->GetBinContent(i+1);
  if(sum>100){
    if(m_fitflag==2 || m_fitflag==4){
      float timmean=_mei[11].first->GetMean();  // let's use Phil's way instead
      float timmeancorr=BinsizeCorr(timmean);
      _mei[12].first->Fill(timmeancorr);
    }
    _mei[16].first->Fill(_mei[11].first->Integral()); // Integrated charge (may be more usfull to convert to Energy first?)
    if(m_fitflag==3 || m_fitflag==4){
      _mei[11].first->Fit("landau","Q");
      TF1 *fit = _mei[11].first->GetFunction("landau");
      _mei[13].first->Fill(fit->GetParameter(1));
      _mei[14].first->Fill(fit->GetParError(1));
      _mei[15].first->Fill(fit->GetChisquare()/fit->GetNDF());
    }
  }



}
void HcalLedAnalysis::LedHOHists ( const HcalDetId detid,
const HODataFrame ledDigi,
std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT,
const HcalDbService cond 
) [private]

Definition at line 747 of file HcalLedAnalysis.cc.

References ecalMGPA::adc(), first, HcalDbService::getHcalCoder(), HcalDbService::getHcalShape(), HcalDbService::getPedestal(), i, gen::k, and HODataFrame::size().

                                                                                                                                                         {

  map<int,LEDBUNCH> _mei;
  _meol = toolT.find(detid);
  _mei = _meol->second;
  // Rest the histos if we're at the end of a 'bunch'
  if((evt-1)%m_nevtsample==0 && state[0]){
    for(int k=0; k<(int)state.size();k++) state[k]=false;
    for(int i=0; i<16; i++) _mei[i].first->Reset();
  }

  // now we have the signal in fC, let's get rid of that darn pedestal
  // Most of this is borrowed from HcalSimpleReconstructor, so thanks Jeremy/Phil

  int maxTS = -1;
  float max_fC = 0;
  float ta = 0;
  m_coder = cond.getHcalCoder(detid);
  m_ped = cond.getPedestal(detid);
  m_shape = cond.getHcalShape();
  for (int TS = m_startTS; TS < m_endTS && TS < ledDigi.size(); TS++){
    int capid = ledDigi[TS].capid();
    int adc = ledDigi[TS].adc();
    double fC = m_coder->charge(*m_shape,adc,capid);
    ta = (fC - m_ped->getValue(capid));
    _mei[TS].first->Fill(ta);
    _mei[10].first->AddBinContent(TS+1,ta);  // This is average pulse, could probably do better (Profile?)
    if(m_fitflag>1){
      if(TS==m_startTS)_mei[11].first->Reset();
      _mei[11].first->SetBinContent(TS+1,ta);
    }
    // keep track of max TS and max amplitude (in fC)
    if (ta > max_fC){
      max_fC = ta;
      maxTS = TS;
    }
  }

  // Now we have a sample with pedestals subtracted and in units of fC
  // If we are using a weighted mean (m_fitflag = 2) to extraxt timing
  // we now want to use Phil's timing correction.  This is not necessary
  // if we are performing a Landau fit (m_fitflag = 3)

  float sum=0.;
  for(int i=0; i<10; i++)sum=sum+_mei[11].first->GetBinContent(i+1);
  if(sum>100){
    if(m_fitflag==2 || m_fitflag==4){
      float timmean=_mei[11].first->GetMean();  // let's use Phil's way instead
      float timmeancorr=BinsizeCorr(timmean);
      _mei[12].first->Fill(timmeancorr);
    }
    _mei[16].first->Fill(_mei[11].first->Integral()); // Integrated charge (may be more usfull to convert to Energy first?)
    if(m_fitflag==3 || m_fitflag==4){
      _mei[11].first->Fit("landau","Q");
      TF1 *fit = _mei[11].first->GetFunction("landau");
      _mei[13].first->Fill(fit->GetParameter(1));
      _mei[14].first->Fill(fit->GetParError(1));
      _mei[15].first->Fill(fit->GetChisquare()/fit->GetNDF());
    }
  }

}
void HcalLedAnalysis::LedSampleAnalysis ( )

Definition at line 460 of file HcalLedAnalysis.cc.

                                       {
  // it is called every m_nevtsample events (a sample) and the end of run
  char LedSampleNum[20];

  sprintf(LedSampleNum,"LedSample_%d",sample);
  m_file->cd();
  m_file->mkdir(LedSampleNum);
  m_file->cd(LedSampleNum);

// Compute LED constants for each HB/HE, HO, HF
  GetLedConst(hbHists.LEDTRENDS);
  GetLedConst(hoHists.LEDTRENDS);
  GetLedConst(hfHists.LEDTRENDS);
}
void HcalLedAnalysis::LedSetup ( const std::string &  m_outputFileROOT)

Definition at line 166 of file HcalLedAnalysis.cc.

Referenced by HcalLedAnalyzer::HcalLedAnalyzer().

                                                                {
  // open the histogram file, create directories within
  m_file=new TFile(m_outputFileROOT.c_str(),"RECREATE");
  m_file->mkdir("HBHE");
  m_file->cd();
  m_file->mkdir("HO");
  m_file->cd();
  m_file->mkdir("HF");
  m_file->cd();
  m_file->mkdir("Calib");
  m_file->cd();
}
void HcalLedAnalysis::LedTrendings ( std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT) [private]

Definition at line 428 of file CastorLedAnalysis.cc.

References HcalDetId::depth(), cond::rpcobgas::detid, HcalDetId::ieta(), HcalDetId::iphi(), j, and AlCaRecoCosmics_cfg::name.

{

  for(_meol=toolT.begin(); _meol!=toolT.end(); _meol++){
    char name[1024];
    HcalDetId detid = _meol->first;
    sprintf(name,"LED timing trend, eta=%d phi=%d depth=%d",detid.ieta(),detid.iphi(),detid.depth());
    int bins = _meol->second[10+m_fitflag].second.first[0].size();
    float lo =0.5;
    float hi = (float)bins+0.5;
    _meol->second[10+m_fitflag].second.second.push_back(new TH1F(name,name,bins,lo,hi));

    std::vector<double>::iterator sample_it;
// LED timing - put content and errors
    int j=0;
    for(sample_it=_meol->second[10+m_fitflag].second.first[0].begin();
        sample_it!=_meol->second[10+m_fitflag].second.first[0].end();sample_it++){
      _meol->second[10+m_fitflag].second.second[0]->SetBinContent(++j,*sample_it);
    }
    j=0;
    for(sample_it=_meol->second[10+m_fitflag].second.first[1].begin();
        sample_it!=_meol->second[10+m_fitflag].second.first[1].end();sample_it++){
      _meol->second[10+m_fitflag].second.second[0]->SetBinError(++j,*sample_it);
    }
    sprintf(name,"Sample (%d events)",m_nevtsample);
    _meol->second[10+m_fitflag].second.second[0]->GetXaxis()->SetTitle(name);
    _meol->second[10+m_fitflag].second.second[0]->GetYaxis()->SetTitle("Peak position");
    _meol->second[10+m_fitflag].second.second[0]->Write();
  }
}
void HcalLedAnalysis::ProcessCalibEvent ( int  fiberChan,
HcalCalibDetId  calibId,
const HcalCalibDataFrame  digi 
) [private]

Definition at line 930 of file HcalLedAnalysis.cc.

References HcalQIESample::adc(), HcalCalibDetId::calibFlavor(), HcalCalibDetId::CalibrationBox, HcalCalibDetId::cboxChannelString(), HcalBarrel, HcalEndcap, HcalForward, HcalOuter, HcalCalibDetId::hcalSubdet(), i, HcalCalibDetId::ieta(), HcalCalibDetId::iphi(), AlCaRecoCosmics_cfg::name, prof2calltree::prefix, HcalCalibDataFrame::sample(), and HcalCalibDataFrame::size().

                                                                                                           {

  _meca = calibHists.find(calibId);
  if (_meca==calibHists.end()){
  // if histos for this channel do not exist, first create them
    char name[1024];
    std::string prefix;
    if (calibId.calibFlavor()==HcalCalibDetId::CalibrationBox) {
      std::string sector=(calibId.hcalSubdet()==HcalBarrel)?("HB"):
        (calibId.hcalSubdet()==HcalEndcap)?("HE"):
        (calibId.hcalSubdet()==HcalOuter)?("HO"):
        (calibId.hcalSubdet()==HcalForward)?("HF"):"";
      sprintf(name,"%s %+d iphi=%d %s",sector.c_str(),calibId.ieta(),calibId.iphi(),calibId.cboxChannelString().c_str());
      prefix=name;
    }
    
    sprintf(name,"%s Pin Diode Mean",prefix.c_str());
    calibHists[calibId].avePulse = new TProfile(name,name,10,-0.5,9.5,0,1000);
    sprintf(name,"%s Pin Diode Current Pulse",prefix.c_str());
    calibHists[calibId].thisPulse = new TH1F(name,name,10,-0.5,9.5);
    sprintf(name,"%s Pin Diode Integrated Pulse",prefix.c_str());
    calibHists[calibId].integPulse = new TH1F(name,name,200,0,500);    
  }
  else {
    for (int i=m_startTS; i<digi.size() && i<=m_endTS; i++) {
      calibHists[calibId].avePulse->Fill(i,digi.sample(i).adc());
      calibHists[calibId].thisPulse->SetBinContent(i+1,digi.sample(i).adc());
    }
    calibHists[calibId].integPulse->Fill(calibHists[calibId].thisPulse->Integral());
  }
}
void HcalLedAnalysis::processLedEvent ( const HBHEDigiCollection hbhe,
const HODigiCollection ho,
const HFDigiCollection hf,
const HcalCalibDigiCollection  calib,
const HcalDbService cond 
)

Definition at line 561 of file HcalLedAnalysis.cc.

References edm::SortedCollection< T, SORT >::begin(), HcalCalibDataFrame::elecId(), edm::SortedCollection< T, SORT >::end(), HcalElectronicsId::fiberChanId(), i, HODataFrame::id(), HBHEDataFrame::id(), HcalCalibDataFrame::id(), HFDataFrame::id(), gen::k, and edm::SortedCollection< T, SORT >::size().

Referenced by HcalLedAnalyzer::analyze().

{
  evt++;
  sample = (evt-1)/m_nevtsample +1;
  evt_curr = evt%m_nevtsample;
  if(evt_curr==0)evt_curr=m_nevtsample;

  // Calib

  if (m_usecalib){
    try{
      if(!calib.size()) throw (int)calib.size();
      // this is effectively a loop over electronic channels
      for (HcalCalibDigiCollection::const_iterator j=calib.begin(); j!=calib.end(); j++){
        const HcalCalibDataFrame digi = (const HcalCalibDataFrame)(*j);   
        HcalElectronicsId elecId = digi.elecId();
        HcalCalibDetId calibId = digi.id();
        ProcessCalibEvent(elecId.fiberChanId(),calibId,digi);  //Shouldn't depend on anything in elecId but not sure how else to do it 
      }
    }
    catch (int i ) {
    //  m_logFile<< "Event with " << i<<" Calib Digis passed." << std::endl;
    }
  }


  // HB + HE
  try{
    if(!hbhe.size()) throw (int)hbhe.size();
// this is effectively a loop over electronic channels
    for (HBHEDigiCollection::const_iterator j=hbhe.begin(); j!=hbhe.end(); j++){
      const HBHEDataFrame digi = (const HBHEDataFrame)(*j);
      for(int k=0; k<(int)state.size();k++) state[k]=true;
      // See if histos exist for this channel, and if not, create them
      _meol = hbHists.LEDTRENDS.find(digi.id());
      if (_meol==hbHists.LEDTRENDS.end()){
        SetupLEDHists(0,digi.id(),hbHists.LEDTRENDS);
      }
      LedHBHEHists(digi.id(),digi,hbHists.LEDTRENDS,cond);
    }
  }
  catch (int i ) {
//    m_logFile<< "Event with " << i<<" HBHE Digis passed." << std::endl;
  } 

  // HO
  try{
    if(!ho.size()) throw (int)ho.size();
    for (HODigiCollection::const_iterator j=ho.begin(); j!=ho.end(); j++){
      const HODataFrame digi = (const HODataFrame)(*j);
      _meol = hoHists.LEDTRENDS.find(digi.id());
      if (_meol==hoHists.LEDTRENDS.end()){
        SetupLEDHists(1,digi.id(),hoHists.LEDTRENDS);
      }
      LedHOHists(digi.id(),digi,hoHists.LEDTRENDS,cond);
    }        
  } 
  catch (int i ) {
//    m_logFile << "Event with " << i<<" HO Digis passed." << std::endl;
  } 

  // HF
  try{
    if(!hf.size()) throw (int)hf.size();
    for (HFDigiCollection::const_iterator j=hf.begin(); j!=hf.end(); j++){
      const HFDataFrame digi = (const HFDataFrame)(*j);
      _meol = hfHists.LEDTRENDS.find(digi.id());
      if (_meol==hfHists.LEDTRENDS.end()){
        SetupLEDHists(2,digi.id(),hfHists.LEDTRENDS);
      }
      LedHFHists(digi.id(),digi,hfHists.LEDTRENDS,cond);
    }
  } 
  catch (int i ) {
//    m_logFile << "Event with " << i<<" HF Digis passed." << std::endl;
  } 

  // Call the function every m_nevtsample events
  if(evt%m_nevtsample==0) LedSampleAnalysis();

}
void HcalLedAnalysis::SetupLEDHists ( int  id,
const HcalDetId  detid,
std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT 
) [private]

Definition at line 516 of file CastorLedAnalysis.cc.

References HcalDetId::depth(), cond::rpcobgas::detid, i, HcalDetId::ieta(), edm::eventsetup::heterocontainer::insert(), HcalDetId::iphi(), and AlCaRecoCosmics_cfg::name.

                                                                                                              {

  string type = "HBHE";
  if(id==1) type = "HO";
  if(id==2) type = "HF";

  _meol = toolT.find(detid);
  if (_meol==toolT.end()){
// if histos for this channel do not exist, create them
    map<int,LEDBUNCH> insert;
    char name[1024];
    for(int i=0; i<10; i++){
      sprintf(name,"%s Pulse height, eta=%d phi=%d depth=%d TS=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth(),i);
      insert[i].first =  new TH1F(name,name,200,0.,2000.);
    }
    sprintf(name,"%s LED Mean pulse, eta=%d phi=%d depth=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
    insert[10].first =  new TH1F(name,name,10,-0.5,9.5);
    sprintf(name,"%s LED Pulse, eta=%d phi=%d depth=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
    insert[11].first =  new TH1F(name,name,10,-0.5,9.5);
    sprintf(name,"%s Mean TS, eta=%d phi=%d depth=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
    insert[12].first =  new TH1F(name,name,200,0.,10.);
    sprintf(name,"%s Peak TS, eta=%d phi=%d depth=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
    insert[13].first =  new TH1F(name,name,200,0.,10.);
    sprintf(name,"%s Peak TS error, eta=%d phi=%d depth=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
    insert[14].first =  new TH1F(name,name,200,0.,0.05);
    sprintf(name,"%s Fit chi2, eta=%d phi=%d depth=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
    insert[15].first =  new TH1F(name,name,100,0.,50.);
    sprintf(name,"%s Integrated Signal, eta=%d phi=%d depth=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
    insert[16].first =  new TH1F(name,name,500,0.,5000.);

    toolT[detid] = insert;
  }
}

Member Data Documentation

std::map<HcalCalibDetId,CALIBBUNCH>::iterator HcalLedAnalysis::_meca [private]

Definition at line 122 of file HcalLedAnalysis.h.

std::map<HcalDetId,std::map<int,float> >::iterator HcalLedAnalysis::_meee [private]

Definition at line 119 of file HcalLedAnalysis.h.

std::map<HcalDetId,std::map<int, LEDBUNCH > >::iterator HcalLedAnalysis::_meol [private]

Definition at line 117 of file HcalLedAnalysis.h.

Definition at line 112 of file HcalLedAnalysis.h.

Definition at line 121 of file HcalLedAnalysis.h.

Definition at line 115 of file HcalLedAnalysis.h.

int HcalLedAnalysis::evt [private]

Definition at line 125 of file HcalLedAnalysis.h.

Definition at line 127 of file HcalLedAnalysis.h.

struct { ... } HcalLedAnalysis::hbHists [private]
struct { ... } HcalLedAnalysis::hfHists [private]
struct { ... } HcalLedAnalysis::hoHists [private]

Definition at line 114 of file HcalLedAnalysis.h.

Definition at line 113 of file HcalLedAnalysis.h.

std::map<HcalDetId,std::map<int, LEDBUNCH > > HcalLedAnalysis::LEDTRENDS

Definition at line 111 of file HcalLedAnalysis.h.

std::map<HcalDetId,std::map<int,float> > HcalLedAnalysis::m_AllPedVals [private]

Definition at line 118 of file HcalLedAnalysis.h.

Definition at line 108 of file HcalLedAnalysis.h.

int HcalLedAnalysis::m_endTS [private]

Definition at line 93 of file HcalLedAnalysis.h.

TFile* HcalLedAnalysis::m_file [private]

Definition at line 74 of file HcalLedAnalysis.h.

Definition at line 105 of file HcalLedAnalysis.h.

Definition at line 95 of file HcalLedAnalysis.h.

std::ofstream HcalLedAnalysis::m_logFile [private]

Definition at line 88 of file HcalLedAnalysis.h.

Definition at line 94 of file HcalLedAnalysis.h.

std::ofstream HcalLedAnalysis::m_outFile [private]

Definition at line 87 of file HcalLedAnalysis.h.

std::string HcalLedAnalysis::m_outputFileROOT [private]

Definition at line 84 of file HcalLedAnalysis.h.

std::string HcalLedAnalysis::m_outputFileText [private]

Definition at line 85 of file HcalLedAnalysis.h.

std::string HcalLedAnalysis::m_outputFileX [private]

Definition at line 86 of file HcalLedAnalysis.h.

std::ofstream HcalLedAnalysis::m_outputFileXML [private]

Definition at line 89 of file HcalLedAnalysis.h.

Definition at line 109 of file HcalLedAnalysis.h.

Definition at line 107 of file HcalLedAnalysis.h.

Definition at line 92 of file HcalLedAnalysis.h.

Definition at line 96 of file HcalLedAnalysis.h.

char HcalLedAnalysis::output[100] [private]

Definition at line 90 of file HcalLedAnalysis.h.

int HcalLedAnalysis::sample [private]

Definition at line 126 of file HcalLedAnalysis.h.

std::vector<bool> HcalLedAnalysis::state [private]

Definition at line 128 of file HcalLedAnalysis.h.