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CastorPedestalAnalysis Class Reference

#include <CastorPedestalAnalysis.h>

Public Member Functions

 CastorPedestalAnalysis (const edm::ParameterSet &ps)
 Constructor. More...
 
int done (const CastorPedestals *fInputPedestals, const CastorPedestalWidths *fInputWidths, CastorPedestals *fOutputPedestals, CastorPedestalWidths *fOutputWidths)
 
void processEvent (const CastorDigiCollection &castor, const CastorDbService &cond)
 
void SampleAnalysis ()
 
void setup (const std::string &m_outputFileROOT)
 
 ~CastorPedestalAnalysis ()
 Destructor. More...
 

Static Public Member Functions

static int CastorPedVal (int nstat[4], const CastorPedestals *fRefPedestals, const CastorPedestalWidths *fRefPedestalWidths, CastorPedestals *fRawPedestals, CastorPedestalWidths *fRawPedestalWidths, CastorPedestals *fValPedestals, CastorPedestalWidths *fValPedestalWidths)
 

Private Types

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

Private Member Functions

void AllChanHists (const HcalDetId detid, const HcalQIESample &qie0, const HcalQIESample &qie1, const HcalQIESample &qie2, const HcalQIESample &qie3, const HcalQIESample &qie4, const HcalQIESample &qie5, std::map< HcalDetId, std::map< int, PEDBUNCH > > &toolT)
 
void GetPedConst (std::map< HcalDetId, std::map< int, PEDBUNCH > > &toolT, TH1F *PedMeans, TH1F *PedWidths)
 
void per2CapsHists (int flag, int id, const HcalDetId detid, const HcalQIESample &qie1, const HcalQIESample &qie2, std::map< HcalDetId, std::map< int, PEDBUNCH > > &toolT, const CastorDbService &cond)
 
void Trendings (std::map< HcalDetId, std::map< int, PEDBUNCH > > &toolT, TH1F *Chi2, TH1F *CapidAverage, TH1F *CapidChi2)
 

Private Attributes

std::map< HcalDetId, std::map< int, PEDBUNCH > >::iterator _meot
 
struct {
   TH1F *   ALLPEDS
 
   TH1F *   CAPID_AVERAGE
 
   TH1F *   CAPID_CHI2
 
   TH1F *   CHI2
 
   TH1F *   PEDMEAN
 
   TH1F *   PEDRMS
 
   std::map< HcalDetId, std::map< int, PEDBUNCH > >   PEDTRENDS
 
castorHists
 
int evt
 
int evt_curr
 
CastorPedestalsfRawPedestals
 
CastorPedestalWidthsfRawPedestalWidths
 
const CastorPedestalsfRefPedestals
 
const CastorPedestalWidthsfRefPedestalWidths
 
CastorPedestalsfValPedestals
 
CastorPedestalWidthsfValPedestalWidths
 
int m_AllPedsOK
 
const CastorQIECoderm_coder
 
int m_endTS
 
TFile * m_file
 
int m_hiSaveflag
 
std::ofstream m_logFile
 
int m_nevtsample
 
std::string m_outputFileMean
 
std::string m_outputFileROOT
 
std::string m_outputFileWidth
 
int m_pedsinADC
 
int m_pedValflag
 
const CastorQIEShapem_shape
 
int m_startTS
 
float m_stat [4]
 
int sample
 
std::vector< bool > state
 

Static Private Attributes

static const int fitflag =0
 

Detailed Description

Definition at line 39 of file CastorPedestalAnalysis.h.

Member Typedef Documentation

typedef std::pair<TH1F*,std::pair<std::map<int, std::vector<double> >,std::vector<TH1F*> > > CastorPedestalAnalysis::PEDBUNCH
private

Definition at line 89 of file CastorPedestalAnalysis.h.

Constructor & Destructor Documentation

CastorPedestalAnalysis::CastorPedestalAnalysis ( const edm::ParameterSet ps)

Constructor.

Definition at line 15 of file CastorPedestalAnalysis.cc.

References castorHists, gather_cfg::cout, evt, edm::ParameterSet::getUntrackedParameter(), mps_fire::i, gen::k, m_AllPedsOK, m_endTS, m_file, m_hiSaveflag, m_nevtsample, m_outputFileMean, m_outputFileROOT, m_outputFileWidth, m_pedsinADC, m_pedValflag, m_startTS, m_stat, sample, and state.

16  : fRefPedestals (nullptr),
17  fRefPedestalWidths (nullptr),
18  fRawPedestals (nullptr),
19  fRawPedestalWidths (nullptr),
20  fValPedestals (nullptr),
21  fValPedestalWidths (nullptr)
22 {
23  evt=0;
24  sample=0;
25  m_file=nullptr;
26  m_AllPedsOK=0;
27  for(int i=0; i<4; i++) m_stat[i]=0;
28  for(int k=0;k<4;k++) state.push_back(true);
29 
30 // user cfg parameters
31  m_outputFileMean = ps.getUntrackedParameter<string>("outputFileMeans", "");
32  if ( !m_outputFileMean.empty() ) {
33  cout << "Castor pedestal means will be saved to " << m_outputFileMean.c_str() << endl;
34  }
35  m_outputFileWidth = ps.getUntrackedParameter<string>("outputFileWidths", "");
36  if ( !m_outputFileWidth.empty() ) {
37  cout << "Castor pedestal widths will be saved to " << m_outputFileWidth.c_str() << endl;
38  }
39  m_outputFileROOT = ps.getUntrackedParameter<string>("outputFileHist", "");
40  if ( !m_outputFileROOT.empty() ) {
41  cout << "Castor pedestal histograms will be saved to " << m_outputFileROOT.c_str() << endl;
42  }
43  m_nevtsample = ps.getUntrackedParameter<int>("nevtsample",0);
44 // for compatibility with previous versions
45  if(m_nevtsample==9999999) m_nevtsample=0;
46  m_pedsinADC = ps.getUntrackedParameter<int>("pedsinADC",0);
47  m_hiSaveflag = ps.getUntrackedParameter<int>("hiSaveflag",0);
48  m_pedValflag = ps.getUntrackedParameter<int>("pedValflag",0);
49  if(m_pedValflag<0) m_pedValflag=0;
50  if (m_nevtsample>0 && m_pedValflag>0) {
51  cout<<"WARNING - incompatible cfg options: nevtsample = "<<m_nevtsample<<", pedValflag = "<<m_pedValflag<<endl;
52  cout<<"Setting pedValflag = 0"<<endl;
53  m_pedValflag=0;
54  }
55  if(m_pedValflag>1) m_pedValflag=1;
56  m_startTS = ps.getUntrackedParameter<int>("firstTS", 0);
57  if(m_startTS<0) m_startTS=0;
58  m_endTS = ps.getUntrackedParameter<int>("lastTS", 9);
59 
60 // m_logFile.open("CastorPedestalAnalysis.log");
61 
62  castorHists.ALLPEDS = new TH1F("Castor All Pedestals","HF All Peds",10,0,9);
63  castorHists.PEDRMS= new TH1F("Castor All Pedestal Widths","HF All Pedestal RMS",100,0,3);
64  castorHists.PEDMEAN= new TH1F("Castor All Pedestal Means","HF All Pedestal Means",100,0,9);
65  castorHists.CHI2= new TH1F("Castor Chi2/ndf for whole range Gauss fit","HF Chi2/ndf Gauss",200,0.,50.);
66 }
T getUntrackedParameter(std::string const &, T const &) const
CastorPedestalWidths * fRawPedestalWidths
struct CastorPedestalAnalysis::@41 castorHists
CastorPedestalWidths * fValPedestalWidths
int k[5][pyjets_maxn]
const CastorPedestalWidths * fRefPedestalWidths
const CastorPedestals * fRefPedestals
CastorPedestalAnalysis::~CastorPedestalAnalysis ( )

Destructor.

Definition at line 69 of file CastorPedestalAnalysis.cc.

References _meot, castorHists, and mps_fire::i.

69  {
70 
71  for(_meot=castorHists.PEDTRENDS.begin(); _meot!=castorHists.PEDTRENDS.end(); _meot++){
72  for(int i=0; i<16; i++) _meot->second[i].first->Delete();
73  }
74 
75  castorHists.ALLPEDS->Delete();
76  castorHists.PEDRMS->Delete();
77  castorHists.PEDMEAN->Delete();
78  castorHists.CHI2->Delete();
79 }
std::map< HcalDetId, std::map< int, PEDBUNCH > >::iterator _meot
struct CastorPedestalAnalysis::@41 castorHists

Member Function Documentation

void CastorPedestalAnalysis::AllChanHists ( const HcalDetId  detid,
const HcalQIESample qie0,
const HcalQIESample qie1,
const HcalQIESample qie2,
const HcalQIESample qie3,
const HcalQIESample qie4,
const HcalQIESample qie5,
std::map< HcalDetId, std::map< int, PEDBUNCH > > &  toolT 
)
private

Definition at line 239 of file CastorPedestalAnalysis.cc.

References _meot, and HcalQIESample::adc().

Referenced by processEvent().

239  {
240 
241 // this function is due to be called for every channel
242 
243  _meot = toolT.find(detid);
244  map<int,PEDBUNCH> _mei = _meot->second;
245  _mei[16].first->Fill(qie4.adc()+qie5.adc()-1.);
246  _mei[17].first->Fill(qie4.adc()+qie5.adc()-qie2.adc()-qie3.adc());
247  _mei[18].first->Fill(qie4.adc()+qie5.adc()-(qie0.adc()+qie1.adc()+qie2.adc()+qie3.adc())/2.);
248 }
std::map< HcalDetId, std::map< int, PEDBUNCH > >::iterator _meot
int adc() const
get the ADC sample
Definition: HcalQIESample.h:22
int CastorPedestalAnalysis::CastorPedVal ( int  nstat[4],
const CastorPedestals fRefPedestals,
const CastorPedestalWidths fRefPedestalWidths,
CastorPedestals fRawPedestals,
CastorPedestalWidths fRawPedestalWidths,
CastorPedestals fValPedestals,
CastorPedestalWidths fValPedestalWidths 
)
static

Definition at line 644 of file CastorPedestalAnalysis.cc.

References CastorCondObjectContainer< Item >::addValues(), MessageLogger_cfi::cerr, CastorCondObjectContainer< Item >::getAllChannels(), CastorPedestalWidth::getSigma(), CastorPedestal::getValue(), CastorCondObjectContainer< Item >::getValues(), HcalForward, mps_fire::i, createfilelist::int, CastorPedestalWidth::setSigma(), mathSSE::sqrt(), and ApeEstimator_cff::width.

Referenced by done().

650 {
651 // new version of pedestal validation - it is designed to be as independent of
652 // all the rest as possible - you only need to provide valid pedestal objects
653 // and a vector of statistics per capID to use this as standalone code
654  HcalDetId detid;
655  float RefPedVals[4]; float RefPedSigs[4][4];
656  float RawPedVals[4]; float RawPedSigs[4][4];
657  map<HcalDetId,bool> isinRaw;
658  map<HcalDetId,bool> isinRef;
659  std::vector<DetId> RefChanns=fRefPedestals->getAllChannels();
660  std::vector<DetId> RawChanns=fRawPedestals->getAllChannels();
661  std::ofstream PedValLog;
662  PedValLog.open("CastorPedVal.log");
663 
664  if(nstat[0]+nstat[1]+nstat[2]+nstat[3]<2500) PedValLog<<"CastorPedVal: warning - low statistics"<<std::endl;
665 // find complete list of channels in current data and reference
666  for (int i=0; i<(int)RawChanns.size(); i++){
667  isinRef[HcalDetId(RawChanns[i])]=false;
668  }
669  for (int i=0; i<(int)RefChanns.size(); i++){
670  detid=HcalDetId(RefChanns[i]);
671  isinRaw[detid]=false;
672  isinRef[detid]=true;
673  }
674  for (int i=0; i<(int)RawChanns.size(); i++){
675  detid=HcalDetId(RawChanns[i]);
676  isinRaw[detid]=true;
677  if (isinRef[detid]==false) {
678  PedValLog<<"CastorPedVal: channel "<<detid<<" not found in reference set"<<std::endl;
679  std::cerr<<"CastorPedVal: channel "<<detid<<" not found in reference set"<<std::endl;
680  }
681  }
682 
683 // main loop over channels
684  int erflag=0;
685  for (int i=0; i<(int)RefChanns.size(); i++){
686  detid=HcalDetId(RefChanns[i]);
687  for (int icap=0; icap<4; icap++) {
688  RefPedVals[icap]=fRefPedestals->getValues(detid)->getValue(icap);
689  for (int icap2=icap; icap2<4; icap2++) {
690  RefPedSigs[icap][icap2]=fRefPedestalWidths->getValues(detid)->getSigma(icap,icap2);
691  if(icap2!=icap)RefPedSigs[icap2][icap]=RefPedSigs[icap][icap2];
692  }
693  }
694 
695 // read new raw values
696  if(isinRaw[detid]) {
697  for (int icap=0; icap<4; icap++) {
698  RawPedVals[icap]=fRawPedestals->getValues(detid)->getValue(icap);
699  for (int icap2=icap; icap2<4; icap2++) {
700  RawPedSigs[icap][icap2]=fRawPedestalWidths->getValues(detid)->getSigma(icap,icap2);
701  if(icap2!=icap)RawPedSigs[icap2][icap]=RawPedSigs[icap][icap2];
702  }
703  }
704 
705 // first quick check if raw values make sense: if not, the channel is treated like absent
706  for (int icap=0; icap<4; icap++) {
707  if(RawPedVals[icap]<1. || RawPedSigs[icap][icap]<0.01) isinRaw[detid]=false;
708  for (int icap2=icap; icap2<4; icap2++){
709  if(fabs(RawPedSigs[icap][icap2]/sqrt(RawPedSigs[icap][icap]*RawPedSigs[icap2][icap2]))>1.) isinRaw[detid]=false;
710  }
711  }
712  }
713 
714 // check raw values against reference
715  if(isinRaw[detid]) {
716  for (int icap=0; icap<4; icap++) {
717  int icap2=(icap+1)%4;
718  float width=sqrt(RawPedSigs[icap][icap]);
719  float erof1=width/sqrt((float)nstat[icap]);
720  float erof2=sqrt(erof1*erof1+RawPedSigs[icap][icap]/(float)nstat[icap]);
721  float erofwidth=width/sqrt(2.*nstat[icap]);
722  float diffof1=RawPedVals[icap]-RefPedVals[icap];
723  float diffof2=RawPedVals[icap]+RawPedVals[icap2]-RefPedVals[icap]-RefPedVals[icap2];
724  float diffofw=width-sqrt(RefPedSigs[icap][icap]);
725 
726 // validation in 2 TS for HB, HE, HO, in 1 TS for HF
727  int nTS=2;
728  if(detid.subdet()==HcalForward) nTS=1;
729  if(nTS==1 && fabs(diffof1)>0.5+erof1) {
730  erflag+=1;
731  PedValLog<<"HcalPedVal: drift in channel "<<detid<<" cap "<<icap<<": "<<RawPedVals[icap]<<" - "<<RefPedVals[icap]<<" = "<<diffof1<<std::endl;
732  }
733  if(nTS==2 && fabs(diffof2)>0.5+erof2) {
734  erflag+=1;
735  PedValLog<<"HcalPedVal: drift in channel "<<detid<<" caps "<<icap<<"+"<<icap2<<": "<<RawPedVals[icap]<<"+"<<RawPedVals[icap2]<<" - "<<RefPedVals[icap]<<"+"<<RefPedVals[icap2]<<" = "<<diffof2<<std::endl;
736  }
737  if(fabs(diffofw)>0.15*width+erofwidth) {
738  erflag+=1;
739  PedValLog<<"HcalPedVal: width changed in channel "<<detid<<" cap "<<icap<<": "<<width<<" - "<<sqrt(RefPedSigs[icap][icap])<<" = "<<diffofw<<std::endl;
740  }
741  }
742  }
743 
744 // for disconnected/bad channels restore reference values
745  else {
746  PedValLog<<"HcalPedVal: no valid data from channel "<<detid<<std::endl;
747  erflag+=100000;
748  CastorPedestal item(detid,RefPedVals[0],RefPedVals[1],RefPedVals[2],RefPedVals[3]);
749  fValPedestals->addValues(item);
750  CastorPedestalWidth widthsp(detid);
751  for (int icap=0; icap<4; icap++) {
752  for (int icap2=icap; icap2<4; icap2++) widthsp.setSigma(icap2,icap,RefPedSigs[icap2][icap]);
753  }
754  fValPedestalWidths->addValues(widthsp);
755  }
756 
757 // end of channel loop
758  }
759 
760  if(erflag==0) PedValLog<<"HcalPedVal: all pedestals checked OK"<<std::endl;
761 
762 // now construct the remaining part of the validated objects
763 // if nothing changed outside tolerance, validated set = reference set
764  if(erflag%100000 == 0) {
765  for (int i=0; i<(int)RefChanns.size(); i++){
766  detid=HcalDetId(RefChanns[i]);
767  if (isinRaw[detid]) {
768  CastorPedestalWidth widthsp(detid);
769  for (int icap=0; icap<4; icap++) {
770  RefPedVals[icap]=fRefPedestals->getValues(detid)->getValue(icap);
771  for (int icap2=icap; icap2<4; icap2++) {
772  RefPedSigs[icap][icap2]=fRefPedestalWidths->getValues(detid)->getSigma(icap,icap2);
773  if(icap2!=icap)RefPedSigs[icap2][icap]=RefPedSigs[icap][icap2];
774  widthsp.setSigma(icap2,icap,RefPedSigs[icap2][icap]);
775  }
776  }
777  fValPedestalWidths->addValues(widthsp);
778  CastorPedestal item(detid,RefPedVals[0],RefPedVals[1],RefPedVals[2],RefPedVals[3]);
779  fValPedestals->addValues(item);
780  }
781  }
782  }
783 
784 // if anything changed, validated set = raw set + reference for missing/bad channels
785  else {
786  for (int i=0; i<(int)RawChanns.size(); i++){
787  detid=HcalDetId(RawChanns[i]);
788  if (isinRaw[detid]) {
789  CastorPedestalWidth widthsp(detid);
790  for (int icap=0; icap<4; icap++) {
791  RawPedVals[icap]=fRawPedestals->getValues(detid)->getValue(icap);
792  for (int icap2=icap; icap2<4; icap2++) {
793  RawPedSigs[icap][icap2]=fRawPedestalWidths->getValues(detid)->getSigma(icap,icap2);
794  if(icap2!=icap)RawPedSigs[icap2][icap]=RawPedSigs[icap][icap2];
795  widthsp.setSigma(icap2,icap,RawPedSigs[icap2][icap]);
796  }
797  }
798  fValPedestalWidths->addValues(widthsp);
799  CastorPedestal item(detid,RawPedVals[0],RawPedVals[1],RawPedVals[2],RawPedVals[3]);
800  fValPedestals->addValues(item);
801  }
802  }
803  }
804  return erflag;
805 }
float getValue(int fCapId) const
get value for capId = 0..3
std::vector< DetId > getAllChannels() const
const Item * getValues(DetId fId, bool throwOnFail=true) const
T sqrt(T t)
Definition: SSEVec.h:18
float getSigma(int fCapId1, int fCapId2) const
get correlation element for capId1/2 = 0..3
bool addValues(const Item &myItem)
int CastorPedestalAnalysis::done ( const CastorPedestals fInputPedestals,
const CastorPedestalWidths fInputWidths,
CastorPedestals fOutputPedestals,
CastorPedestalWidths fOutputWidths 
)

Definition at line 414 of file CastorPedestalAnalysis.cc.

References castorHists, CastorPedVal(), gather_cfg::cout, evt, fRawPedestals, fRawPedestalWidths, fRefPedestals, fRefPedestalWidths, fValPedestals, fValPedestalWidths, mps_fire::i, m_AllPedsOK, m_file, m_nevtsample, m_outputFileROOT, m_pedValflag, m_stat, SampleAnalysis(), and Trendings().

418 {
419  int nstat[4];
420 
421 // Pedestal objects
422  // inputs...
423  fRefPedestals = fInputPedestals;
424  fRefPedestalWidths = fInputPedestalWidths;
425 
426  // outputs...
427  if(m_pedValflag>0) {
428  fValPedestals = fOutputPedestals;
429  fValPedestalWidths = fOutputPedestalWidths;
432  }
433  else {
434  fRawPedestals = fOutputPedestals;
435  fRawPedestalWidths = fOutputPedestalWidths;
438  }
439 
440 // compute pedestal constants
442  if(m_nevtsample>0) {
444  }
445 
446 // trending histos
447  if(m_nevtsample>0){
448  m_file->cd();
449  m_file->cd("Castor");
450  Trendings(castorHists.PEDTRENDS,castorHists.CHI2,castorHists.CAPID_AVERAGE,castorHists.CAPID_CHI2);
451  }
452 
453  if (m_nevtsample<1) {
454 
455 // pedestal validation: m_AllPedsOK=-1 means not validated,
456 // 0 everything OK,
457 // N>0 : mod(N,100000) drifts + width changes
458 // int(N/100000) missing channels
459  m_AllPedsOK=-1;
460  if(m_pedValflag>0) {
461  for (int i=0; i<4; i++) nstat[i]=(int)m_stat[i];
462  int NPedErrors=CastorPedVal(nstat,fRefPedestals,fRefPedestalWidths,
465  m_AllPedsOK=NPedErrors;
466  }
467 // setting m_AllPedsOK=-2 will inhibit writing pedestals out
468 // if(m_pedValflag==1){
469 // if(evt<100)m_AllPedsOK=-2;
470 // }
471 
472  }
473 
474  // Write other histograms.
475 
476  // Castor
477  m_file->cd();
478  m_file->cd("Castor");
479  castorHists.ALLPEDS->Write();
480  castorHists.PEDRMS->Write();
481  castorHists.PEDMEAN->Write();
482 
483  m_file->Close();
484  cout << "Hcal/Castor histograms written to " << m_outputFileROOT.c_str() << endl;
485  return (int)m_AllPedsOK;
486 }
CastorPedestalWidths * fRawPedestalWidths
struct CastorPedestalAnalysis::@41 castorHists
static int CastorPedVal(int nstat[4], const CastorPedestals *fRefPedestals, const CastorPedestalWidths *fRefPedestalWidths, CastorPedestals *fRawPedestals, CastorPedestalWidths *fRawPedestalWidths, CastorPedestals *fValPedestals, CastorPedestalWidths *fValPedestalWidths)
void Trendings(std::map< HcalDetId, std::map< int, PEDBUNCH > > &toolT, TH1F *Chi2, TH1F *CapidAverage, TH1F *CapidChi2)
CastorPedestalWidths * fValPedestalWidths
const CastorPedestalWidths * fRefPedestalWidths
const CastorPedestals * fRefPedestals
void CastorPedestalAnalysis::GetPedConst ( std::map< HcalDetId, std::map< int, PEDBUNCH > > &  toolT,
TH1F *  PedMeans,
TH1F *  PedWidths 
)
private

Definition at line 264 of file CastorPedestalAnalysis.cc.

References _meot, CastorCondObjectContainer< Item >::addValues(), cap, vertices_cff::chi2, fitflag, fRawPedestals, fRawPedestalWidths, mps_fire::i, m_endTS, m_hiSaveflag, m_nevtsample, m_pedsinADC, m_startTS, m_stat, CastorPedestalWidth::setSigma(), and mathSSE::sqrt().

Referenced by SampleAnalysis().

265 {
266 // Completely rewritten version oct 2006
267 // Compute pedestal constants and fill into CastorPedestals and CastorPedestalWidths objects
268  float cap[4]; float sig[4][4]; float dcap[4]; float dsig[4][4]; float chi2[4];
269 
270  for(_meot=toolT.begin(); _meot!=toolT.end(); _meot++){
271  HcalDetId detid = _meot->first;
272 
273 // take mean and width from a Gaussian fit or directly from the histo
274  if(fitflag>0){
275  for (int i=0; i<4; i++) {
276  TF1 *fit = _meot->second[i].first->GetFunction("gaus");
277  chi2[i]=0;
278  if(fit->GetNDF()!=0) chi2[i]=fit->GetChisquare()/fit->GetNDF();
279  cap[i]=fit->GetParameter(1);
280  sig[i][i]=fit->GetParameter(2);
281  dcap[i]=fit->GetParError(1);
282  dsig[i][i]=fit->GetParError(2);
283  }
284  }
285  else{
286  for (int i=0; i<4; i++) {
287  cap[i]=_meot->second[i].first->GetMean();
288  sig[i][i]=_meot->second[i].first->GetRMS();
289  m_stat[i]=0;
290 
291  for(int j=m_startTS; j<m_endTS+1; j++){
292  m_stat[i]+=_meot->second[i].first->GetBinContent(j+1);
293  }
294  dcap[i] = sig[i][i]/sqrt(m_stat[i]);
295 // dsig[i][i] = dcap[i]*sig[i][i]/cap[i];
296  dsig[i][i] = sig[i][i]/sqrt(2.*m_stat[i]);
297  chi2[i]=0.;
298  }
299  }
300 
301  for (int i=0; i<4; i++) {
302  if(m_hiSaveflag>0) {
303  if (m_pedsinADC)
304  _meot->second[i].first->GetXaxis()->SetTitle("ADC");
305  else _meot->second[i].first->GetXaxis()->SetTitle("Charge, fC");
306  _meot->second[i].first->GetYaxis()->SetTitle("CapID samplings");
307  _meot->second[i].first->Write();
308  }
309  if(m_nevtsample>0) {
310  _meot->second[i].second.first[0].push_back(cap[i]);
311  _meot->second[i].second.first[1].push_back(dcap[i]);
312  _meot->second[i].second.first[2].push_back(sig[i][i]);
313  _meot->second[i].second.first[3].push_back(dsig[i][i]);
314  _meot->second[i].second.first[4].push_back(chi2[i]);
315  }
316  PedMeans->Fill(cap[i]);
317  PedWidths->Fill(sig[i][i]);
318  }
319 
320 // special histos for Shuichi
321  if(m_hiSaveflag==-100){
322  for(int i=16; i<19; i++){
323  if (m_pedsinADC)
324  _meot->second[i].first->GetXaxis()->SetTitle("ADC");
325  else _meot->second[i].first->GetXaxis()->SetTitle("Charge, fC");
326  _meot->second[i].first->GetYaxis()->SetTitle("Events");
327  _meot->second[i].first->Write();
328  }
329  }
330 
331 // diagonal sigma is width squared
332  sig[0][0]=sig[0][0]*sig[0][0];
333  sig[1][1]=sig[1][1]*sig[1][1];
334  sig[2][2]=sig[2][2]*sig[2][2];
335  sig[3][3]=sig[3][3]*sig[3][3];
336 
337 // off diagonal sigmas (correlations) are computed from 3 histograms
338 // here we still have all 4*3=12 combinations
339  sig[0][1]= _meot->second[4].first->GetMean()-cap[0]*cap[1];
340  sig[0][2]= _meot->second[8].first->GetMean()-cap[0]*cap[2];
341  sig[1][2]= _meot->second[5].first->GetMean()-cap[1]*cap[2];
342  sig[1][3]= _meot->second[9].first->GetMean()-cap[1]*cap[3];
343  sig[2][3]= _meot->second[6].first->GetMean()-cap[2]*cap[3];
344  sig[0][3]= _meot->second[12].first->GetMean()-cap[0]*cap[3];
345  sig[1][0]= _meot->second[13].first->GetMean()-cap[1]*cap[0];
346  sig[2][0]= _meot->second[10].first->GetMean()-cap[2]*cap[0];
347  sig[2][1]= _meot->second[14].first->GetMean()-cap[2]*cap[1];
348  sig[3][1]= _meot->second[11].first->GetMean()-cap[3]*cap[1];
349  sig[3][2]= _meot->second[15].first->GetMean()-cap[3]*cap[2];
350  sig[3][0]= _meot->second[7].first->GetMean()-cap[3]*cap[0];
351 
352 // there is no proper error calculation for the correlation coefficients
353  for(int i=0; i<4; i++){
354  if(m_nevtsample>0) {
355  _meot->second[i].second.first[5].push_back(sig[i][(i+1)%4]);
356  _meot->second[i].second.first[6].push_back(2*sig[i][i]*dsig[i][i]);
357  _meot->second[i].second.first[7].push_back(sig[i][(i+2)%4]);
358  _meot->second[i].second.first[8].push_back(2*sig[i][i]*dsig[i][i]);
359  _meot->second[i].second.first[9].push_back(sig[i][(i+3)%4]);
360  _meot->second[i].second.first[10].push_back(2*sig[i][i]*dsig[i][i]);
361  }
362 // save product histos if desired
363  if(m_hiSaveflag>10) {
364  if (m_pedsinADC)
365  _meot->second[i+4].first->GetXaxis()->SetTitle("ADC^2");
366  else _meot->second[i+4].first->GetXaxis()->SetTitle("Charge^2, fC^2");
367  _meot->second[i+4].first->GetYaxis()->SetTitle("2-CapID samplings");
368  _meot->second[i+4].first->Write();
369  if (m_pedsinADC)
370  _meot->second[i+8].first->GetXaxis()->SetTitle("ADC^2");
371  else _meot->second[i+8].first->GetXaxis()->SetTitle("Charge^2, fC^2");
372  _meot->second[i+8].first->GetYaxis()->SetTitle("2-CapID samplings");
373  _meot->second[i+8].first->Write();
374  if (m_pedsinADC)
375  _meot->second[i+12].first->GetXaxis()->SetTitle("ADC^2");
376  else _meot->second[i+12].first->GetXaxis()->SetTitle("Charge^2, fC^2");
377  _meot->second[i+12].first->GetYaxis()->SetTitle("2-CapID samplings");
378  _meot->second[i+12].first->Write();
379  }
380  }
381 
382 // fill the objects - at this point only close and medium correlations are stored
383 // and the matrix is assumed symmetric
384  if (m_nevtsample<1) {
385  sig[1][0]=sig[0][1];
386  sig[2][0]=sig[0][2];
387  sig[2][1]=sig[1][2];
388  sig[3][1]=sig[1][3];
389  sig[3][2]=sig[2][3];
390  sig[0][3]=sig[3][0];
391  if (fRawPedestals) {
392  CastorPedestal item(detid,cap[0],cap[1],cap[2],cap[3]);
393  fRawPedestals->addValues(item);
394  }
395  if (fRawPedestalWidths) {
396  CastorPedestalWidth widthsp(detid);
397  widthsp.setSigma(0,0,sig[0][0]);
398  widthsp.setSigma(0,1,sig[0][1]);
399  widthsp.setSigma(0,2,sig[0][2]);
400  widthsp.setSigma(1,1,sig[1][1]);
401  widthsp.setSigma(1,2,sig[1][2]);
402  widthsp.setSigma(1,3,sig[1][3]);
403  widthsp.setSigma(2,2,sig[2][2]);
404  widthsp.setSigma(2,3,sig[2][3]);
405  widthsp.setSigma(3,3,sig[3][3]);
406  widthsp.setSigma(3,0,sig[0][3]);
407  fRawPedestalWidths->addValues(widthsp);
408  }
409  }
410  }
411 }
static const double cap
Definition: HcalTimeSlew.cc:7
CastorPedestalWidths * fRawPedestalWidths
std::map< HcalDetId, std::map< int, PEDBUNCH > >::iterator _meot
T sqrt(T t)
Definition: SSEVec.h:18
bool addValues(const Item &myItem)
void CastorPedestalAnalysis::per2CapsHists ( int  flag,
int  id,
const HcalDetId  detid,
const HcalQIESample qie1,
const HcalQIESample qie2,
std::map< HcalDetId, std::map< int, PEDBUNCH > > &  toolT,
const CastorDbService cond 
)
private

Definition at line 131 of file CastorPedestalAnalysis.cc.

References _meot, HcalQIESample::adc(), create_public_pileup_plots::bins, HcalQIESample::capid(), castorHists, CastorQIECoder::charge(), HcalDetId::depth(), evt, RemoveAddSevLevel::flag, CastorDbService::getCastorCoder(), CastorDbService::getCastorShape(), mps_fire::i, HcalDetId::ieta(), edm::eventsetup::heterocontainer::insert(), HcalDetId::iphi(), m_nevtsample, m_pedsinADC, dataset::name, and state.

Referenced by processEvent().

131  {
132 
133 // this function is due to be called for every time slice, it fills either a charge
134 // histo for a single capID (flag=0) or a product histo for two capIDs (flag>0)
135 
136  static const int bins=10;
137  static const int bins2=100;
138  float lo=-0.5; float hi=9.5;
139  map<int,PEDBUNCH> _mei;
140  static map<HcalDetId, map<int,float> > QieCalibMap;
141  string type = "Castor";
142 
143  /*
144  if(id==0){
145  if(detid.ieta()<16) type = "HB";
146  if(detid.ieta()>16) type = "HE";
147  if(detid.ieta()==16){
148  if(detid.depth()<3) type = "HB";
149  if(detid.depth()==3) type = "HE";
150  }
151  }
152  else if(id==1) type = "HO";
153  else if(id==2) type = "HF";
154  */
155 
156  _meot = toolT.find(detid);
157 
158 // if histos for the current channel do not exist, first create them,
159  if (_meot==toolT.end()){
160  map<int,PEDBUNCH> insert;
161  map<int,float> qiecalib;
162  char name[1024];
163  for(int i=0; i<4; i++){
164  lo=-0.5;
165  // fix from Andy: if you convert to fC and then bin in units of 1, you may 'skip' a bin while
166  // filling, since the ADCs are quantized
167  if (m_pedsinADC) hi=9.5;
168  else hi = 11.5;
169  sprintf(name,"%s Pedestal, eta=%d phi=%d d=%d cap=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth(),i);
170  insert[i].first = new TH1F(name,name,bins,lo,hi);
171  sprintf(name,"%s Product, eta=%d phi=%d d=%d caps=%d*%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth(),i,(i+1)%4);
172  insert[4+i].first = new TH1F(name,name,bins2,0.,100.);
173  sprintf(name,"%s Product, eta=%d phi=%d d=%d caps=%d*%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth(),i,(i+2)%4);
174  insert[8+i].first = new TH1F(name,name,bins2,0.,100.);
175  sprintf(name,"%s Product, eta=%d phi=%d d=%d caps=%d*%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth(),i,(i+3)%4);
176  insert[12+i].first = new TH1F(name,name,bins2,0.,100.);
177  }
178  sprintf(name,"%s Signal in TS 4+5, eta=%d phi=%d d=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
179  insert[16].first = new TH1F(name,name,21,-0.5,20.5);
180  sprintf(name,"%s Signal in TS 4+5-2-3, eta=%d phi=%d d=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
181  insert[17].first = new TH1F(name,name,21,-10.5,10.5);
182  sprintf(name,"%s Signal in TS 4+5-(0+1+2+3)/2., eta=%d phi=%d d=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
183  insert[18].first = new TH1F(name,name,21,-10.5,10.5);
184  toolT[detid] = insert;
185  _meot = toolT.find(detid);
186 // store QIE calibrations in a map for later reuse
187  QieCalibMap[detid]=qiecalib;
188  }
189 
190  _mei = _meot->second;
191 
192  const CastorQIECoder* coder = cond.getCastorCoder(detid);
193  const CastorQIEShape* shape = cond.getCastorShape();
194  float charge1 = coder->charge(*shape,qie1.adc(),qie1.capid());
195  float charge2 = coder->charge(*shape,qie2.adc(),qie2.capid());
196 
197 // fill single capID histo
198  if(flag==0){
199  if(m_nevtsample>0) {
200  if((evt-1)%m_nevtsample==0 && state[qie1.capid()]){
201  state[qie1.capid()]=false;
202  _mei[qie1.capid()].first->Reset();
203  _mei[qie1.capid()+4].first->Reset();
204  _mei[qie1.capid()+8].first->Reset();
205  _mei[qie1.capid()+12].first->Reset();
206  }
207  }
208  if (qie1.adc()<bins){
209  if (m_pedsinADC) _mei[qie1.capid()].first->Fill(qie1.adc());
210  else _mei[qie1.capid()].first->Fill(charge1);
211  }
212  else if(qie1.adc()>=bins){
213  _mei[qie1.capid()].first->AddBinContent(bins+1,1);
214  }
215  }
216 
217 // fill 2 capID histo
218  if(flag>0){
219  map<int,float> qiecalib = QieCalibMap[detid];
220  //float charge1=(qie1.adc()-qiecalib[qie1.capid()+4])/qiecalib[qie1.capid()];
221  //float charge2=(qie2.adc()-qiecalib[qie2.capid()+4])/qiecalib[qie2.capid()];
222  if (charge1*charge2<bins2){
223  _mei[qie1.capid()+4*flag].first->Fill(charge1*charge2);
224  }
225  else{
226  _mei[qie1.capid()+4*flag].first->Fill(bins2);
227  }
228  }
229 
230  if(flag==0){
231  // if(id==0) hbHists.ALLPEDS->Fill(qie1.adc());
232  // else if(id==1) hoHists.ALLPEDS->Fill(qie1.adc());
233  // else if(id==2) castorHists.ALLPEDS->Fill(qie1.adc());
234  castorHists.ALLPEDS->Fill(qie1.adc());
235  }
236 }
type
Definition: HCALResponse.h:21
std::map< HcalDetId, std::map< int, PEDBUNCH > >::iterator _meot
struct CastorPedestalAnalysis::@41 castorHists
int adc() const
get the ADC sample
Definition: HcalQIESample.h:22
int depth() const
get the tower depth
Definition: HcalDetId.cc:129
const CastorQIEShape * getCastorShape() const
int ieta() const
get the cell ieta
Definition: HcalDetId.h:56
float charge(const CastorQIEShape &fShape, unsigned fAdc, unsigned fCapId) const
ADC [0..127] + capid [0..3] -> fC conversion.
bool insert(Storage &iStorage, ItemType *iItem, const IdTag &iIdTag)
Definition: HCMethods.h:49
int iphi() const
get the cell iphi
Definition: HcalDetId.cc:124
int capid() const
get the Capacitor id
Definition: HcalQIESample.h:26
const CastorQIECoder * getCastorCoder(const HcalGenericDetId &fId) const
void CastorPedestalAnalysis::processEvent ( const CastorDigiCollection castor,
const CastorDbService cond 
)

Definition at line 90 of file CastorPedestalAnalysis.cc.

References AllChanHists(), edm::SortedCollection< T, SORT >::begin(), castorHists, edm::SortedCollection< T, SORT >::empty(), edm::SortedCollection< T, SORT >::end(), evt, evt_curr, RemoveAddSevLevel::flag, CastorDbService::getCastorCoder(), CastorDbService::getCastorShape(), mps_fire::i, CastorDataFrame::id(), m_coder, m_endTS, m_nevtsample, m_shape, m_startTS, per2CapsHists(), CastorDataFrame::sample(), sample, SampleAnalysis(), CastorDataFrame::size(), and edm::SortedCollection< T, SORT >::size().

92 {
93  evt++;
94  sample=1;
95  evt_curr=evt;
96  if(m_nevtsample>0) {
97  sample = (evt-1)/m_nevtsample +1;
100  }
101 
102  m_shape = cond.getCastorShape();
103  // HF
104  try{
105  if(castor.empty()) throw (int)castor.size();
106  for (CastorDigiCollection::const_iterator j=castor.begin(); j!=castor.end(); ++j){
107  const CastorDataFrame digi = (const CastorDataFrame)(*j);
108  m_coder = cond.getCastorCoder(digi.id());
109  for (int i=m_startTS; i<digi.size() && i<=m_endTS; i++) {
110  for(int flag=0; flag<4; flag++){
111  if(i+flag<digi.size() && i+flag<=m_endTS){
112  per2CapsHists(flag,2,digi.id(),digi.sample(i),digi.sample(i+flag),castorHists.PEDTRENDS,cond);
113  }
114  }
115  }
116  if(m_startTS==0 && m_endTS>4){
117  AllChanHists(digi.id(),digi.sample(0),digi.sample(1),digi.sample(2),digi.sample(3),digi.sample(4),digi.sample(5),castorHists.PEDTRENDS);
118  }
119  }
120  }
121  catch (int i ) {
122 // m_logFile << "Event with " << i<<" Castor Digis passed." << std::endl;
123  }
124  // Call the function every m_nevtsample events
125  if(m_nevtsample>0) {
127  }
128 }
struct CastorPedestalAnalysis::@41 castorHists
const CastorQIECoder * m_coder
const HcalQIESample & sample(int i) const
access a sample
std::vector< CastorDataFrame >::const_iterator const_iterator
void AllChanHists(const HcalDetId detid, const HcalQIESample &qie0, const HcalQIESample &qie1, const HcalQIESample &qie2, const HcalQIESample &qie3, const HcalQIESample &qie4, const HcalQIESample &qie5, std::map< HcalDetId, std::map< int, PEDBUNCH > > &toolT)
const CastorQIEShape * getCastorShape() const
const_iterator end() const
const CastorQIEShape * m_shape
size_type size() const
const HcalCastorDetId & id() const
int size() const
total number of samples in the digi
void per2CapsHists(int flag, int id, const HcalDetId detid, const HcalQIESample &qie1, const HcalQIESample &qie2, std::map< HcalDetId, std::map< int, PEDBUNCH > > &toolT, const CastorDbService &cond)
const_iterator begin() const
const CastorQIECoder * getCastorCoder(const HcalGenericDetId &fId) const
void CastorPedestalAnalysis::SampleAnalysis ( )

Definition at line 251 of file CastorPedestalAnalysis.cc.

References castorHists, GetPedConst(), m_file, and sample.

Referenced by done(), and processEvent().

251  {
252  // it is called every m_nevtsample events (a sample) and the end of run
253  char PedSampleNum[20];
254 
255 // Compute pedestal constants for each HBHE, HO, HF
256  sprintf(PedSampleNum,"Castor_Sample%d",sample);
257  m_file->cd();
258  m_file->mkdir(PedSampleNum);
259  m_file->cd(PedSampleNum);
260  GetPedConst(castorHists.PEDTRENDS,castorHists.PEDMEAN,castorHists.PEDRMS);
261 }
struct CastorPedestalAnalysis::@41 castorHists
void GetPedConst(std::map< HcalDetId, std::map< int, PEDBUNCH > > &toolT, TH1F *PedMeans, TH1F *PedWidths)
void CastorPedestalAnalysis::setup ( const std::string &  m_outputFileROOT)

Definition at line 82 of file CastorPedestalAnalysis.cc.

References m_file.

Referenced by o2olib.O2OTool::execute().

82  {
83  // open the histogram file, create directories within
84  m_file=new TFile(m_outputFileROOT.c_str(),"RECREATE");
85  m_file->mkdir("Castor");
86  m_file->cd();
87 }
void CastorPedestalAnalysis::Trendings ( std::map< HcalDetId, std::map< int, PEDBUNCH > > &  toolT,
TH1F *  Chi2,
TH1F *  CapidAverage,
TH1F *  CapidChi2 
)
private

Definition at line 489 of file CastorPedestalAnalysis.cc.

References _meot, begin, create_public_pileup_plots::bins, HcalDetId::depth(), objects.autophobj::float, mps_fire::i, HcalDetId::ieta(), HcalDetId::iphi(), m_nevtsample, dataset::name, sample, and findQualityFiles::size.

Referenced by done().

489  {
490 
491 // check stability of pedestal constants in a single long run
492 
493  map<int, std::vector<double> > AverageValues;
494 
495  for(_meot=toolT.begin(); _meot!=toolT.end(); _meot++){
496  for(int i=0; i<4; i++){
497  char name[1024];
498  HcalDetId detid = _meot->first;
499  sprintf(name,"Pedestal trend, eta=%d phi=%d d=%d cap=%d",detid.ieta(),detid.iphi(),detid.depth(),i);
500  int bins = _meot->second[i].second.first[0].size();
501  float lo =0.5;
502  float hi = (float)bins+0.5;
503  _meot->second[i].second.second.push_back(new TH1F(name,name,bins,lo,hi));
504  sprintf(name,"Width trend, eta=%d phi=%d d=%d cap=%d",detid.ieta(),detid.iphi(),detid.depth(),i);
505  bins = _meot->second[i].second.first[2].size();
506  hi = (float)bins+0.5;
507  _meot->second[i].second.second.push_back(new TH1F(name,name,bins,lo,hi));
508  sprintf(name,"Correlation trend, eta=%d phi=%d d=%d caps=%d*%d",detid.ieta(),detid.iphi(),detid.depth(),i,(i+1)%4);
509  bins = _meot->second[i].second.first[5].size();
510  hi = (float)bins+0.5;
511  _meot->second[i].second.second.push_back(new TH1F(name,name,bins,lo,hi));
512 /* sprintf(name,"Correlation trend, eta=%d phi=%d d=%d caps=%d*%d",detid.ieta(),detid.iphi(),detid.depth(),i,(i+2)%4);
513  bins = _meot->second[i].second.first[7].size();
514  hi = (float)bins+0.5;
515  _meot->second[i].second.second.push_back(new TH1F(name,name,bins,lo,hi));
516  sprintf(name,"Correlation trend, eta=%d phi=%d d=%d caps=%d*%d",detid.ieta(),detid.iphi(),detid.depth(),i,(i+3)%4);
517  bins = _meot->second[i].second.first[9].size();
518  hi = (float)bins+0.5;
519  _meot->second[i].second.second.push_back(new TH1F(name,name,bins,lo,hi)); */
520 
521  std::vector<double>::iterator sample_it;
522  // Pedestal mean - put content and errors
523  int j=0;
524  for(sample_it=_meot->second[i].second.first[0].begin();
525  sample_it!=_meot->second[i].second.first[0].end();++sample_it){
526  _meot->second[i].second.second[0]->SetBinContent(++j,*sample_it);
527  }
528  j=0;
529  for(sample_it=_meot->second[i].second.first[1].begin();
530  sample_it!=_meot->second[i].second.first[1].end();++sample_it){
531  _meot->second[i].second.second[0]->SetBinError(++j,*sample_it);
532  }
533  // fit with a constant - extract parameters
534  _meot->second[i].second.second[0]->Fit("pol0","Q");
535  TF1 *fit = _meot->second[i].second.second[0]->GetFunction("pol0");
536  AverageValues[0].push_back(fit->GetParameter(0));
537  AverageValues[1].push_back(fit->GetParError(0));
538  if(sample>1)
539  AverageValues[2].push_back(fit->GetChisquare()/fit->GetNDF());
540  else
541  AverageValues[2].push_back(fit->GetChisquare());
542  sprintf(name,"Sample (%d events)",m_nevtsample);
543  _meot->second[i].second.second[0]->GetXaxis()->SetTitle(name);
544  _meot->second[i].second.second[0]->GetYaxis()->SetTitle("Pedestal value");
545  _meot->second[i].second.second[0]->Write();
546  // Pedestal width - put content and errors
547  j=0;
548  for(sample_it=_meot->second[i].second.first[2].begin();
549  sample_it!=_meot->second[i].second.first[2].end();++sample_it){
550  _meot->second[i].second.second[1]->SetBinContent(++j,*sample_it);
551  }
552  j=0;
553  for(sample_it=_meot->second[i].second.first[3].begin();
554  sample_it!=_meot->second[i].second.first[3].end();++sample_it){
555  _meot->second[i].second.second[1]->SetBinError(++j,*sample_it);
556  }
557  _meot->second[i].second.second[1]->GetXaxis()->SetTitle(name);
558  _meot->second[i].second.second[1]->GetYaxis()->SetTitle("Pedestal width");
559  _meot->second[i].second.second[1]->Write();
560  // Correlation coeffs - put contents and errors
561  j=0;
562  for(sample_it=_meot->second[i].second.first[5].begin();
563  sample_it!=_meot->second[i].second.first[5].end();++sample_it){
564  _meot->second[i].second.second[2]->SetBinContent(++j,*sample_it);
565  }
566  j=0;
567  for(sample_it=_meot->second[i].second.first[6].begin();
568  sample_it!=_meot->second[i].second.first[6].end();++sample_it){
569  _meot->second[i].second.second[2]->SetBinError(++j,*sample_it);
570  }
571  _meot->second[i].second.second[2]->GetXaxis()->SetTitle(name);
572  _meot->second[i].second.second[2]->GetYaxis()->SetTitle("Close correlation");
573  _meot->second[i].second.second[2]->Write();
574  /* j=0;
575  for(sample_it=_meot->second[i].second.first[7].begin();
576  sample_it!=_meot->second[i].second.first[7].end();sample_it++){
577  _meot->second[i].second.second[3]->SetBinContent(++j,*sample_it);
578  }
579  j=0;
580  for(sample_it=_meot->second[i].second.first[8].begin();
581  sample_it!=_meot->second[i].second.first[8].end();sample_it++){
582  _meot->second[i].second.second[3]->SetBinError(++j,*sample_it);
583  }
584  _meot->second[i].second.second[3]->GetXaxis()->SetTitle(name);
585  _meot->second[i].second.second[3]->GetYaxis()->SetTitle("Intermediate correlation");
586  _meot->second[i].second.second[3]->Write();
587  j=0;
588  for(sample_it=_meot->second[i].second.first[9].begin();
589  sample_it!=_meot->second[i].second.first[9].end();sample_it++){
590  _meot->second[i].second.second[4]->SetBinContent(++j,*sample_it);
591  }
592  j=0;
593  for(sample_it=_meot->second[i].second.first[10].begin();
594  sample_it!=_meot->second[i].second.first[10].end();sample_it++){
595  _meot->second[i].second.second[4]->SetBinError(++j,*sample_it);
596  }
597  _meot->second[i].second.second[4]->GetXaxis()->SetTitle(name);
598  _meot->second[i].second.second[4]->GetYaxis()->SetTitle("Distant correlation");
599  _meot->second[i].second.second[4]->Write(); */
600  // chi2
601  j=0;
602  for(sample_it=_meot->second[i].second.first[4].begin();
603  sample_it!=_meot->second[i].second.first[4].end();++sample_it){
604  Chi2->Fill(*sample_it);
605  }
606  }
607  }
608  CapidAverage= new TH1F("Constant fit: Pedestal Values",
609  "Constant fit: Pedestal Values",
610  AverageValues[0].size(),0.,AverageValues[0].size());
611  std::vector<double>::iterator sample_it;
612  int j=0;
613  for(sample_it=AverageValues[0].begin();
614  sample_it!=AverageValues[0].end();++sample_it){
615  CapidAverage->SetBinContent(++j,*sample_it);
616  }
617  j=0;
618  for(sample_it=AverageValues[1].begin();
619  sample_it!=AverageValues[1].end();++sample_it){
620  CapidAverage->SetBinError(++j,*sample_it);
621  }
622  CapidChi2= new TH1F("Constant fit: Chi2/ndf",
623  "Constant fit: Chi2/ndf",
624  AverageValues[2].size(),0.,AverageValues[2].size());
625  j=0;
626  for(sample_it=AverageValues[2].begin();
627  sample_it!=AverageValues[2].end();++sample_it){
628  CapidChi2->SetBinContent(++j,*sample_it);
629  //CapidChi2->SetBinError(++j,0);
630  }
631  Chi2->GetXaxis()->SetTitle("Chi2/ndf");
632  Chi2->GetYaxis()->SetTitle("50 x [(16+2) x 4 x 4] `events`");
633  Chi2->Write();
634  CapidAverage->GetYaxis()->SetTitle("Pedestal value");
635  CapidAverage->GetXaxis()->SetTitle("(16+2) x 4 x 4 `events`");
636  CapidAverage->Write();
637  CapidChi2->GetYaxis()->SetTitle("Chi2/ndf");
638  CapidChi2->GetXaxis()->SetTitle("(16+2) x 4 x 4 `events`");
639  CapidChi2->Write();
640 
641 }
size
Write out results.
std::map< HcalDetId, std::map< int, PEDBUNCH > >::iterator _meot
int depth() const
get the tower depth
Definition: HcalDetId.cc:129
int ieta() const
get the cell ieta
Definition: HcalDetId.h:56
int iphi() const
get the cell iphi
Definition: HcalDetId.cc:124
#define begin
Definition: vmac.h:30
Definition: Chi2.h:17

Member Data Documentation

std::map<HcalDetId,std::map<int, PEDBUNCH > >::iterator CastorPedestalAnalysis::_meot
private
TH1F* CastorPedestalAnalysis::ALLPEDS

Definition at line 117 of file CastorPedestalAnalysis.h.

TH1F* CastorPedestalAnalysis::CAPID_AVERAGE

Definition at line 121 of file CastorPedestalAnalysis.h.

TH1F* CastorPedestalAnalysis::CAPID_CHI2

Definition at line 122 of file CastorPedestalAnalysis.h.

struct { ... } CastorPedestalAnalysis::castorHists
TH1F* CastorPedestalAnalysis::CHI2

Definition at line 120 of file CastorPedestalAnalysis.h.

int CastorPedestalAnalysis::evt
private
int CastorPedestalAnalysis::evt_curr
private

Definition at line 133 of file CastorPedestalAnalysis.h.

Referenced by processEvent().

const int CastorPedestalAnalysis::fitflag =0
staticprivate

Definition at line 138 of file CastorPedestalAnalysis.h.

Referenced by GetPedConst().

CastorPedestals* CastorPedestalAnalysis::fRawPedestals
private

Definition at line 127 of file CastorPedestalAnalysis.h.

Referenced by done(), and GetPedConst().

CastorPedestalWidths* CastorPedestalAnalysis::fRawPedestalWidths
private

Definition at line 128 of file CastorPedestalAnalysis.h.

Referenced by done(), and GetPedConst().

const CastorPedestals* CastorPedestalAnalysis::fRefPedestals
private

Definition at line 125 of file CastorPedestalAnalysis.h.

Referenced by done().

const CastorPedestalWidths* CastorPedestalAnalysis::fRefPedestalWidths
private

Definition at line 126 of file CastorPedestalAnalysis.h.

Referenced by done().

CastorPedestals* CastorPedestalAnalysis::fValPedestals
private

Definition at line 129 of file CastorPedestalAnalysis.h.

Referenced by done().

CastorPedestalWidths* CastorPedestalAnalysis::fValPedestalWidths
private

Definition at line 130 of file CastorPedestalAnalysis.h.

Referenced by done().

int CastorPedestalAnalysis::m_AllPedsOK
private

Definition at line 111 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), and done().

const CastorQIECoder* CastorPedestalAnalysis::m_coder
private

Definition at line 114 of file CastorPedestalAnalysis.h.

Referenced by processEvent().

int CastorPedestalAnalysis::m_endTS
private

Definition at line 106 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), GetPedConst(), and processEvent().

TFile* CastorPedestalAnalysis::m_file
private

Definition at line 99 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), done(), SampleAnalysis(), and setup().

int CastorPedestalAnalysis::m_hiSaveflag
private

Definition at line 109 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), and GetPedConst().

std::ofstream CastorPedestalAnalysis::m_logFile
private

Definition at line 104 of file CastorPedestalAnalysis.h.

int CastorPedestalAnalysis::m_nevtsample
private
std::string CastorPedestalAnalysis::m_outputFileMean
private

Definition at line 102 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis().

std::string CastorPedestalAnalysis::m_outputFileROOT
private

Definition at line 101 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), and done().

std::string CastorPedestalAnalysis::m_outputFileWidth
private

Definition at line 103 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis().

int CastorPedestalAnalysis::m_pedsinADC
private

Definition at line 108 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), GetPedConst(), and per2CapsHists().

int CastorPedestalAnalysis::m_pedValflag
private

Definition at line 110 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), and done().

const CastorQIEShape* CastorPedestalAnalysis::m_shape
private

Definition at line 113 of file CastorPedestalAnalysis.h.

Referenced by processEvent().

int CastorPedestalAnalysis::m_startTS
private

Definition at line 105 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), GetPedConst(), and processEvent().

float CastorPedestalAnalysis::m_stat[4]
private

Definition at line 134 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), done(), and GetPedConst().

TH1F* CastorPedestalAnalysis::PEDMEAN

Definition at line 119 of file CastorPedestalAnalysis.h.

TH1F* CastorPedestalAnalysis::PEDRMS

Definition at line 118 of file CastorPedestalAnalysis.h.

std::map<HcalDetId,std::map<int, PEDBUNCH > > CastorPedestalAnalysis::PEDTRENDS

Definition at line 116 of file CastorPedestalAnalysis.h.

int CastorPedestalAnalysis::sample
private
std::vector<bool> CastorPedestalAnalysis::state
private

Definition at line 135 of file CastorPedestalAnalysis.h.

Referenced by CastorPedestalAnalysis(), and per2CapsHists().