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SiStripGainCosmicCalculator.cc
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1 // -*- C++ -*-
2 // Package: SiStripChannelGain
3 // Class: SiStripGainCosmicCalculator
4 // Original Author: G. Bruno, D. Kcira
5 // Created: Mon May 20 10:04:31 CET 2007
18 #include "CLHEP/Random/RandFlat.h"
19 #include "CLHEP/Random/RandGauss.h"
34 //#include "DQM/SiStripCommon/interface/SiStripGenerateKey.h"
35 
36 //---------------------------------------------------------------------------------------------------------
38  edm::LogInfo("SiStripGainCosmicCalculator::SiStripGainCosmicCalculator");
40  edm::LogInfo("SiStripApvGainCalculator::SiStripApvGainCalculator")<<"ExpectedChargeDeposition="<<ExpectedChargeDeposition;
41 
42  TrackProducer = iConfig.getParameter<std::string>("TrackProducer");
43  TrackLabel = iConfig.getParameter<std::string>("TrackLabel");
44 
45  detModulesToBeExcluded.clear(); detModulesToBeExcluded = iConfig.getParameter< std::vector<unsigned> >("detModulesToBeExcluded");
46  MinNrEntries = iConfig.getUntrackedParameter<unsigned>("minNrEntries", 20);
47  MaxChi2OverNDF = iConfig.getUntrackedParameter<double>("maxChi2OverNDF", 5.);
48 
49  outputHistogramsInRootFile = iConfig.getParameter<bool>("OutputHistogramsInRootFile");
50  outputFileName = iConfig.getParameter<std::string>("OutputFileName");
51 
52  edm::LogInfo("SiStripApvGainCalculator")<<"Clusters from "<<detModulesToBeExcluded.size()<<" modules will be ignored in the calibration:";
53  edm::LogInfo("SiStripApvGainCalculator")<<"The calibration for these DetIds will be set to a default value";
54  for( std::vector<uint32_t>::const_iterator imod = detModulesToBeExcluded.begin(); imod != detModulesToBeExcluded.end(); imod++){
55  edm::LogInfo("SiStripApvGainCalculator")<<"exclude detid = "<< *imod;
56  }
57 
58  printdebug_ = iConfig.getUntrackedParameter<bool>("printDebug", false);
59  tTopo = nullptr;
60 }
61 
62 
64  edm::LogInfo("SiStripGainCosmicCalculator::~SiStripGainCosmicCalculator");
65 }
66 
68 }
69 
71 {
72  //Retrieve tracker topology from geometry
74  iSetup.get<IdealGeometryRecord>().get(tTopoHandle);
75  tTopo = tTopoHandle.product();
76 
77  eventSetupCopy_ = &iSetup;
78  std::cout<<"SiStripGainCosmicCalculator::algoBeginJob called"<<std::endl;
80  HlistAPVPairs = new TObjArray(); HlistOtherHistos = new TObjArray();
81  //
82  HlistOtherHistos->Add(new TH1F( Form("APVPairCorrections"), Form("APVPairCorrections"), 50,-1.,4.));
83  HlistOtherHistos->Add(new TH1F(Form("APVPairCorrectionsTIB1mono"),Form("APVPairCorrectionsTIB1mono"),50,-1.,4.));
84  HlistOtherHistos->Add(new TH1F(Form("APVPairCorrectionsTIB1stereo"),Form("APVPairCorrectionsTIB1stereo"),50,-1.,4.));
85  HlistOtherHistos->Add(new TH1F(Form("APVPairCorrectionsTIB2"),Form("APVPairCorrectionsTIB2"),50,-1.,4.));
86  HlistOtherHistos->Add(new TH1F(Form("APVPairCorrectionsTOB1"),Form("APVPairCorrectionsTOB1"),50,-1.,4.));
87  HlistOtherHistos->Add(new TH1F(Form("APVPairCorrectionsTOB2"),Form("APVPairCorrectionsTOB2"),50,-1.,4.));
88  HlistOtherHistos->Add(new TH1F(Form("LocalAngle"),Form("LocalAngle"),70,-0.1,3.4));
89  HlistOtherHistos->Add(new TH1F(Form("LocalAngleAbsoluteCosine"),Form("LocalAngleAbsoluteCosine"),48,-0.1,1.1));
90  HlistOtherHistos->Add(new TH1F(Form("LocalPosition_cm"),Form("LocalPosition_cm"),100,-5.,5.));
91  HlistOtherHistos->Add(new TH1F(Form("LocalPosition_normalized"),Form("LocalPosition_normalized"),100,-1.1,1.1));
92  TH1F* local_histo = new TH1F(Form("SiStripRecHitType"),Form("SiStripRecHitType"),2,0.5,2.5); HlistOtherHistos->Add(local_histo);
93  local_histo->GetXaxis()->SetBinLabel(1,"simple"); local_histo->GetXaxis()->SetBinLabel(2,"matched");
94 
95  // get cabling and find out list of active detectors
96  edm::ESHandle<SiStripDetCabling> siStripDetCabling; iSetup.get<SiStripDetCablingRcd>().get(siStripDetCabling);
97  std::vector<uint32_t> activeDets; activeDets.clear();
98  SelectedDetIds.clear();
99  siStripDetCabling->addActiveDetectorsRawIds(activeDets);
100 // SelectedDetIds = activeDets; // all active detector modules
101  // use SiStripSubStructure for selecting certain regions
102  SiStripSubStructure substructure;
103  substructure.getTIBDetectors(activeDets, SelectedDetIds, 0, 0, 0, 0); // this adds rawDetIds to SelectedDetIds
104  substructure.getTOBDetectors(activeDets, SelectedDetIds, 0, 0, 0); // this adds rawDetIds to SelectedDetIds
105  // get tracker geometry and find nr. of apv pairs for each active detector
106  edm::ESHandle<TrackerGeometry> tkGeom; iSetup.get<TrackerDigiGeometryRecord>().get( tkGeom );
107  for(TrackerGeometry::DetContainer::const_iterator it = tkGeom->dets().begin(); it != tkGeom->dets().end(); it++){ // loop over detector modules
108  if( dynamic_cast<const StripGeomDetUnit*>((*it))!=0){
109  uint32_t detid= ((*it)->geographicalId()).rawId();
110  // get thickness for all detector modules, not just for active, this is strange
111  double module_thickness = (*it)->surface().bounds().thickness(); // get thickness of detector from GeomDet (DetContainer == vector<GeomDet*>)
112  thickness_map.insert(std::make_pair(detid,module_thickness));
113  //
114  bool is_active_detector = false;
115  for(std::vector<uint32_t>::iterator iactive = SelectedDetIds.begin(); iactive != SelectedDetIds.end(); iactive++){
116  if( *iactive == detid ){
117  is_active_detector = true;
118  break; // leave for loop if found matching detid
119  }
120  }
121  //
122  bool exclude_this_detid = false;
123  for( std::vector<uint32_t>::const_iterator imod = detModulesToBeExcluded.begin(); imod != detModulesToBeExcluded.end(); imod++ ){
124  if(*imod == detid) exclude_this_detid = true; // found in exclusion list
125  break;
126  }
127  //
128  if(is_active_detector && (!exclude_this_detid)){ // check whether is active detector and that should not be excluded
129  const StripTopology& p = dynamic_cast<const StripGeomDetUnit*>((*it))->specificTopology();
130  unsigned short NAPVPairs = p.nstrips()/256;
131  if( NAPVPairs<2 || NAPVPairs>3 ) {
132  edm::LogError("SiStripGainCosmicCalculator")<<"Problem with Number of strips in detector: "<<p.nstrips()<<" Exiting program";
133  exit(1);
134  }
135  for(int iapp = 0; iapp<NAPVPairs; iapp++){
136  TString hid = Form("ChargeAPVPair_%i_%i",detid,iapp);
137  HlistAPVPairs->Add(new TH1F(hid,hid,45,0.,1350.)); // multiply by 3 to take into account division by width
138  }
139  }
140  }
141  }
142 }
143 
144 //---------------------------------------------------------------------------------------------------------
146  using namespace edm;
148 
149  //TO BE RESTORED
150  // anglefinder_->init(event,iSetup);
151 
152 
153  // get seeds
154 // edm::Handle<TrajectorySeedCollection> seedcoll;
155 // event.getByType(seedcoll);
156  // get tracks
157  Handle<reco::TrackCollection> trackCollection; iEvent.getByLabel(TrackProducer, TrackLabel, trackCollection);
158  const reco::TrackCollection *tracks=trackCollection.product();
159 
160 // // get magnetic field
161 // edm::ESHandle<MagneticField> esmagfield;
162 // es.get<IdealMagneticFieldRecord>().get(esmagfield);
163 // magfield=&(*esmagfield);
164  // loop over tracks
165  for(reco::TrackCollection::const_iterator itr = tracks->begin(); itr != tracks->end(); itr++){ // looping over tracks
166 
167  //TO BE RESTORED
168  // std::vector<std::pair<const TrackingRecHit *,float> >hitangle =anglefinder_->findtrackangle((*(*seedcoll).begin()),*itr);
169  std::vector<std::pair<const TrackingRecHit *,float> >hitangle;// =anglefinder_->findtrackangle((*(*seedcoll).begin()),*itr);
170 
171  for(std::vector<std::pair<const TrackingRecHit *,float> >::const_iterator hitangle_iter=hitangle.begin();hitangle_iter!=hitangle.end();hitangle_iter++){
172  const TrackingRecHit * trechit = hitangle_iter->first;
173  float local_angle=hitangle_iter->second;
174  LocalPoint local_position= trechit->localPosition();
175  const SiStripRecHit2D* sistripsimplehit=dynamic_cast<const SiStripRecHit2D*>(trechit);
176  const SiStripMatchedRecHit2D* sistripmatchedhit=dynamic_cast<const SiStripMatchedRecHit2D*>(trechit);
177 // std::cout<<" hit/matched "<<std::ios::hex<<sistripsimplehit<<" "<<sistripmatchedhit<<std::endl;
178  ((TH1F*) HlistOtherHistos->FindObject("LocalAngle"))->Fill(local_angle);
179  ((TH1F*) HlistOtherHistos->FindObject("LocalAngleAbsoluteCosine"))->Fill(fabs(cos(local_angle)));
180  if(sistripsimplehit){
181  ((TH1F*) HlistOtherHistos->FindObject("SiStripRecHitType"))->Fill(1.);
182  const SiStripRecHit2D::ClusterRef & cluster=sistripsimplehit->cluster();
183  const std::vector<uint8_t>& ampls = cluster->amplitudes();
184 // const std::vector<uint16_t>& ampls = cluster->amplitudes();
185  uint32_t thedetid = 0; // is zero since long time cluster->geographicalId();
186  double module_width = moduleWidth(thedetid, &iSetup);
187  ((TH1F*) HlistOtherHistos->FindObject("LocalPosition_cm"))->Fill(local_position.x());
188  ((TH1F*) HlistOtherHistos->FindObject("LocalPosition_normalized"))->Fill(local_position.x()/module_width);
189  double module_thickness = moduleThickness(thedetid, &iSetup);
190  int ifirststrip= cluster->firstStrip();
191  int theapvpairid = int(float(ifirststrip)/256.);
192  TH1F* histopointer = (TH1F*) HlistAPVPairs->FindObject(Form("ChargeAPVPair_%i_%i",thedetid,theapvpairid));
193  if( histopointer ){
194  short cCharge = 0;
195  for(unsigned int iampl = 0; iampl<ampls.size(); iampl++){
196  cCharge += ampls[iampl];
197  }
198  double cluster_charge_over_path = ((double)cCharge) * fabs(cos(local_angle)) / ( 10. * module_thickness);
199  histopointer->Fill(cluster_charge_over_path);
200  }
201  }else{
202  if(sistripmatchedhit) ((TH1F*) HlistOtherHistos->FindObject("SiStripRecHitType"))->Fill(2.);
203  }
204  }
205  }
206 }
207 
208 
209 //---------------------------------------------------------------------------------------------------------
210 std::pair<double,double> SiStripGainCosmicCalculator::getPeakOfLandau( TH1F * inputHisto){ // automated fitting with finding of the appropriate nr. of ADCs
211  // set some default dummy value and return if no entries
212  double adcs = -0.5; double error = 0.; double nr_of_entries = inputHisto->GetEntries();
213  if(nr_of_entries < MinNrEntries){
214  return std::make_pair(adcs,error);
215  }
216 //
217 // // fit with initial setting of parameter values
218 // double rms_of_histogram = inputHisto->GetRMS();
219 // TF1 *landaufit = new TF1("landaufit","landau",0.,450.);
220 // landaufit->SetParameters(nr_of_entries,mean_of_histogram,rms_of_histogram);
221 // inputHisto->Fit("landaufit","0Q+");
222 // delete landaufit;
223 //
224  // perform fit with standard landau
225  inputHisto->Fit("landau","0Q");
226  TF1 * fitfunction = (TF1*) inputHisto->GetListOfFunctions()->First();
227  adcs = fitfunction->GetParameter("MPV");
228  error = fitfunction->GetParError(1); // MPV is parameter 1 (0=constant, 1=MPV, 2=Sigma)
229  double chi2 = fitfunction->GetChisquare();
230  double ndf = fitfunction->GetNDF();
231  double chi2overndf = chi2 / ndf;
232  // in case things went wrong, try to refit in smaller range
233  if(adcs< 2. || (error/adcs)>1.8 ){
234  inputHisto->Fit("landau","0Q",0,0.,400.);
235  TF1 * fitfunction2 = (TF1*) inputHisto->GetListOfFunctions()->First();
236  std::cout<<"refitting landau for histogram "<<inputHisto->GetTitle()<<std::endl;
237  std::cout<<"initial error/adcs ="<<error<<" / "<<adcs<<std::endl;
238  std::cout<<"new error/adcs ="<<fitfunction2->GetParError(1)<<" / "<<fitfunction2->GetParameter("MPV")<<std::endl;
239  adcs = fitfunction2->GetParameter("MPV");
240  error = fitfunction2->GetParError(1); // MPV is parameter 1 (0=constant, 1=MPV, 2=Sigma)
241  chi2 = fitfunction2->GetChisquare();
242  ndf = fitfunction2->GetNDF();
243  chi2overndf = chi2 / ndf;
244  }
245  // if still wrong, give up
246  if(adcs<2. || chi2overndf>MaxChi2OverNDF){
247  adcs = -0.5; error = 0.;
248  }
249  return std::make_pair(adcs,error);
250 }
251 
252 //---------------------------------------------------------------------------------------------------------
253 double SiStripGainCosmicCalculator::moduleWidth(const uint32_t detid, const edm::EventSetup* iSetup) // get width of the module detid
254 { //dk: copied from A. Giammanco and hacked, module_width values : 10.49 12.03 6.144 7.14 9.3696
255  edm::ESHandle<TrackerGeometry> tkGeom; iSetup->get<TrackerDigiGeometryRecord>().get( tkGeom );
256  double module_width=0.;
257  const GeomDetUnit* it = tkGeom->idToDetUnit(DetId(detid));
258  if (dynamic_cast<const StripGeomDetUnit*>(it)==0 && dynamic_cast<const PixelGeomDetUnit*>(it)==0) {
259  std::cout << "this detID doesn't seem to belong to the Tracker" << std::endl;
260  }else{
261  module_width = it->surface().bounds().width();
262  }
263  return module_width;
264 }
265 
266 //---------------------------------------------------------------------------------------------------------
267 double SiStripGainCosmicCalculator::moduleThickness(const uint32_t detid, const edm::EventSetup* iSetup) // get thickness of the module detid
268 { //dk: copied from A. Giammanco and hacked
269  edm::ESHandle<TrackerGeometry> tkGeom; iSetup->get<TrackerDigiGeometryRecord>().get( tkGeom );
270  double module_thickness=0.;
271  const GeomDetUnit* it = tkGeom->idToDetUnit(DetId(detid));
272  if (dynamic_cast<const StripGeomDetUnit*>(it)==0 && dynamic_cast<const PixelGeomDetUnit*>(it)==0) {
273  std::cout << "this detID doesn't seem to belong to the Tracker" << std::endl;
274  }else{
275  module_thickness = it->surface().bounds().thickness();
276  }
277  return module_thickness;
278 }
279 
280 //---------------------------------------------------------------------------------------------------------
282  std::cout<<"SiStripGainCosmicCalculator::getNewObject called"<<std::endl;
283 
284  std::cout<<"total_nr_of_events="<<total_nr_of_events<<std::endl;
285  // book some more histograms
286  TH1F *ChargeOfEachAPVPair = new TH1F("ChargeOfEachAPVPair","ChargeOfEachAPVPair",1,0,1); ChargeOfEachAPVPair->SetBit(TH1::kCanRebin);
287  TH1F *EntriesApvPairs = new TH1F("EntriesApvPairs","EntriesApvPairs",1,0,1); EntriesApvPairs->SetBit(TH1::kCanRebin);
288  TH1F * NrOfEntries = new TH1F("NrOfEntries","NrOfEntries",351,-0.5,350.5);// NrOfEntries->SetBit(TH1::kCanRebin);
289  TH1F * ModuleThickness = new TH1F("ModuleThickness","ModuleThickness",2,0.5,2.5); HlistOtherHistos->Add(ModuleThickness);
290  ModuleThickness->GetXaxis()->SetBinLabel(1,"320mu"); ModuleThickness->GetXaxis()->SetBinLabel(2,"500mu"); ModuleThickness->SetYTitle("Nr APVPairs");
291  TH1F * ModuleWidth = new TH1F("ModuleWidth","ModuleWidth",5,0.5,5.5); HlistOtherHistos->Add(ModuleWidth);
292  ModuleWidth->GetXaxis()->SetBinLabel(1,"6.144cm"); ModuleWidth->GetXaxis()->SetBinLabel(2,"7.14cm");
293  ModuleWidth->GetXaxis()->SetBinLabel(3,"9.3696cm"); ModuleWidth->GetXaxis()->SetBinLabel(4,"10.49cm");
294  ModuleWidth->GetXaxis()->SetBinLabel(5,"12.03cm");
295  ModuleWidth->SetYTitle("Nr APVPairs");
296  // loop over single histograms and extract peak value of charge
297  HlistAPVPairs->Sort(); // sort alfabetically
298  TIter hiterator(HlistAPVPairs);
299  double MeanCharge = 0.;
300  double NrOfApvPairs = 0.;
301  TH1F *MyHisto = (TH1F*)hiterator();
302  while( MyHisto ){
303  TString histo_title = MyHisto->GetTitle();
304  if(histo_title.Contains("ChargeAPVPair_")){
305  std::pair<double,double> two_values = getPeakOfLandau(MyHisto);
306  double local_nrofadcs = two_values.first;
307  double local_sigma = two_values.second;
308  ChargeOfEachAPVPair->Fill(histo_title, local_nrofadcs);
309  int ichbin = ChargeOfEachAPVPair->GetXaxis()->FindBin(histo_title.Data());
310  ChargeOfEachAPVPair->SetBinError(ichbin,local_sigma);
311  EntriesApvPairs->Fill(histo_title, MyHisto->GetEntries());
312  NrOfEntries->Fill(MyHisto->GetEntries());
313  if(local_nrofadcs > 0){ // if nr of adcs is negative, the fitting routine could not extract meaningfull numbers
314  MeanCharge += local_nrofadcs;
315  NrOfApvPairs += 1.; // count nr of apv pairs since do not know whether nr of bins of histogram is the same
316  }
317  }
318  MyHisto = (TH1F*)hiterator();
319  }
320  ChargeOfEachAPVPair->LabelsDeflate("X"); EntriesApvPairs->LabelsDeflate("X"); // trim nr. of bins to match active labels
321  HlistOtherHistos->Add(ChargeOfEachAPVPair);
322  HlistOtherHistos->Add(EntriesApvPairs);
323  HlistOtherHistos->Add(NrOfEntries);
324  MeanCharge = MeanCharge / NrOfApvPairs;
325  // calculate correction
326  TH1F* CorrectionOfEachAPVPair = (TH1F*) ChargeOfEachAPVPair->Clone("CorrectionOfEachAPVPair");
327  TH1F *ChargeOfEachAPVPairControlView = new TH1F("ChargeOfEachAPVPairControlView","ChargeOfEachAPVPairControlView",1,0,1); ChargeOfEachAPVPairControlView->SetBit(TH1::kCanRebin);
328 TH1F *CorrectionOfEachAPVPairControlView = new TH1F("CorrectionOfEachAPVPairControlView","CorrectionOfEachAPVPairControlView",1,0,1); CorrectionOfEachAPVPairControlView->SetBit(TH1::kCanRebin);
329  std::ofstream APVPairTextOutput("apvpair_corrections.txt");
330  APVPairTextOutput<<"# MeanCharge = "<<MeanCharge<<std::endl;
331  APVPairTextOutput<<"# Nr. of APVPairs = "<<NrOfApvPairs<<std::endl;
332  for(int ibin=1; ibin <= ChargeOfEachAPVPair->GetNbinsX(); ibin++){
333  TString local_bin_label = ChargeOfEachAPVPair->GetXaxis()->GetBinLabel(ibin);
334  double local_charge_over_path = ChargeOfEachAPVPair->GetBinContent(ibin);
335  if(local_bin_label.Contains("ChargeAPVPair_") && local_charge_over_path > 0.0000001){ // calculate correction only for meaningful numbers
336  uint32_t extracted_detid; std::istringstream read_label((local_bin_label(14,9)).Data()); read_label >> extracted_detid;
337  unsigned short extracted_apvpairid; std::istringstream read_apvpair((local_bin_label(24,1)).Data()); read_apvpair >> extracted_apvpairid;
338  double local_error_of_charge = ChargeOfEachAPVPair->GetBinError(ibin);
339  double local_correction = -0.5;
340  double local_error_correction = 0.;
341  local_correction = MeanCharge / local_charge_over_path; // later use ExpectedChargeDeposition instead of MeanCharge
342  local_error_correction = local_correction * local_error_of_charge / local_charge_over_path;
343  if(local_error_correction>1.8){ // understand why error too large sometimes
344  std::cout<<"too large error "<<local_error_correction<<" for histogram "<<local_bin_label<<std::endl;
345  }
346  double nr_of_entries = EntriesApvPairs->GetBinContent(ibin);
347  APVPairTextOutput<<local_bin_label<<" "<<local_correction<<" "<<local_charge_over_path<<" "<<nr_of_entries<<std::endl;
348  CorrectionOfEachAPVPair->SetBinContent(ibin, local_correction);
349  CorrectionOfEachAPVPair->SetBinError(ibin, local_error_correction);
350  ((TH1F*) HlistOtherHistos->FindObject("APVPairCorrections"))->Fill(local_correction);
351  DetId thedetId = DetId(extracted_detid);
352  unsigned int generalized_layer = 0;
353  // calculate generalized_layer: 31,32 = TIB1, 33 = TIB2, 33 = TIB3, 51 = TOB1, 52 = TOB2, 60 = TEC
354  if(thedetId.subdetId()==StripSubdetector::TIB){
355 
356  generalized_layer = 10*thedetId.subdetId() + tTopo->tibLayer(thedetId.rawId()) + tTopo->tibStereo(thedetId.rawId());
357  if(tTopo->tibLayer(thedetId.rawId())==2){
358  generalized_layer++;
359  if (tTopo->tibGlued(thedetId.rawId())) edm::LogError("ClusterMTCCFilter")<<"WRONGGGG"<<std::endl;
360  }
361  }else{
362  generalized_layer = 10*thedetId.subdetId();
363  if(thedetId.subdetId()==StripSubdetector::TOB){
364 
365  generalized_layer += tTopo->tobLayer(thedetId.rawId());
366  }
367  }
368  if(generalized_layer==31){
369  ((TH1F*) HlistOtherHistos->FindObject("APVPairCorrectionsTIB1mono"))->Fill(local_correction);
370  }
371  if(generalized_layer==32){
372  ((TH1F*) HlistOtherHistos->FindObject("APVPairCorrectionsTIB1stereo"))->Fill(local_correction);
373  }
374  if(generalized_layer==33){
375  ((TH1F*) HlistOtherHistos->FindObject("APVPairCorrectionsTIB2"))->Fill(local_correction);
376  }
377  if(generalized_layer==51){
378  ((TH1F*) HlistOtherHistos->FindObject("APVPairCorrectionsTOB1"))->Fill(local_correction);
379  }
380  if(generalized_layer==52){
381  ((TH1F*) HlistOtherHistos->FindObject("APVPairCorrectionsTOB2"))->Fill(local_correction);
382  }
383  // control view
384  edm::ESHandle<SiStripDetCabling> siStripDetCabling; eventSetupCopy_->get<SiStripDetCablingRcd>().get(siStripDetCabling);
385  const FedChannelConnection& fedchannelconnection = siStripDetCabling->getConnection( extracted_detid, extracted_apvpairid );
386  std::ostringstream local_key;
387  // in S. Mersi's analysis the APVPair id seems to be used instead of the lldChannel, hence use the same here
388  local_key<<"fecCrate"<<fedchannelconnection.fecCrate()<<"_fecSlot"<<fedchannelconnection.fecSlot()<<"_fecRing"<<fedchannelconnection.fecRing()<<"_ccuAddr"<<fedchannelconnection.ccuAddr()<<"_ccuChan"<<fedchannelconnection.ccuChan()<<"_apvPair"<<extracted_apvpairid;
389  TString control_key = local_key.str();
390  ChargeOfEachAPVPairControlView->Fill(control_key,local_charge_over_path);
391  int ibin1 = ChargeOfEachAPVPairControlView->GetXaxis()->FindBin(control_key);
392  ChargeOfEachAPVPairControlView->SetBinError(ibin1,local_error_of_charge);
393  CorrectionOfEachAPVPairControlView->Fill(control_key, local_correction);
394  int ibin2 = CorrectionOfEachAPVPairControlView->GetXaxis()->FindBin(control_key);
395  CorrectionOfEachAPVPairControlView->SetBinError(ibin2, local_error_correction);
396  // thickness of each module
397  double module_thickness = moduleThickness(extracted_detid, eventSetupCopy_);
398  if( fabs(module_thickness - 0.032)<0.001 ) ModuleThickness->Fill(1);
399  if( fabs(module_thickness - 0.05)<0.001 ) ModuleThickness->Fill(2);
400  // width of each module
401  double module_width = moduleWidth(extracted_detid, eventSetupCopy_);
402  if(fabs(module_width-6.144)<0.01) ModuleWidth->Fill(1);
403  if(fabs(module_width-7.14)<0.01) ModuleWidth->Fill(2);
404  if(fabs(module_width-9.3696)<0.01) ModuleWidth->Fill(3);
405  if(fabs(module_width-10.49)<0.01) ModuleWidth->Fill(4);
406  if(fabs(module_width-12.03)<0.01) ModuleWidth->Fill(5);
407  }
408  }
409  HlistOtherHistos->Add(CorrectionOfEachAPVPair);
410  ChargeOfEachAPVPairControlView->LabelsDeflate("X");
411  CorrectionOfEachAPVPairControlView->LabelsDeflate("X");
412  HlistOtherHistos->Add(ChargeOfEachAPVPairControlView);
413  HlistOtherHistos->Add(CorrectionOfEachAPVPairControlView);
414  // output histograms to file
415 
416 
418  TFile *outputfile = new TFile(outputFileName,"RECREATE");
419  HlistAPVPairs->Write();
420  HlistOtherHistos->Write();
421  outputfile->Close();
422  }
423 
425 
426 // for(std::map<uint32_t,OptoScanAnalysis*>::const_iterator it = analyses.begin(); it != analyses.end(); it++){
427 // //Generate Gain for det detid
428 // std::vector<float> theSiStripVector;
429 // for(unsigned short j=0; j<it->second; j++){
430 // float gain;
431 
432 // // if(sigmaGain_/meanGain_ < 0.00001) gain = meanGain_;
433 // // else{
434 // gain = CLHEP::RandGauss::shoot(meanGain_, sigmaGain_);
435 // if(gain<=minimumPosValue_) gain=minimumPosValue_;
436 // // }
437 
438 // if (printdebug_)
439 // edm::LogInfo("SiStripGainCalculator") << "detid " << it->first << " \t"
440 // << " apv " << j << " \t"
441 // << gain << " \t"
442 // << std::endl;
443 // theSiStripVector.push_back(gain);
444 // }
445 // SiStripApvGain::Range range(theSiStripVector.begin(),theSiStripVector.end());
446 // if ( ! obj->put(it->first,range) )
447 // edm::LogError("SiStripGainCalculator")<<"[SiStripGainCalculator::beginJob] detid already exists"<<std::endl;
448 // }
449 
450  return obj;
451 }
452 
const uint16_t & fecSlot() const
T getParameter(std::string const &) const
virtual int nstrips() const =0
T getUntrackedParameter(std::string const &, T const &) const
std::vector< uint32_t > SelectedDetIds
const uint16_t & fecCrate() const
unsigned int tibLayer(const DetId &id) const
double moduleThickness(const uint32_t detid, const edm::EventSetup *iSetup)
const edm::EventSetup * eventSetupCopy_
std::vector< Track > TrackCollection
collection of Tracks
Definition: TrackFwd.h:10
const Bounds & bounds() const
Definition: Surface.h:128
double moduleWidth(const uint32_t detid, const edm::EventSetup *iSetup)
const Plane & surface() const
The nominal surface of the GeomDet.
Definition: GeomDet.h:35
std::pair< double, double > getPeakOfLandau(TH1F *inputHisto)
uint32_t rawId() const
get the raw id
Definition: DetId.h:43
virtual float thickness() const =0
int iEvent
Definition: GenABIO.cc:230
const uint16_t & fecRing() const
void getTOBDetectors(const std::vector< uint32_t > &inputDetRawIds, std::vector< uint32_t > &tobDetRawIds, uint32_t layer=0, uint32_t bkw_frw=0, uint32_t rod=0) const
Class containning control, module, detector and connection information, at the level of a FED channel...
void Fill(HcalDetId &id, double val, std::vector< TH2F > &depth)
void algoBeginJob(const edm::EventSetup &)
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
const uint16_t & ccuChan() const
SiStripGainCosmicCalculator(const edm::ParameterSet &)
std::map< uint32_t, double > thickness_map
ClusterRef cluster() const
int subdetId() const
get the contents of the subdetector field (not cast into any detector&#39;s numbering enum) ...
Definition: DetId.h:37
const uint16_t & ccuAddr() const
bool getByLabel(InputTag const &tag, Handle< PROD > &result) const
Definition: Event.h:390
Definition: DetId.h:18
uint32_t tibGlued(const DetId &id) const
tuple tracks
Definition: testEve_cfg.py:39
const T & get() const
Definition: EventSetup.h:55
std::vector< uint32_t > detModulesToBeExcluded
T const * product() const
Definition: ESHandle.h:62
void algoAnalyze(const edm::Event &, const edm::EventSetup &)
void getTIBDetectors(const std::vector< uint32_t > &inputDetRawIds, std::vector< uint32_t > &tibDetRawIds, uint32_t layer=0, uint32_t bkw_frw=0, uint32_t int_ext=0, uint32_t string=0) const
tuple cout
Definition: gather_cfg.py:121
uint32_t tibStereo(const DetId &id) const
T x() const
Definition: PV3DBase.h:62
virtual LocalPoint localPosition() const =0
virtual float width() const =0
unsigned int tobLayer(const DetId &id) const