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DTT0CalibrationNew.cc
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1 /*
2  * See header file for a description of this class.
3  *
4  * \author S. Bolognesi - INFN Torino
5  * 06/08/2008 Mofified by Antonio.Vilela.Pereira@cern.ch
6  */
7 
10 
13 
16 
19 
22 
23 #include "TH1I.h"
24 #include "TFile.h"
25 #include "TKey.h"
26 #include "TSpectrum.h"
27 #include "TF1.h"
28 
29 using namespace std;
30 using namespace edm;
31 // using namespace cond;
32 
33 // Constructor
35  // Get the debug parameter for verbose output
36  debug = pset.getUntrackedParameter<bool>("debug");
37  if(debug)
38  cout << "[DTT0CalibrationNew]Constructor called!" << endl;
39 
40  // Get the label to retrieve digis from the event
41  digiLabel = pset.getUntrackedParameter<string>("digiLabel");
42 
43  dbLabel = pset.getUntrackedParameter<string>("dbLabel", "");
44 
45  // The root file which contain the histos per layer
46  string rootFileName = pset.getUntrackedParameter<string>("rootFileName","DTT0PerLayer.root");
47  theFile = new TFile(rootFileName.c_str(), "RECREATE");
48 
49  theCalibWheel = pset.getUntrackedParameter<string>("calibWheel", "All"); //FIXME amke a vector of integer instead of a string
50  if(theCalibWheel != "All") {
51  stringstream linestr;
52  int selWheel;
53  linestr << theCalibWheel;
54  linestr >> selWheel;
55  cout << "[DTT0CalibrationNewPerLayer] chosen wheel " << selWheel << endl;
56  }
57 
58  // Sector/s to calibrate
59  theCalibSector = pset.getUntrackedParameter<string>("calibSector", "All"); //FIXME amke a vector of integer instead of a string
60  if(theCalibSector != "All") {
61  stringstream linestr;
62  int selSector;
63  linestr << theCalibSector;
64  linestr >> selSector;
65  cout << "[DTT0CalibrationNewPerLayer] chosen sector " << selSector << endl;
66  }
67 
68  vector<string> defaultCell;
69  defaultCell.push_back("None");
70  cellsWithHistos = pset.getUntrackedParameter<vector<string> >("cellsWithHisto", defaultCell);
71  for(vector<string>::const_iterator cell = cellsWithHistos.begin(); cell != cellsWithHistos.end(); ++cell){
72  if((*cell) != "None"){
73  stringstream linestr;
74  int wheel,sector,station,sl,layer,wire;
75  linestr << (*cell);
76  linestr >> wheel >> sector >> station >> sl >> layer >> wire;
77  wireIdWithHistos.push_back(DTWireId(wheel,station,sector,sl,layer,wire));
78  }
79  }
80 
81  hT0SectorHisto=0;
82 
83  nevents=0;
84  eventsForLayerT0 = pset.getParameter<unsigned int>("eventsForLayerT0");
85  eventsForWireT0 = pset.getParameter<unsigned int>("eventsForWireT0");
86  tpPeakWidth = pset.getParameter<double>("tpPeakWidth");
87  tpPeakWidthPerLayer = pset.getParameter<double>("tpPeakWidthPerLayer");
88  timeBoxWidth = pset.getParameter<unsigned int>("timeBoxWidth");
89  rejectDigiFromPeak = pset.getParameter<unsigned int>("rejectDigiFromPeak");
90 
91  spectrum = new TSpectrum(5);
92  retryForLayerT0 = 0;
93 }
94 
95 // Destructor
97  if(debug)
98  cout << "[DTT0CalibrationNew]Destructor called!" << endl;
99 
100  delete spectrum;
101  theFile->Close();
102 }
103 
106  if(debug || event.id().event() % 500==0)
107  cout << "--- [DTT0CalibrationNew] Analysing Event: #Run: " << event.id().run()
108  << " #Event: " << event.id().event() << endl;
109  nevents++;
110 
111  // Get the digis from the event
113  event.getByLabel(digiLabel, digis);
114 
115  // Get the DT Geometry
116  eventSetup.get<MuonGeometryRecord>().get(dtGeom);
117 
118  // Get ttrig DB
119  edm::ESHandle<DTTtrig> tTrigMap;
120  eventSetup.get<DTTtrigRcd>().get(dbLabel,tTrigMap);
121 
122  // Iterate through all digi collections ordered by LayerId
124  for (dtLayerIt = digis->begin();
125  dtLayerIt != digis->end();
126  ++dtLayerIt){
127  // Get the iterators over the digis associated with this LayerId
128  const DTDigiCollection::Range& digiRange = (*dtLayerIt).second;
129 
130  // Get the layerId
131  const DTLayerId layerId = (*dtLayerIt).first; //FIXME: check to be in the right sector
132  const DTChamberId chamberId = layerId.superlayerId().chamberId();
133 
134  if((theCalibWheel != "All") && (layerId.superlayerId().chamberId().wheel() != selWheel))
135  continue;
136  if((theCalibSector != "All") && (layerId.superlayerId().chamberId().sector() != selSector))
137  continue;
138 
139  //if(debug) {
140  // cout << "Layer " << layerId<<" with "<<distance(digiRange.first, digiRange.second)<<" digi"<<endl;
141  //}
142 
143  float tTrig,tTrigRMS, kFactor;
144  tTrigMap->get(layerId.superlayerId(), tTrig, tTrigRMS, kFactor, DTTimeUnits::counts );
145  if(debug&&(nevents <= 1)){
146  cout << " Superlayer: " << layerId.superlayerId() << endl
147  << " tTrig,tTrigRMS= " << tTrig << ", " << tTrigRMS << endl;
148  }
149 
150  // Loop over all digis in the given layer
151  for (DTDigiCollection::const_iterator digi = digiRange.first;
152  digi != digiRange.second;
153  ++digi) {
154  double t0 = (*digi).countsTDC();
155 
156  //Use first bunch of events to fill t0 per layer
157  if(nevents < eventsForLayerT0){
158  //Get the per-layer histo from the map
159  TH1I *hT0LayerHisto = theHistoLayerMap[layerId];
160  //If it doesn't exist, book it
161  if(hT0LayerHisto == 0){
162  theFile->cd();
163  float hT0Min = tTrig - 2*tTrigRMS;
164  float hT0Max = hT0Min + timeBoxWidth;
165  hT0LayerHisto = new TH1I(getHistoName(layerId).c_str(),
166  "T0 from pulses by layer (TDC counts, 1 TDC count = 0.781 ns)",
167  timeBoxWidth,hT0Min,hT0Max);
168  if(debug)
169  cout << " New T0 per Layer Histo: " << hT0LayerHisto->GetName() << endl;
170  theHistoLayerMap[layerId] = hT0LayerHisto;
171  }
172 
173  //Fill the histos
174  theFile->cd();
175  if(hT0LayerHisto != 0) {
176  // if(debug)
177  // cout<<"Filling histo "<<hT0LayerHisto->GetName()<<" with digi "<<t0<<" TDC counts"<<endl;
178  hT0LayerHisto->Fill(t0);
179  }
180  }
181 
182  //Use all the remaining events to compute t0 per wire
183  if(nevents>eventsForLayerT0){
184  // Get the wireId
185  const DTWireId wireId(layerId, (*digi).wire());
186  if(debug) {
187  cout << " Wire: " << wireId << endl
188  << " time (TDC counts): " << (*digi).countsTDC()<< endl;
189  }
190 
191  //Fill the histos per wire for the chosen cells
192  vector<DTWireId>::iterator it = find(wireIdWithHistos.begin(),wireIdWithHistos.end(),wireId);
193  if (it!=wireIdWithHistos.end()){
194  //Get the per-wire histo from the map
195  TH1I *hT0WireHisto = theHistoWireMap[wireId];
196  //If it doesn't exist, book it
197  if(hT0WireHisto == 0){
198  theFile->cd();
199  hT0WireHisto = new TH1I(getHistoName(wireId).c_str(),"T0 from pulses by wire (TDC counts, 1 TDC count = 0.781 ns)",7000,0,7000);
200  //hT0SectorHisto->GetBinCenter(hT0SectorHisto->GetMaximumBin())-100,
201  //hT0SectorHisto->GetBinCenter(hT0SectorHisto->GetMaximumBin())+100);
202  if(debug)
203  cout << " New T0 per wire Histo: " << hT0WireHisto->GetName() << endl;
204  theHistoWireMap[wireId] = hT0WireHisto;
205  }
206  //Fill the histos
207  theFile->cd();
208  if(hT0WireHisto != 0) {
209  //if(debug)
210  // cout<<"Filling histo "<<hT0WireHisto->GetName()<<" with digi "<<t0<<" TDC counts"<<endl;
211  hT0WireHisto->Fill(t0);
212  }
213  }
214 
215  //Check the tzero has reasonable value
216  //float hT0Min = tTrig - 2*tTrigRMS;
217  //float hT0Max = hT0Min + timeBoxWidth;
218  /*if(abs(hT0SectorHisto->GetBinCenter(hT0SectorHisto->GetMaximumBin()) - t0) > rejectDigiFromPeak){
219  if(debug)
220  cout<<"digi skipped because t0 per sector "<<hT0SectorHisto->GetBinCenter(hT0SectorHisto->GetMaximumBin())<<endl;
221  continue;
222  }*/
223  /*if((t0 < hT0Min)||(t0 > hT0Max)){
224  if(debug)
225  cout<<"digi skipped because t0 outside of interval (" << hT0Min << "," << hT0Max << ")" <<endl;
226  continue;
227  }*/
228  //Select per layer
229  if(fabs(theTPPeakMap[layerId] - t0) > rejectDigiFromPeak){
230  if(debug)
231  cout<<"digi skipped because t0 too far from peak " << theTPPeakMap[layerId] << endl;
232  continue;
233  }
234 
235  //Find to ref. per chamber
236  theSumT0ByChamber[chamberId] = theSumT0ByChamber[chamberId] + t0;
237  theCountT0ByChamber[chamberId]++;
238 
239  //Use second bunch of events to compute a t0 reference per wire
240  if(nevents< (eventsForLayerT0 + eventsForWireT0)){
241  if(!nDigiPerWire_ref[wireId]){
242  mK_ref[wireId] = 0;
243  }
244  nDigiPerWire_ref[wireId] = nDigiPerWire_ref[wireId] + 1;
245  mK_ref[wireId] = mK_ref[wireId] + (t0-mK_ref[wireId])/nDigiPerWire_ref[wireId];
246  }
247  //Use last all the remaining events to compute the mean and sigma t0 per wire
248  else if(nevents>(eventsForLayerT0 + eventsForWireT0)){
249  if(abs(t0-mK_ref[wireId]) > tpPeakWidth)
250  continue;
251  if(!nDigiPerWire[wireId]){
252  theAbsoluteT0PerWire[wireId] = 0;
253  qK[wireId] = 0;
254  mK[wireId] = 0;
255  }
256  nDigiPerWire[wireId] = nDigiPerWire[wireId] + 1;
257  theAbsoluteT0PerWire[wireId] = theAbsoluteT0PerWire[wireId] + t0;
258  //theSigmaT0PerWire[wireId] = theSigmaT0PerWire[wireId] + (t0*t0);
259  qK[wireId] = qK[wireId] + ((nDigiPerWire[wireId]-1)*(t0-mK[wireId])*(t0-mK[wireId])/nDigiPerWire[wireId]);
260  mK[wireId] = mK[wireId] + (t0-mK[wireId])/nDigiPerWire[wireId];
261  }
262  }//end if(nevents>1000)
263  }//end loop on digi
264  }//end loop on layer
265 
266  //Use the t0 per layer histos to have an indication about the t0 position
267  if(nevents == eventsForLayerT0){
268  bool increaseEvtsForLayerT0 = false;
269  for(map<DTLayerId, TH1I*>::const_iterator lHisto = theHistoLayerMap.begin();
270  lHisto != theHistoLayerMap.end();
271  ++lHisto){
272  if(debug)
273  cout<<"Reading histogram "<<(*lHisto).second->GetName()<<" with mean "<<(*lHisto).second->GetMean()<<" and RMS "<<(*lHisto).second->GetRMS() << endl;
274 
275  //Find peaks
276  //int npeaks = spectrum->Search((*lHisto).second,0.5,"goff");
277  //int npeaks = spectrum->Search((*lHisto).second,(tpPeakWidthPerLayer/2.),"goff",0.3);
278  int npeaks = spectrum->Search((*lHisto).second,(tpPeakWidthPerLayer/2.),"",0.3);
279 
280  double *peaks = spectrum->GetPositionX();
281  //Put in a std::vector<float>
282  vector<float> peakMeans(peaks,peaks + npeaks);
283  //Sort the peaks in ascending order
284  sort(peakMeans.begin(),peakMeans.end());
285 
286  //Find best peak -- preliminary criteria: find peak closest to center of time box
287  float tTrig,tTrigRMS, kFactor;
288  tTrigMap->get((*lHisto).first.superlayerId(), tTrig, tTrigRMS, kFactor, DTTimeUnits::counts );
289 
290  float timeBoxCenter = (2*tTrig + (float)timeBoxWidth)/2.;
291  float hMin = (*lHisto).second->GetXaxis()->GetXmin();
292  float hMax = (*lHisto).second->GetXaxis()->GetXmax();
293  vector<float>::const_iterator tpPeak = peakMeans.end();
294  for(vector<float>::const_iterator it = peakMeans.begin(); it != peakMeans.end(); ++it){
295  float mean = *it;
296 
297  int bin = (*lHisto).second->GetXaxis()->FindBin(mean);
298  float yp = (*lHisto).second->GetBinContent(bin);
299  if(debug) cout << "Peak : (" << mean << "," << yp << ")" << endl;
300 
301  //Find RMS
302  float previous_peak = (it == peakMeans.begin())?hMin:*(it - 1);
303  float next_peak = (it == (peakMeans.end()-1))?hMax:*(it + 1);
304 
305  float rangemin = mean - (mean - previous_peak)/8.;
306  float rangemax = mean + (next_peak - mean)/8.;
307  int binmin = (*lHisto).second->GetXaxis()->FindBin(rangemin);
308  int binmax = (*lHisto).second->GetXaxis()->FindBin(rangemax);
309  (*lHisto).second->GetXaxis()->SetRange(binmin,binmax);
310  //RMS estimate
311  float rms_seed = (*lHisto).second->GetRMS();
312 
313  /*rangemin = mean - 2*rms_seed;
314  rangemax = mean + 2*rms_seed;
315  if(debug) cout << "Seed for RMS, Fit min, Fit max: " << rms_seed << ", " << rangemin << ", " << rangemax << endl;
316  //Fit to gaussian
317  string funcname("fitFcn_");
318  funcname += (*lHisto).second->GetName();
319  if(debug) cout << "Fitting function " << funcname << endl;
320  TF1* func = new TF1(funcname.c_str(),"gaus",rangemin,rangemax);
321  func->SetParameters(yp,mean,rms_seed);
322  (*lHisto).second->Fit(func,"Q","",rangemin,rangemax);
323 
324  float fitconst = func->GetParameter(0);
325  float fitmean = func->GetParameter(1);
326  float fitrms = func->GetParameter(2);
327  float chisquare = func->GetChisquare()/func->GetNDF();
328  if(debug) cout << "Gaussian fit constant,mean,RMS,chi2= " << fitconst << ", " << fitmean << ", " << fitrms << ", " << chisquare << endl;*/
329 
330  //Reject peaks with RMS larger than specified
331  //if(fitrms > tpPeakWidth) continue;
332  if(rms_seed > tpPeakWidthPerLayer) continue;
333 
334  if(fabs(mean - timeBoxCenter) < fabs(*tpPeak - timeBoxCenter)) tpPeak = it;
335  }
336  //Didn't find peak
337  /*if(tpPeak == peakMeans.end()){
338  if(retryForLayerT0 < 2){
339  increaseEvtsForLayerT0 = true;
340  retryForLayerT0++;
341  break;
342  }
343  }*/
344 
345  float selPeak = (tpPeak != peakMeans.end())?*tpPeak:(*lHisto).second->GetBinCenter((*lHisto).second->GetMaximumBin());
346  if(debug) cout << "Peak selected at " << selPeak << endl;
347 
348  theTPPeakMap[(*lHisto).first] = selPeak;
349 
350  //Take the mean as a first t0 estimation
351  /*if((*lHisto).second->GetRMS() < tpPeakWidth){
352  if(hT0SectorHisto == 0){
353  hT0SectorHisto = new TH1D("hT0AllLayerOfSector","T0 from pulses per layer in sector",
354  //20, (*lHisto).second->GetMean()-100, (*lHisto).second->GetMean()+100);
355  700, 0, 7000);
356  //300,3300,3600);
357  }
358  if(debug)
359  cout<<" accepted"<<endl;
360  //TH1I* aux_histo = (*lHisto).second;
361  //aux_histo->GetXaxis()->SetRangeUser(3300,3600);
362  hT0SectorHisto->Fill((*lHisto).second->GetMean());
363  //hT0SectorHisto->Fill(aux_histo->GetMean());
364  }
365  //Take the mean of noise + 400ns as a first t0 estimation
366  //if((*lHisto).second->GetRMS()>10.0 && ((*lHisto).second->GetRMS()<15.0)){
367  //double t0_estim = (*lHisto).second->GetMean() + 400;
368  //if(hT0SectorHisto == 0){
369  // hT0SectorHisto = new TH1D("hT0AllLayerOfSector","T0 from pulses per layer in sector",
370  // //20, t0_estim-100, t0_estim+100);
371  // 700, 0, 7000);
372  //}
373  //if(debug)
374  // cout<<" accepted + 400ns"<<endl;
375  //hT0SectorHisto->Fill((*lHisto).second->GetMean() + 400);
376  //}
377  if(debug)
378  cout<<endl;
379 
380  theT0LayerMap[(*lHisto).second->GetName()] = (*lHisto).second->GetMean();
381  theSigmaT0LayerMap[(*lHisto).second->GetName()] = (*lHisto).second->GetRMS();*/
382  }
383  /*if(!hT0SectorHisto){
384  cout<<"[DTT0CalibrationNew]: All the t0 per layer are still uncorrect: trying with greater number of events"<<endl;
385  eventsForLayerT0 = eventsForLayerT0*2;
386  return;
387  }
388  if(debug)
389  cout<<"[DTT0CalibrationNew] t0 reference for this sector "<<
390  hT0SectorHisto->GetBinCenter(hT0SectorHisto->GetMaximumBin())<<endl;*/
391  if(increaseEvtsForLayerT0){
392  cout<<"[DTT0CalibrationNew]: t0 per layer are still uncorrect: trying with greater number of events"<<endl;
393  eventsForLayerT0 = eventsForLayerT0*2;
394  return;
395  }
396  }
397 }
398 
400 
401  DTT0* t0s = new DTT0();
402  DTT0* t0sWRTChamber = new DTT0();
403 
404  if(debug)
405  cout << "[DTT0CalibrationNewPerLayer]Writing histos to file!" << endl;
406 
407  theFile->cd();
408  //hT0SectorHisto->Write();
409  for(map<DTWireId, TH1I*>::const_iterator wHisto = theHistoWireMap.begin();
410  wHisto != theHistoWireMap.end();
411  ++wHisto) {
412  (*wHisto).second->Write();
413  }
414  for(map<DTLayerId, TH1I*>::const_iterator lHisto = theHistoLayerMap.begin();
415  lHisto != theHistoLayerMap.end();
416  ++lHisto) {
417  (*lHisto).second->Write();
418  }
419 
420  if(debug)
421  cout << "[DTT0CalibrationNew] Compute and store t0 and sigma per wire" << endl;
422 
423  for(map<DTChamberId,double>::const_iterator chamber = theSumT0ByChamber.begin();
424  chamber != theSumT0ByChamber.end();
425  ++chamber) theRefT0ByChamber[(*chamber).first] = theSumT0ByChamber[(*chamber).first]/((double)theCountT0ByChamber[(*chamber).first]);
426 
427  for(map<DTWireId, double>::const_iterator wiret0 = theAbsoluteT0PerWire.begin();
428  wiret0 != theAbsoluteT0PerWire.end();
429  ++wiret0){
430  if(nDigiPerWire[(*wiret0).first]){
431  double t0 = (*wiret0).second/nDigiPerWire[(*wiret0).first];
432  DTChamberId chamberId = ((*wiret0).first).chamberId();
433  //theRelativeT0PerWire[(*wiret0).first] = t0 - hT0SectorHisto->GetBinCenter(hT0SectorHisto->GetMaximumBin());
434  theRelativeT0PerWire[(*wiret0).first] = t0 - theRefT0ByChamber[chamberId];
435  cout<<"Wire "<<(*wiret0).first<<" has t0 "<<t0<<"(absolute) "<<theRelativeT0PerWire[(*wiret0).first]<<"(relative)";
436 
437  //theSigmaT0PerWire[(*wiret0).first] = sqrt((theSigmaT0PerWire[(*wiret0).first] / nDigiPerWire[(*wiret0).first]) - t0*t0);
438  theSigmaT0PerWire[(*wiret0).first] = sqrt(qK[(*wiret0).first]/nDigiPerWire[(*wiret0).first]);
439  cout<<" sigma "<<theSigmaT0PerWire[(*wiret0).first]<<endl;
440  }
441  else{
442  cout<<"[DTT0CalibrationNew] ERROR: no digis in wire "<<(*wiret0).first<<endl;
443  abort();
444  }
445  }
446 
448  // Get all the sls from the setup
449  const vector<const DTSuperLayer*>& superLayers = dtGeom->superLayers();
450  // Loop over all SLs
451  for(auto sl = superLayers.begin();
452  sl != superLayers.end(); sl++) {
453 
454 
455  //Compute mean for odd and even superlayers
456  double oddLayersMean=0;
457  double evenLayersMean=0;
458  double oddLayersDen=0;
459  double evenLayersDen=0;
460  for(map<DTWireId, double>::const_iterator wiret0 = theRelativeT0PerWire.begin();
461  wiret0 != theRelativeT0PerWire.end();
462  ++wiret0){
463  if((*wiret0).first.layerId().superlayerId() == (*sl)->id()){
464  if(debug)
465  cout<<"[DTT0CalibrationNew] Superlayer "<<(*sl)->id()
466  <<"layer " <<(*wiret0).first.layerId().layer()<<" with "<<(*wiret0).second<<endl;
467  if(((*wiret0).first.layerId().layer()) % 2){
468  oddLayersMean = oddLayersMean + (*wiret0).second;
469  oddLayersDen++;
470  }
471  else{
472  evenLayersMean = evenLayersMean + (*wiret0).second;
473  evenLayersDen++;
474  }
475  }
476  }
477  oddLayersMean = oddLayersMean/oddLayersDen;
478  evenLayersMean = evenLayersMean/evenLayersDen;
479  if(debug && oddLayersMean)
480  cout<<"[DTT0CalibrationNew] Relative T0 mean for odd layers "<<oddLayersMean<<" even layers"<<evenLayersMean<<endl;
481 
482  //Compute sigma for odd and even superlayers
483  double oddLayersSigma=0;
484  double evenLayersSigma=0;
485  for(map<DTWireId, double>::const_iterator wiret0 = theRelativeT0PerWire.begin();
486  wiret0 != theRelativeT0PerWire.end();
487  ++wiret0){
488  if((*wiret0).first.layerId().superlayerId() == (*sl)->id()){
489  if(((*wiret0).first.layerId().layer()) % 2){
490  oddLayersSigma = oddLayersSigma + ((*wiret0).second - oddLayersMean) * ((*wiret0).second - oddLayersMean);
491  }
492  else{
493  evenLayersSigma = evenLayersSigma + ((*wiret0).second - evenLayersMean) * ((*wiret0).second - evenLayersMean);
494  }
495  }
496  }
497  oddLayersSigma = oddLayersSigma/oddLayersDen;
498  evenLayersSigma = evenLayersSigma/evenLayersDen;
499  oddLayersSigma = sqrt(oddLayersSigma);
500  evenLayersSigma = sqrt(evenLayersSigma);
501 
502  if(debug && oddLayersMean)
503  cout<<"[DTT0CalibrationNew] Relative T0 sigma for odd layers "<<oddLayersSigma<<" even layers"<<evenLayersSigma<<endl;
504 
505  //Recompute the mean for odd and even superlayers discarding fluctations
506  double oddLayersFinalMean=0;
507  double evenLayersFinalMean=0;
508  for(map<DTWireId, double>::const_iterator wiret0 = theRelativeT0PerWire.begin();
509  wiret0 != theRelativeT0PerWire.end();
510  ++wiret0){
511  if((*wiret0).first.layerId().superlayerId() == (*sl)->id()){
512  if(((*wiret0).first.layerId().layer()) % 2){
513  if(abs((*wiret0).second - oddLayersMean) < (2*oddLayersSigma))
514  oddLayersFinalMean = oddLayersFinalMean + (*wiret0).second;
515  }
516  else{
517  if(abs((*wiret0).second - evenLayersMean) < (2*evenLayersSigma))
518  evenLayersFinalMean = evenLayersFinalMean + (*wiret0).second;
519  }
520  }
521  }
522  oddLayersFinalMean = oddLayersFinalMean/oddLayersDen;
523  evenLayersFinalMean = evenLayersFinalMean/evenLayersDen;
524  if(debug && oddLayersMean)
525  cout<<"[DTT0CalibrationNew] Final relative T0 mean for odd layers "<<oddLayersFinalMean<<" even layers"<<evenLayersFinalMean<<endl;
526 
527  for(map<DTWireId, double>::const_iterator wiret0 = theRelativeT0PerWire.begin();
528  wiret0 != theRelativeT0PerWire.end();
529  ++wiret0){
530  if((*wiret0).first.layerId().superlayerId() == (*sl)->id()){
531  double t0=-999;
532  if(((*wiret0).first.layerId().layer()) % 2)
533  t0 = (*wiret0).second + (evenLayersFinalMean - oddLayersFinalMean);
534  else
535  t0 = (*wiret0).second;
536 
537  cout<<"[DTT0CalibrationNew] Wire "<<(*wiret0).first<<" has t0 "<<(*wiret0).second<<" (relative, after even-odd layer corrections) "
538  <<" sigma "<<theSigmaT0PerWire[(*wiret0).first]<<endl;
539  //Store the results into DB
540  t0s->set((*wiret0).first, t0, theSigmaT0PerWire[(*wiret0).first],DTTimeUnits::counts);
541  }
542  }
543  }
544 
546  if(debug)
547  cout << "[DTT0CalibrationNew]Computing relative t0 wrt to chamber average" << endl;
548  //Compute the reference for each chamber
549  map<DTChamberId,double> sumT0ByChamber;
550  map<DTChamberId,int> countT0ByChamber;
551  for(DTT0::const_iterator tzero = t0s->begin();
552  tzero != t0s->end(); ++tzero) {
553 // @@@ NEW DTT0 FORMAT
554 // DTChamberId chamberId((*tzero).first.wheelId,
555 // (*tzero).first.stationId,
556 // (*tzero).first.sectorId);
557 // sumT0ByChamber[chamberId] = sumT0ByChamber[chamberId] + (*tzero).second.t0mean;
558  int channelId = tzero->channelId;
559  if ( channelId == 0 ) continue;
560  DTWireId wireId(channelId);
561  DTChamberId chamberId(wireId.chamberId());
562  //sumT0ByChamber[chamberId] = sumT0ByChamber[chamberId] + tzero->t0mean;
563 // @@@ better DTT0 usage
564  float t0mean_f;
565  float t0rms_f;
566  t0s->get(wireId,t0mean_f,t0rms_f,DTTimeUnits::counts);
567  sumT0ByChamber[chamberId] = sumT0ByChamber[chamberId] + t0mean_f;
568 // @@@ NEW DTT0 END
569  countT0ByChamber[chamberId]++;
570  }
571 
572  //Change reference for each wire and store the new t0s in the new map
573  for(DTT0::const_iterator tzero = t0s->begin();
574  tzero != t0s->end(); ++tzero) {
575 // @@@ NEW DTT0 FORMAT
576 // DTChamberId chamberId((*tzero).first.wheelId,
577 // (*tzero).first.stationId,
578 // (*tzero).first.sectorId);
579 // double t0mean = ((*tzero).second.t0mean) - (sumT0ByChamber[chamberId]/countT0ByChamber[chamberId]);
580 // double t0rms = (*tzero).second.t0rms;
581 // DTWireId wireId((*tzero).first.wheelId,
582 // (*tzero).first.stationId,
583 // (*tzero).first.sectorId,
584 // (*tzero).first.slId,
585 // (*tzero).first.layerId,
586 // (*tzero).first.cellId);
587  int channelId = tzero->channelId;
588  if ( channelId == 0 ) continue;
589  DTWireId wireId( channelId );
590  DTChamberId chamberId(wireId.chamberId());
591  //double t0mean = (tzero->t0mean) - (sumT0ByChamber[chamberId]/countT0ByChamber[chamberId]);
592  //double t0rms = tzero->t0rms;
593 // @@@ better DTT0 usage
594  float t0mean_f;
595  float t0rms_f;
596  t0s->get(wireId,t0mean_f,t0rms_f,DTTimeUnits::counts);
597  double t0mean = t0mean_f - (sumT0ByChamber[chamberId]/countT0ByChamber[chamberId]);
598  double t0rms = t0rms_f;
599 // @@@ NEW DTT0 END
600  t0sWRTChamber->set(wireId,
601  t0mean,
602  t0rms,
604  if(debug){
605  //cout<<"Chamber "<<chamberId<<" has reference "<<(sumT0ByChamber[chamberId]/countT0ByChamber[chamberId]);
606 // cout<<"Changing t0 of wire "<<wireId<<" from "<<(*tzero).second.t0mean<<" to "<<t0mean<<endl;
607  cout<<"Changing t0 of wire "<<wireId<<" from "<<tzero->t0mean<<" to "<<t0mean<<endl;
608  }
609  }
610 
612  if(debug)
613  cout << "[DTT0CalibrationNew]Writing values in DB!" << endl;
614  // FIXME: to be read from cfg?
615  string t0Record = "DTT0Rcd";
616  // Write the t0 map to DB
617  DTCalibDBUtils::writeToDB(t0Record, t0sWRTChamber);
618 }
619 
620 string DTT0CalibrationNew::getHistoName(const DTWireId& wId) const {
621  string histoName;
622  stringstream theStream;
623  theStream << "Ch_" << wId.wheel() << "_" << wId.station() << "_" << wId.sector()
624  << "_SL" << wId.superlayer() << "_L" << wId.layer() << "_W"<< wId.wire() <<"_hT0Histo";
625  theStream >> histoName;
626  return histoName;
627 }
628 
629 string DTT0CalibrationNew::getHistoName(const DTLayerId& lId) const {
630  string histoName;
631  stringstream theStream;
632  theStream << "Ch_" << lId.wheel() << "_" << lId.station() << "_" << lId.sector()
633  << "_SL" << lId.superlayer() << "_L" << lId.layer() <<"_hT0Histo";
634  theStream >> histoName;
635  return histoName;
636 }
637 
const_iterator begin() const
Definition: DTT0.cc:204
RunNumber_t run() const
Definition: EventID.h:39
int set(int wheelId, int stationId, int sectorId, int slId, int layerId, int cellId, float t0mean, float t0rms, DTTimeUnits::type unit)
Definition: DTT0.cc:140
T getParameter(std::string const &) const
EventNumber_t event() const
Definition: EventID.h:41
T getUntrackedParameter(std::string const &, T const &) const
DTChamberId chamberId() const
Return the corresponding ChamberId.
void endJob()
Compute the mean and the RMS of the t0 from the maps and write them to the DB with channel granularit...
int layer() const
Return the layer number.
Definition: DTLayerId.h:53
DTSuperLayerId superlayerId() const
Return the corresponding SuperLayerId.
Definition: DTLayerId.h:59
void find(edm::Handle< EcalRecHitCollection > &hits, DetId thisDet, std::vector< EcalRecHitCollection::const_iterator > &hit, bool debug=false)
Definition: FindCaloHit.cc:7
int get(int wheelId, int stationId, int sectorId, int slId, int layerId, int cellId, float &t0mean, float &t0rms, DTTimeUnits::type unit) const
Definition: DTT0.cc:67
std::vector< DTT0Data >::const_iterator const_iterator
Access methods to data.
Definition: DTT0.h:140
virtual ~DTT0CalibrationNew()
Destructor.
Definition: DTT0.h:53
T sqrt(T t)
Definition: SSEVec.h:18
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
How EventSelector::AcceptEvent() decides whether to accept an event for output otherwise it is excluding the probing of A single or multiple positive and the trigger will pass if any such matching triggers are PASS or EXCEPTION[A criterion thatmatches no triggers at all is detected and causes a throw.] A single negative with an expectation of appropriate bit checking in the decision and the trigger will pass if any such matching triggers are FAIL or EXCEPTION A wildcarded negative criterion that matches more than one trigger in the trigger but the state exists so we define the behavior If all triggers are the negative crieriion will lead to accepting the event(this again matches the behavior of"!*"before the partial wildcard feature was incorporated).The per-event"cost"of each negative criterion with multiple relevant triggers is about the same as!*was in the past
int wire() const
Return the wire number.
Definition: DTWireId.h:56
const_iterator end() const
Definition: DTT0.cc:209
int superlayer() const
Return the superlayer number (deprecated method name)
#define debug
Definition: HDRShower.cc:19
DTT0CalibrationNew(const edm::ParameterSet &pset)
Constructor.
const T & get() const
Definition: EventSetup.h:56
std::vector< DTDigi >::const_iterator const_iterator
edm::EventID id() const
Definition: EventBase.h:58
int sector() const
Definition: DTChamberId.h:61
void analyze(const edm::Event &event, const edm::EventSetup &eventSetup)
Fill the maps with t0 (by channel)
static const double tzero[3]
std::pair< const_iterator, const_iterator > Range
tuple cout
Definition: gather_cfg.py:145
std::string getHistoName(const DTWireId &wId) const
int station() const
Return the station number.
Definition: DTChamberId.h:51
int wheel() const
Return the wheel number.
Definition: DTChamberId.h:45
static void writeToDB(std::string record, T *payload)