CMS 3D CMS Logo

CSCValidation.cc
Go to the documentation of this file.
1 /*
2  * validation package for CSC DIGIs, RECHITs and SEGMENTs + more.
3  *
4  * original authors:
5  * Michael Schmitt (Northwestern University)
6  * Andy Kubik (Northwestern University)
7  *
8  * CONTACT: CSC DPG (Jul-2022)
9  *
10  */
11 
12 // UPDATED AND RUNNING IN 12_x 15.07.2022 TIM COX - includes updates from external version
13 
15 
16 using namespace std;
17 using namespace edm;
18 
20 // CONSTRUCTOR //
22 CSCValidation::CSCValidation(const ParameterSet& pset) {
23  // Get the various input parameters
24  rootFileName = pset.getUntrackedParameter<std::string>("rootFileName", "valHists.root");
25  isSimulation = pset.getUntrackedParameter<bool>("isSimulation", false);
26  writeTreeToFile = pset.getUntrackedParameter<bool>("writeTreeToFile", true);
27  detailedAnalysis = pset.getUntrackedParameter<bool>("detailedAnalysis", false);
28  useDigis = pset.getUntrackedParameter<bool>("useDigis", true);
29 
30  // event quality filter
31  useQualityFilter = pset.getUntrackedParameter<bool>("useQualityFilter", false);
32  pMin = pset.getUntrackedParameter<double>("pMin", 4.);
33  chisqMax = pset.getUntrackedParameter<double>("chisqMax", 20.);
34  nCSCHitsMin = pset.getUntrackedParameter<int>("nCSCHitsMin", 10);
35  nCSCHitsMax = pset.getUntrackedParameter<int>("nCSCHitsMax", 25);
36  lengthMin = pset.getUntrackedParameter<double>("lengthMin", 140.);
37  lengthMax = pset.getUntrackedParameter<double>("lengthMax", 600.);
38  deltaPhiMax = pset.getUntrackedParameter<double>("deltaPhiMax", 0.2);
39  polarMax = pset.getUntrackedParameter<double>("polarMax", 0.7);
40  polarMin = pset.getUntrackedParameter<double>("polarMin", 0.3);
41 
42  // trigger filter
43  useTriggerFilter = pset.getUntrackedParameter<bool>("useTriggerFilter", false);
44 
45  // input tags for collections
46  rd_token = consumes<FEDRawDataCollection>(pset.getParameter<edm::InputTag>("rawDataTag"));
47  sd_token = consumes<CSCStripDigiCollection>(pset.getParameter<edm::InputTag>("stripDigiTag"));
48  wd_token = consumes<CSCWireDigiCollection>(pset.getParameter<edm::InputTag>("wireDigiTag"));
49  cd_token = consumes<CSCComparatorDigiCollection>(pset.getParameter<edm::InputTag>("compDigiTag"));
50  al_token = consumes<CSCALCTDigiCollection>(pset.getParameter<edm::InputTag>("alctDigiTag"));
51  cl_token = consumes<CSCCLCTDigiCollection>(pset.getParameter<edm::InputTag>("clctDigiTag"));
52  co_token = consumes<CSCCorrelatedLCTDigiCollection>(pset.getParameter<edm::InputTag>("corrlctDigiTag"));
53  rh_token = consumes<CSCRecHit2DCollection>(pset.getParameter<edm::InputTag>("cscRecHitTag"));
54  se_token = consumes<CSCSegmentCollection>(pset.getParameter<edm::InputTag>("cscSegTag"));
55  sa_token = consumes<reco::TrackCollection>(pset.getParameter<edm::InputTag>("saMuonTag"));
56  l1_token = consumes<L1MuGMTReadoutCollection>(pset.getParameter<edm::InputTag>("l1aTag"));
57  tr_token = consumes<TriggerResults>(pset.getParameter<edm::InputTag>("hltTag"));
58  sh_token = consumes<PSimHitContainer>(pset.getParameter<edm::InputTag>("simHitTag"));
59  // conditions
60  pedestalsToken_ = esConsumes<CSCDBPedestals, CSCDBPedestalsRcd>();
61  gainsToken_ = esConsumes<CSCDBGains, CSCDBGainsRcd>();
62  noiseToken_ = esConsumes<CSCDBNoiseMatrix, CSCDBNoiseMatrixRcd>();
63  crosstalkToken_ = esConsumes<CSCDBCrosstalk, CSCDBCrosstalkRcd>();
64 
65  crateToken_ = esConsumes<CSCCrateMap, CSCCrateMapRcd>();
66 
67  // flags to switch on/off individual modules
68  makeOccupancyPlots = pset.getUntrackedParameter<bool>("makeOccupancyPlots", true);
69  makeTriggerPlots = pset.getUntrackedParameter<bool>("makeTriggerPlots", false);
70  makeStripPlots = pset.getUntrackedParameter<bool>("makeStripPlots", true);
71  makeWirePlots = pset.getUntrackedParameter<bool>("makeWirePlots", true);
72  makeRecHitPlots = pset.getUntrackedParameter<bool>("makeRecHitPlots", true);
73  makeSimHitPlots = pset.getUntrackedParameter<bool>("makeSimHitPlots", true);
74  makeSegmentPlots = pset.getUntrackedParameter<bool>("makeSegmentPlots", true);
75  makeResolutionPlots = pset.getUntrackedParameter<bool>("makeResolutionPlots", true);
76  makePedNoisePlots = pset.getUntrackedParameter<bool>("makePedNoisePlots", true);
77  makeEfficiencyPlots = pset.getUntrackedParameter<bool>("makeEfficiencyPlots", true);
78  makeGasGainPlots = pset.getUntrackedParameter<bool>("makeGasGainPlots", true);
79  makeAFEBTimingPlots = pset.getUntrackedParameter<bool>("makeAFEBTimingPlots", true);
80  makeCompTimingPlots = pset.getUntrackedParameter<bool>("makeCompTimingPlots", true);
81  makeADCTimingPlots = pset.getUntrackedParameter<bool>("makeADCTimingPlots", true);
82  makeRHNoisePlots = pset.getUntrackedParameter<bool>("makeRHNoisePlots", false);
83  makeCalibPlots = pset.getUntrackedParameter<bool>("makeCalibPlots", false);
84  makeStandalonePlots = pset.getUntrackedParameter<bool>("makeStandalonePlots", false);
85  makeTimeMonitorPlots = pset.getUntrackedParameter<bool>("makeTimeMonitorPlots", false);
86  makeHLTPlots = pset.getUntrackedParameter<bool>("makeHLTPlots", false);
87 
88  // set counters to zero
89  nEventsAnalyzed = 0;
90  rhTreeCount = 0;
91  segTreeCount = 0;
92  firstEvent = true;
93 
94  // Create the root file for the histograms
95  theFile = new TFile(rootFileName.c_str(), "RECREATE");
96  theFile->cd();
97 
98  // Create object of class CSCValHists to manage histograms
99  histos = new CSCValHists();
100 
101  // book Occupancy Histos
102  hOWires = new TH2I("hOWires", "Wire Digi Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
103  hOStrips = new TH2I("hOStrips", "Strip Digi Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
104  hORecHits = new TH2I("hORecHits", "RecHit Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
105  hOSegments = new TH2I("hOSegments", "Segments Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
106 
107  // book Eff histos
108  hSSTE = new TH1F("hSSTE", "hSSTE", 40, 0, 40);
109  hRHSTE = new TH1F("hRHSTE", "hRHSTE", 40, 0, 40);
110  hSEff = new TH1F("hSEff", "Segment Efficiency", 20, 0.5, 20.5);
111  hRHEff = new TH1F("hRHEff", "recHit Efficiency", 20, 0.5, 20.5);
112 
113  const int nChambers = 36;
114  const int nTypes = 20;
115  float nCH_min = 0.5;
116  float nCh_max = float(nChambers) + 0.5;
117  float nT_min = 0.5;
118  float nT_max = float(nTypes) + 0.5;
119 
120  hSSTE2 = new TH2F("hSSTE2", "hSSTE2", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
121  hRHSTE2 = new TH2F("hRHSTE2", "hRHSTE2", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
122  hStripSTE2 = new TH2F("hStripSTE2", "hStripSTE2", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
123  hWireSTE2 = new TH2F("hWireSTE2", "hWireSTE2", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
124 
125  hEffDenominator = new TH2F("hEffDenominator", "hEffDenominator", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
126  hSEff2 = new TH2F("hSEff2", "Segment Efficiency 2D", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
127  hRHEff2 = new TH2F("hRHEff2", "recHit Efficiency 2D", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
128 
129  hStripEff2 = new TH2F("hStripEff2", "strip Efficiency 2D", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
130  hWireEff2 = new TH2F("hWireEff2", "wire Efficiency 2D", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
131 
132  hSensitiveAreaEvt =
133  new TH2F("hSensitiveAreaEvt", "events in sensitive area", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
134 
135  hSSTETight = new TH1F("hSSTETight", "hSSTE Tight", 40, 0, 40);
136  hRHSTETight = new TH1F("hRHSTETight", "hRHSTE Tight", 40, 0, 40);
137 
138  hSSTE2Tight = new TH2F("hSSTE2Tight", "hSSTE2 Tight", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
139  hRHSTE2Tight = new TH2F("hRHSTE2Tight", "hRHSTE2 Tight", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
140  hStripSTE2Tight =
141  new TH2F("hStripSTE2Tight", "hStripSTE2 Tight", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
142  hWireSTE2Tight = new TH2F("hWireSTE2Tight", "hWireSTE2 Tight", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
143  hEffDenominatorTight =
144  new TH2F("hEffDenominatorTight", "hEffDenominator Tight", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
145 
146  // setup trees to hold global position data for rechits and segments
147  if (writeTreeToFile)
148  histos->setupTrees();
149 
150  geomToken_ = esConsumes<CSCGeometry, MuonGeometryRecord>();
151 }
152 
154 // DESTRUCTOR //
156 CSCValidation::~CSCValidation() {
157  // produce final efficiency histograms
158  histoEfficiency(hRHSTE, hRHEff);
159  histoEfficiency(hSSTE, hSEff);
160  hSEff2->Divide(hSSTE2, hEffDenominator, 1., 1., "B");
161  hRHEff2->Divide(hRHSTE2, hEffDenominator, 1., 1., "B");
162  hStripEff2->Divide(hStripSTE2, hEffDenominator, 1., 1., "B");
163  hWireEff2->Divide(hWireSTE2, hEffDenominator, 1., 1., "B");
164 
165  histos->insertPlot(hRHSTETight, "hRHSTETight", "Efficiency");
166  histos->insertPlot(hSSTETight, "hSSTETight", "Efficiency");
167  histos->insertPlot(hStripSTE2Tight, "hStripSTE2Tight", "Efficiency");
168  histos->insertPlot(hWireSTE2Tight, "hWireSTE2Tight", "Efficiency");
169  histos->insertPlot(hRHSTE2Tight, "hRHSTE2Tight", "Efficiency");
170  histos->insertPlot(hSSTE2Tight, "hSSTE2Tight", "Efficiency");
171  histos->insertPlot(hEffDenominatorTight, "hEffDenominatorTight", "Efficiency");
172 
173  histos->insertPlot(hRHSTE, "hRHSTE", "Efficiency");
174  histos->insertPlot(hSSTE, "hSSTE", "Efficiency");
175  histos->insertPlot(hSSTE2, "hSSTE2", "Efficiency");
176  histos->insertPlot(hEffDenominator, "hEffDenominator", "Efficiency");
177  histos->insertPlot(hRHSTE2, "hRHSTE2", "Efficiency");
178  histos->insertPlot(hStripSTE2, "hStripSTE2", "Efficiency");
179  histos->insertPlot(hWireSTE2, "hWireSTE2", "Efficiency");
180 
181  //moving this to post job macros
182  histos->insertPlot(hSEff, "hSEff", "Efficiency");
183  histos->insertPlot(hRHEff, "hRHEff", "Efficiency");
184 
185  histos->insertPlot(hSEff2, "hSEff2", "Efficiency");
186  histos->insertPlot(hRHEff2, "hRHEff2", "Efficiency");
187  histos->insertPlot(hStripEff2, "hStripff2", "Efficiency");
188  histos->insertPlot(hWireEff2, "hWireff2", "Efficiency");
189 
190  histos->insertPlot(hSensitiveAreaEvt, "", "Efficiency");
191 
192  // throw in occupancy plots so they're saved
193  histos->insertPlot(hOWires, "hOWires", "Digis");
194  histos->insertPlot(hOStrips, "hOStrips", "Digis");
195  histos->insertPlot(hORecHits, "hORecHits", "recHits");
196  histos->insertPlot(hOSegments, "hOSegments", "Segments");
197 
198  // write histos to the specified file
199  histos->writeHists(theFile);
200  if (writeTreeToFile)
201  histos->writeTrees(theFile);
202  theFile->Close();
203 }
204 
206 // Analysis //
209  // increment counter
210  nEventsAnalyzed++;
211 
212  //int iRun = event.id().run();
213  //int iEvent = event.id().event();
214 
215  // Get the Digis
222  if (useDigis) {
223  event.getByToken(sd_token, strips);
224  event.getByToken(wd_token, wires);
225  event.getByToken(cd_token, compars);
226  event.getByToken(al_token, alcts);
227  event.getByToken(cl_token, clcts);
228  event.getByToken(co_token, correlatedlcts);
229  }
230 
231  // Get the CSC Geometry :
232  edm::ESHandle<CSCGeometry> cscGeom = eventSetup.getHandle(geomToken_);
233 
234  // Get the RecHits collection :
236  event.getByToken(rh_token, recHits);
237 
238  //CSCRecHit2DCollection::const_iterator recIt;
239  //for (recIt = recHits->begin(); recIt != recHits->end(); recIt++) {
240  // recIt->print();
241  // }
242 
243  // Get the SimHits (if applicable)
245  if (isSimulation)
246  event.getByToken(sh_token, simHits);
247 
248  // get CSC segment collection
250  event.getByToken(se_token, cscSegments);
251 
252  // get the trigger collection
254  if (makeTriggerPlots || useTriggerFilter || (useDigis && makeTimeMonitorPlots)) {
255  event.getByToken(l1_token, pCollection);
256  }
258  if (makeHLTPlots) {
259  event.getByToken(tr_token, hlt);
260  }
261 
262  // get the standalone muon collection
264  if (makeStandalonePlots || useQualityFilter) {
265  event.getByToken(sa_token, saMuons);
266  }
267 
269  // Run the modules //
271 
272  // Only do this for the first event
273  // this is probably outdated and needs to be looked at
274  if (nEventsAnalyzed == 1 && makeCalibPlots)
275  doCalibrations(eventSetup);
276 
277  // Look at the l1a trigger info (returns true if csc L1A present)
278  bool CSCL1A = false;
279  if (makeTriggerPlots || useTriggerFilter)
280  CSCL1A = doTrigger(pCollection);
281  if (!useTriggerFilter)
282  CSCL1A = true; // always true if not filtering on trigger
283 
284  cleanEvent = false;
285  if (makeStandalonePlots || useQualityFilter)
286  cleanEvent = filterEvents(recHits, cscSegments, saMuons);
287  if (!useQualityFilter)
288  cleanEvent = true; // always true if not filtering on event quality
289 
290  // look at various chamber occupancies
291  // keep this outside of filter for diagnostics???
292  if (makeOccupancyPlots && CSCL1A)
293  doOccupancies(strips, wires, recHits, cscSegments);
294 
295  if (makeHLTPlots)
296  doHLT(hlt);
297 
298  if (cleanEvent && CSCL1A) {
299  // general look at strip digis
300  if (makeStripPlots && useDigis)
301  doStripDigis(strips);
302 
303  // general look at wire digis
304  if (makeWirePlots && useDigis)
305  doWireDigis(wires);
306 
307  // general look at rechits
308  if (makeRecHitPlots)
309  doRecHits(recHits, cscGeom);
310 
311  // look at simHits
312  if (isSimulation && makeSimHitPlots)
314 
315  // general look at Segments
316  if (makeSegmentPlots)
317  doSegments(cscSegments, cscGeom);
318 
319  // look at hit resolution
320  if (makeResolutionPlots)
321  doResolution(cscSegments, cscGeom);
322 
323  // look at Pedestal Noise
324  if (makePedNoisePlots && useDigis)
325  doPedestalNoise(strips);
326 
327  // look at recHit and segment efficiencies
328  if (makeEfficiencyPlots)
329  doEfficiencies(wires, strips, recHits, cscSegments, cscGeom);
330 
331  // gas gain
332  if (makeGasGainPlots && useDigis)
333  doGasGain(*wires, *strips, *recHits);
334 
335  // AFEB timing
336  if (makeAFEBTimingPlots && useDigis)
337  doAFEBTiming(*wires);
338 
339  // Comparators timing
340  if (makeCompTimingPlots && useDigis)
341  doCompTiming(*compars);
342 
343  // strip ADC timing
344  if (makeADCTimingPlots)
345  doADCTiming(*recHits);
346 
347  // recHit Noise
348  if (makeRHNoisePlots && useDigis)
349  doNoiseHits(recHits, cscSegments, cscGeom, strips);
350 
351  // look at standalone muons (not implemented yet)
352  if (makeStandalonePlots)
353  doStandalone(saMuons);
354 
355  // make plots for monitoring the trigger and offline timing
356  if (makeTimeMonitorPlots)
357  doTimeMonitoring(recHits, cscSegments, alcts, clcts, correlatedlcts, pCollection, cscGeom, eventSetup, event);
358 
359  firstEvent = false;
360  }
361 }
362 
363 // ==============================================
364 //
365 // event filter, returns true only for events with "good" standalone muon
366 //
367 // ==============================================
368 
369 bool CSCValidation::filterEvents(edm::Handle<CSCRecHit2DCollection> recHits,
372  //int nGoodSAMuons = 0;
373 
374  if (recHits->size() < 4 || recHits->size() > 100)
375  return false;
376  if (cscSegments->size() < 1 || cscSegments->size() > 15)
377  return false;
378  return true;
379  //if (saMuons->size() != 1) return false;
380  /*
381  for(reco::TrackCollection::const_iterator muon = saMuons->begin(); muon != saMuons->end(); ++ muon ) {
382  double p = muon->p();
383  double reducedChisq = muon->normalizedChi2();
384 
385  GlobalPoint innerPnt(muon->innerPosition().x(),muon->innerPosition().y(),muon->innerPosition().z());
386  GlobalPoint outerPnt(muon->outerPosition().x(),muon->outerPosition().y(),muon->outerPosition().z());
387  GlobalVector innerKin(muon->innerMomentum().x(),muon->innerMomentum().y(),muon->innerMomentum().z());
388  GlobalVector outerKin(muon->outerMomentum().x(),muon->outerMomentum().y(),muon->outerMomentum().z());
389  GlobalVector deltaPnt = innerPnt - outerPnt;
390  double crudeLength = deltaPnt.mag();
391  double deltaPhi = innerPnt.phi() - outerPnt.phi();
392  double innerGlobalPolarAngle = innerKin.theta();
393  double outerGlobalPolarAngle = outerKin.theta();
394 
395  int nCSCHits = 0;
396  for (trackingRecHit_iterator hit = muon->recHitsBegin(); hit != muon->recHitsEnd(); ++hit ) {
397  if ( (*hit)->isValid() ) {
398  const DetId detId( (*hit)->geographicalId() );
399  if (detId.det() == DetId::Muon) {
400  if (detId.subdetId() == MuonSubdetId::CSC) {
401  nCSCHits++;
402  } // this is a CSC hit
403  } // this is a muon hit
404  } // hit is valid
405  } // end loop over rechits
406 
407  bool goodSAMuon = (p > pMin)
408  && ( reducedChisq < chisqMax )
409  && ( nCSCHits >= nCSCHitsMin )
410  && ( nCSCHits <= nCSCHitsMax )
411  && ( crudeLength > lengthMin )
412  && ( crudeLength < lengthMax );
413 
414 
415  goodSAMuon = goodSAMuon && ( fabs(deltaPhi) < deltaPhiMax );
416  goodSAMuon = goodSAMuon &&
417  (
418  ( ( innerGlobalPolarAngle > polarMin) && ( innerGlobalPolarAngle < polarMax) ) ||
419  ( (M_PI-innerGlobalPolarAngle > polarMin) && (M_PI-innerGlobalPolarAngle < polarMax) )
420  );
421  goodSAMuon = goodSAMuon &&
422  (
423  ( ( outerGlobalPolarAngle > polarMin) && ( outerGlobalPolarAngle < polarMax) ) ||
424  ( (M_PI-outerGlobalPolarAngle > polarMin) && (M_PI-outerGlobalPolarAngle < polarMax) )
425  );
426 
427  //goodSAMuon = goodSAMuon && (nCSCHits > nCSCHitsMin) && (nCSCHits < 13);
428  //goodSAMuon = goodSAMuon && (nCSCHits > 13) && (nCSCHits < 19);
429  //goodSAMuon = goodSAMuon && (nCSCHits > 19) && (nCSCHits < nCSCHitsMax);
430 
431 
432  if (goodSAMuon) nGoodSAMuons++;
433 
434  } // end loop over stand-alone muon collection
435 
436 
437  histos->fill1DHist(nGoodSAMuons,"hNGoodMuons", "Number of Good STA Muons per Event",11,-0.5,10.5,"STAMuons");
438 
439  if (nGoodSAMuons == 1) return true;
440  return false;
441  */
442 }
443 
444 // ==============================================
445 //
446 // look at Occupancies
447 //
448 // ==============================================
449 
450 void CSCValidation::doOccupancies(edm::Handle<CSCStripDigiCollection> strips,
454  bool wireo[2][4][4][36];
455  bool stripo[2][4][4][36];
456  bool rechito[2][4][4][36];
457  bool segmento[2][4][4][36];
458 
459  bool hasWires = false;
460  bool hasStrips = false;
461  bool hasRecHits = false;
462  bool hasSegments = false;
463 
464  for (int e = 0; e < 2; e++) {
465  for (int s = 0; s < 4; s++) {
466  for (int r = 0; r < 4; r++) {
467  for (int c = 0; c < 36; c++) {
468  wireo[e][s][r][c] = false;
469  stripo[e][s][r][c] = false;
470  rechito[e][s][r][c] = false;
471  segmento[e][s][r][c] = false;
472  }
473  }
474  }
475  }
476 
477  if (useDigis) {
478  //wires
479  for (CSCWireDigiCollection::DigiRangeIterator wi = wires->begin(); wi != wires->end(); wi++) {
480  CSCDetId id = (CSCDetId)(*wi).first;
481  int kEndcap = id.endcap();
482  int kRing = id.ring();
483  int kStation = id.station();
484  int kChamber = id.chamber();
485  std::vector<CSCWireDigi>::const_iterator wireIt = (*wi).second.first;
486  std::vector<CSCWireDigi>::const_iterator lastWire = (*wi).second.second;
487  for (; wireIt != lastWire; ++wireIt) {
488  if (!wireo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
489  wireo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
490  hOWires->Fill(kChamber, typeIndex(id));
491  histos->fill1DHist(
492  chamberSerial(id), "hOWireSerial", "Wire Occupancy by Chamber Serial", 601, -0.5, 600.5, "Digis");
493  hasWires = true;
494  }
495  }
496  }
497 
498  //strips
499  for (CSCStripDigiCollection::DigiRangeIterator si = strips->begin(); si != strips->end(); si++) {
500  CSCDetId id = (CSCDetId)(*si).first;
501  int kEndcap = id.endcap();
502  int kRing = id.ring();
503  int kStation = id.station();
504  int kChamber = id.chamber();
505  std::vector<CSCStripDigi>::const_iterator stripIt = (*si).second.first;
506  std::vector<CSCStripDigi>::const_iterator lastStrip = (*si).second.second;
507  for (; stripIt != lastStrip; ++stripIt) {
508  std::vector<int> myADCVals = stripIt->getADCCounts();
509  bool thisStripFired = false;
510  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
511  float threshold = 13.3;
512  float diff = 0.;
513  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
514  diff = (float)myADCVals[iCount] - thisPedestal;
515  if (diff > threshold) {
516  thisStripFired = true;
517  }
518  }
519  if (thisStripFired) {
520  if (!stripo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
521  stripo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
522  hOStrips->Fill(kChamber, typeIndex(id));
523  histos->fill1DHist(
524  chamberSerial(id), "hOStripSerial", "Strip Occupancy by Chamber Serial", 601, -0.5, 600.5, "Digis");
525  hasStrips = true;
526  }
527  }
528  }
529  }
530  }
531 
532  //rechits
534  for (recIt = recHits->begin(); recIt != recHits->end(); recIt++) {
535  CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
536  int kEndcap = idrec.endcap();
537  int kRing = idrec.ring();
538  int kStation = idrec.station();
539  int kChamber = idrec.chamber();
540  if (!rechito[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
541  rechito[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
542  histos->fill1DHist(
543  chamberSerial(idrec), "hORecHitsSerial", "RecHit Occupancy by Chamber Serial", 601, -0.5, 600.5, "recHits");
544  hORecHits->Fill(kChamber, typeIndex(idrec));
545  hasRecHits = true;
546  }
547  }
548 
549  //segments
550  for (CSCSegmentCollection::const_iterator segIt = cscSegments->begin(); segIt != cscSegments->end(); segIt++) {
551  CSCDetId id = (CSCDetId)(*segIt).cscDetId();
552  int kEndcap = id.endcap();
553  int kRing = id.ring();
554  int kStation = id.station();
555  int kChamber = id.chamber();
556  if (!segmento[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
557  segmento[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
558  histos->fill1DHist(
559  chamberSerial(id), "hOSegmentsSerial", "Segment Occupancy by Chamber Serial", 601, -0.5, 600.5, "Segments");
560  hOSegments->Fill(kChamber, typeIndex(id));
561  hasSegments = true;
562  }
563  }
564 
565  // overall CSC occupancy (events with CSC data compared to total)
566  histos->fill1DHist(1, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
567  if (hasWires)
568  histos->fill1DHist(3, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
569  if (hasStrips)
570  histos->fill1DHist(5, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
571  if (hasWires && hasStrips)
572  histos->fill1DHist(7, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
573  if (hasRecHits)
574  histos->fill1DHist(9, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
575  if (hasSegments)
576  histos->fill1DHist(11, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
577  if (!cleanEvent)
578  histos->fill1DHist(13, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
579 }
580 
581 // ==============================================
582 //
583 // look at Trigger info
584 //
585 // ==============================================
586 
587 bool CSCValidation::doTrigger(edm::Handle<L1MuGMTReadoutCollection> pCollection) {
588  std::vector<L1MuGMTReadoutRecord> L1Mrec = pCollection->getRecords();
589  std::vector<L1MuGMTReadoutRecord>::const_iterator igmtrr;
590 
591  bool csc_l1a = false;
592  bool dt_l1a = false;
593  bool rpcf_l1a = false;
594  bool rpcb_l1a = false;
595  bool beamHaloTrigger = false;
596 
597  int myBXNumber = -1000;
598 
599  for (igmtrr = L1Mrec.begin(); igmtrr != L1Mrec.end(); igmtrr++) {
600  std::vector<L1MuRegionalCand>::const_iterator iter1;
601  std::vector<L1MuRegionalCand> rmc;
602 
603  // CSC
604  int icsc = 0;
605  rmc = igmtrr->getCSCCands();
606  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
607  if (!(*iter1).empty()) {
608  icsc++;
609  int kQuality = (*iter1).quality(); // kQuality = 1 means beam halo
610  if (kQuality == 1)
611  beamHaloTrigger = true;
612  }
613  }
614  if (igmtrr->getBxInEvent() == 0 && icsc > 0)
615  csc_l1a = true;
616  if (igmtrr->getBxInEvent() == 0) {
617  myBXNumber = igmtrr->getBxNr();
618  }
619 
620  // DT
621  int idt = 0;
622  rmc = igmtrr->getDTBXCands();
623  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
624  if (!(*iter1).empty()) {
625  idt++;
626  }
627  }
628  if (igmtrr->getBxInEvent() == 0 && idt > 0)
629  dt_l1a = true;
630 
631  // RPC Barrel
632  int irpcb = 0;
633  rmc = igmtrr->getBrlRPCCands();
634  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
635  if (!(*iter1).empty()) {
636  irpcb++;
637  }
638  }
639  if (igmtrr->getBxInEvent() == 0 && irpcb > 0)
640  rpcb_l1a = true;
641 
642  // RPC Forward
643  int irpcf = 0;
644  rmc = igmtrr->getFwdRPCCands();
645  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
646  if (!(*iter1).empty()) {
647  irpcf++;
648  }
649  }
650  if (igmtrr->getBxInEvent() == 0 && irpcf > 0)
651  rpcf_l1a = true;
652  }
653 
654  // Fill some histograms with L1A info
655  if (csc_l1a)
656  histos->fill1DHist(myBXNumber, "vtBXNumber", "BX Number", 4001, -0.5, 4000.5, "Trigger");
657  if (csc_l1a)
658  histos->fill1DHist(1, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
659  if (dt_l1a)
660  histos->fill1DHist(2, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
661  if (rpcb_l1a)
662  histos->fill1DHist(3, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
663  if (rpcf_l1a)
664  histos->fill1DHist(4, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
665  if (beamHaloTrigger)
666  histos->fill1DHist(8, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
667 
668  if (csc_l1a) {
669  histos->fill1DHist(1, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
670  if (dt_l1a)
671  histos->fill1DHist(2, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
672  if (rpcb_l1a)
673  histos->fill1DHist(3, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
674  if (rpcf_l1a)
675  histos->fill1DHist(4, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
676  if (dt_l1a || rpcb_l1a || rpcf_l1a)
677  histos->fill1DHist(5, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
678  if (!(dt_l1a || rpcb_l1a || rpcf_l1a))
679  histos->fill1DHist(6, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
680  } else {
681  histos->fill1DHist(1, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
682  if (dt_l1a)
683  histos->fill1DHist(2, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
684  if (rpcb_l1a)
685  histos->fill1DHist(3, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
686  if (rpcf_l1a)
687  histos->fill1DHist(4, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
688  if (dt_l1a || rpcb_l1a || rpcf_l1a)
689  histos->fill1DHist(5, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
690  if (!(dt_l1a || rpcb_l1a || rpcf_l1a))
691  histos->fill1DHist(6, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
692  }
693 
694  // if valid CSC L1A then return true for possible use elsewhere
695 
696  if (csc_l1a)
697  return true;
698 
699  return false;
700 }
701 
702 // ==============================================
703 //
704 // look at HLT Trigger
705 //
706 // ==============================================
707 
708 bool CSCValidation::doHLT(Handle<TriggerResults> hlt) {
709  // HLT stuff
710  int hltSize = hlt->size();
711  for (int i = 0; i < hltSize; ++i) {
712  if (hlt->accept(i))
713  histos->fill1DHist(i, "hltBits", "HLT Trigger Bits", hltSize + 1, -0.5, (float)hltSize + 0.5, "Trigger");
714  }
715 
716  return true;
717 }
718 
719 // ==============================================
720 //
721 // look at Calibrations
722 //
723 // ==============================================
724 
725 void CSCValidation::doCalibrations(const edm::EventSetup& eventSetup) {
726  // Only do this for the first event
727  if (nEventsAnalyzed == 1) {
728  LogDebug("Calibrations") << "Loading Calibrations...";
729 
730  // get the gains
731  edm::ESHandle<CSCDBGains> hGains = eventSetup.getHandle(gainsToken_);
732  const CSCDBGains* pGains = hGains.product();
733  // get the crosstalks
734  edm::ESHandle<CSCDBCrosstalk> hCrosstalk = eventSetup.getHandle(crosstalkToken_);
735  const CSCDBCrosstalk* pCrosstalk = hCrosstalk.product();
736  // get the noise matrix
737  edm::ESHandle<CSCDBNoiseMatrix> hNoiseMatrix = eventSetup.getHandle(noiseToken_);
738  const CSCDBNoiseMatrix* pNoiseMatrix = hNoiseMatrix.product();
739  // get pedestals
740  edm::ESHandle<CSCDBPedestals> hPedestals = eventSetup.getHandle(pedestalsToken_);
741  const CSCDBPedestals* pPedestals = hPedestals.product();
742 
743  LogDebug("Calibrations") << "Calibrations Loaded!";
744 
745  for (int i = 0; i < 400; i++) {
746  int bin = i + 1;
747  histos->fillCalibHist(pGains->gains[i].gain_slope, "hCalibGainsS", "Gains Slope", 400, 0, 400, bin, "Calib");
748  histos->fillCalibHist(
749  pCrosstalk->crosstalk[i].xtalk_slope_left, "hCalibXtalkSL", "Xtalk Slope Left", 400, 0, 400, bin, "Calib");
750  histos->fillCalibHist(
751  pCrosstalk->crosstalk[i].xtalk_slope_right, "hCalibXtalkSR", "Xtalk Slope Right", 400, 0, 400, bin, "Calib");
752  histos->fillCalibHist(pCrosstalk->crosstalk[i].xtalk_intercept_left,
753  "hCalibXtalkIL",
754  "Xtalk Intercept Left",
755  400,
756  0,
757  400,
758  bin,
759  "Calib");
760  histos->fillCalibHist(pCrosstalk->crosstalk[i].xtalk_intercept_right,
761  "hCalibXtalkIR",
762  "Xtalk Intercept Right",
763  400,
764  0,
765  400,
766  bin,
767  "Calib");
768  histos->fillCalibHist(pPedestals->pedestals[i].ped, "hCalibPedsP", "Peds", 400, 0, 400, bin, "Calib");
769  histos->fillCalibHist(pPedestals->pedestals[i].rms, "hCalibPedsR", "Peds RMS", 400, 0, 400, bin, "Calib");
770  histos->fillCalibHist(
771  pNoiseMatrix->matrix[i].elem33, "hCalibNoise33", "Noise Matrix 33", 400, 0, 400, bin, "Calib");
772  histos->fillCalibHist(
773  pNoiseMatrix->matrix[i].elem34, "hCalibNoise34", "Noise Matrix 34", 400, 0, 400, bin, "Calib");
774  histos->fillCalibHist(
775  pNoiseMatrix->matrix[i].elem35, "hCalibNoise35", "Noise Matrix 35", 400, 0, 400, bin, "Calib");
776  histos->fillCalibHist(
777  pNoiseMatrix->matrix[i].elem44, "hCalibNoise44", "Noise Matrix 44", 400, 0, 400, bin, "Calib");
778  histos->fillCalibHist(
779  pNoiseMatrix->matrix[i].elem45, "hCalibNoise45", "Noise Matrix 45", 400, 0, 400, bin, "Calib");
780  histos->fillCalibHist(
781  pNoiseMatrix->matrix[i].elem46, "hCalibNoise46", "Noise Matrix 46", 400, 0, 400, bin, "Calib");
782  histos->fillCalibHist(
783  pNoiseMatrix->matrix[i].elem55, "hCalibNoise55", "Noise Matrix 55", 400, 0, 400, bin, "Calib");
784  histos->fillCalibHist(
785  pNoiseMatrix->matrix[i].elem56, "hCalibNoise56", "Noise Matrix 56", 400, 0, 400, bin, "Calib");
786  histos->fillCalibHist(
787  pNoiseMatrix->matrix[i].elem57, "hCalibNoise57", "Noise Matrix 57", 400, 0, 400, bin, "Calib");
788  histos->fillCalibHist(
789  pNoiseMatrix->matrix[i].elem66, "hCalibNoise66", "Noise Matrix 66", 400, 0, 400, bin, "Calib");
790  histos->fillCalibHist(
791  pNoiseMatrix->matrix[i].elem67, "hCalibNoise67", "Noise Matrix 67", 400, 0, 400, bin, "Calib");
792  histos->fillCalibHist(
793  pNoiseMatrix->matrix[i].elem77, "hCalibNoise77", "Noise Matrix 77", 400, 0, 400, bin, "Calib");
794  }
795  }
796 }
797 
798 // ==============================================
799 //
800 // look at WIRE DIGIs
801 //
802 // ==============================================
803 
804 void CSCValidation::doWireDigis(edm::Handle<CSCWireDigiCollection> wires) {
805  int nWireGroupsTotal = 0;
806  for (CSCWireDigiCollection::DigiRangeIterator dWDiter = wires->begin(); dWDiter != wires->end(); dWDiter++) {
807  CSCDetId id = (CSCDetId)(*dWDiter).first;
808  std::vector<CSCWireDigi>::const_iterator wireIter = (*dWDiter).second.first;
809  std::vector<CSCWireDigi>::const_iterator lWire = (*dWDiter).second.second;
810  for (; wireIter != lWire; ++wireIter) {
811  int myWire = wireIter->getWireGroup();
812  int myTBin = wireIter->getTimeBin();
813  nWireGroupsTotal++;
814  histos->fill1DHistByType(myWire, "hWireWire", "Wiregroup Numbers Fired", id, 113, -0.5, 112.5, "Digis");
815  histos->fill1DHistByType(myTBin, "hWireTBin", "Wire TimeBin Fired", id, 17, -0.5, 16.5, "Digis");
816  histos->fillProfile(
817  chamberSerial(id), myTBin, "hWireTBinProfile", "Wire TimeBin Fired", 601, -0.5, 600.5, -0.5, 16.5, "Digis");
818  if (detailedAnalysis) {
819  histos->fill1DHistByLayer(
820  myWire, "hWireWire", "Wiregroup Numbers Fired", id, 113, -0.5, 112.5, "WireNumberByLayer");
821  histos->fill1DHistByLayer(myTBin, "hWireTBin", "Wire TimeBin Fired", id, 17, -0.5, 16.5, "WireTimeByLayer");
822  }
823  }
824  } // end wire loop
825 
826  // this way you can zero suppress but still store info on # events with no digis
827  if (nWireGroupsTotal == 0)
828  nWireGroupsTotal = -1;
829 
830  histos->fill1DHist(nWireGroupsTotal, "hWirenGroupsTotal", "Wires Fired Per Event", 251, -0.5, 250.5, "Digis");
831 }
832 
833 // ==============================================
834 //
835 // look at STRIP DIGIs
836 //
837 // ==============================================
838 
839 void CSCValidation::doStripDigis(edm::Handle<CSCStripDigiCollection> strips) {
840  int nStripsFired = 0;
841  for (CSCStripDigiCollection::DigiRangeIterator dSDiter = strips->begin(); dSDiter != strips->end(); dSDiter++) {
842  CSCDetId id = (CSCDetId)(*dSDiter).first;
843  std::vector<CSCStripDigi>::const_iterator stripIter = (*dSDiter).second.first;
844  std::vector<CSCStripDigi>::const_iterator lStrip = (*dSDiter).second.second;
845  for (; stripIter != lStrip; ++stripIter) {
846  int myStrip = stripIter->getStrip();
847  std::vector<int> myADCVals = stripIter->getADCCounts();
848  bool thisStripFired = false;
849  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
850  float threshold = 13.3;
851  float diff = 0.;
852  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
853  diff = (float)myADCVals[iCount] - thisPedestal;
854  if (diff > threshold) {
855  thisStripFired = true;
856  }
857  }
858  if (thisStripFired) {
859  nStripsFired++;
860  // fill strip histos
861  histos->fill1DHistByType(myStrip, "hStripStrip", "Strip Number", id, 81, -0.5, 80.5, "Digis");
862  if (detailedAnalysis) {
863  histos->fill1DHistByLayer(myStrip, "hStripStrip", "Strip Number", id, 81, -0.5, 80.5, "StripNumberByLayer");
864  }
865  }
866  }
867  } // end strip loop
868 
869  if (nStripsFired == 0)
870  nStripsFired = -1;
871 
872  histos->fill1DHist(nStripsFired, "hStripNFired", "Fired Strips per Event", 351, -0.5, 350.5, "Digis");
873 }
874 
875 //=======================================================
876 //
877 // Look at the Pedestal Noise Distributions
878 //
879 //=======================================================
880 
881 void CSCValidation::doPedestalNoise(edm::Handle<CSCStripDigiCollection> strips) {
882  constexpr float threshold = 13.3;
883  for (CSCStripDigiCollection::DigiRangeIterator dPNiter = strips->begin(); dPNiter != strips->end(); dPNiter++) {
884  CSCDetId id = (CSCDetId)(*dPNiter).first;
885  std::vector<CSCStripDigi>::const_iterator pedIt = (*dPNiter).second.first;
886  std::vector<CSCStripDigi>::const_iterator lStrip = (*dPNiter).second.second;
887  for (; pedIt != lStrip; ++pedIt) {
888  int myStrip = pedIt->getStrip();
889  std::vector<int> myADCVals = pedIt->getADCCounts();
890  float TotalADC = getSignal(*strips, id, myStrip);
891  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
892  float thisSignal =
893  (1. / 6) * (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
894  bool thisStripFired = TotalADC > threshold;
895  if (!thisStripFired) {
896  float ADC = thisSignal - thisPedestal;
897  histos->fill1DHist(ADC, "hStripPed", "Pedestal Noise Distribution", 50, -25., 25., "PedestalNoise");
898  histos->fill1DHistByType(ADC, "hStripPedME", "Pedestal Noise Distribution", id, 50, -25., 25., "PedestalNoise");
899  histos->fillProfile(chamberSerial(id),
900  ADC,
901  "hStripPedMEProfile",
902  "Wire TimeBin Fired",
903  601,
904  -0.5,
905  600.5,
906  -25,
907  25,
908  "PedestalNoise");
909  if (detailedAnalysis) {
910  histos->fill1DHistByLayer(
911  ADC, "hStripPedME", "Pedestal Noise Distribution", id, 50, -25., 25., "PedestalNoiseByLayer");
912  }
913  }
914  }
915  }
916 }
917 
918 // ==============================================
919 //
920 // look at RECHITs
921 //
922 // ==============================================
923 
924 void CSCValidation::doRecHits(edm::Handle<CSCRecHit2DCollection> recHits, edm::ESHandle<CSCGeometry> cscGeom) {
925  // Get the RecHits collection :
926  int nRecHits = recHits->size();
927 
928  // ---------------------
929  // Loop over rechits
930  // ---------------------
931 
932  // Build iterator for rechits and loop :
934  for (dRHIter = recHits->begin(); dRHIter != recHits->end(); dRHIter++) {
935  // Find chamber with rechits in CSC
936  CSCDetId idrec = (CSCDetId)(*dRHIter).cscDetId();
937  int kEndcap = idrec.endcap();
938  int kRing = idrec.ring();
939  int kStation = idrec.station();
940  int kChamber = idrec.chamber();
941  int kLayer = idrec.layer();
942 
943  // Store rechit as a Local Point:
944  LocalPoint rhitlocal = (*dRHIter).localPosition();
945  float xreco = rhitlocal.x();
946  float yreco = rhitlocal.y();
947  LocalError rerrlocal = (*dRHIter).localPositionError();
948  //these errors are squared!
949  float xxerr = rerrlocal.xx();
950  float yyerr = rerrlocal.yy();
951  float xyerr = rerrlocal.xy();
952  // errors in strip units
953  float stpos = (*dRHIter).positionWithinStrip();
954  float sterr = (*dRHIter).errorWithinStrip();
955 
956  // Find the charge associated with this hit
957  float rHSumQ = 0;
958  float sumsides = 0.;
959  int adcsize = dRHIter->nStrips() * dRHIter->nTimeBins();
960  for (unsigned int i = 0; i < dRHIter->nStrips(); i++) {
961  for (unsigned int j = 0; j < dRHIter->nTimeBins() - 1; j++) {
962  rHSumQ += dRHIter->adcs(i, j);
963  if (i != 1)
964  sumsides += dRHIter->adcs(i, j);
965  }
966  }
967 
968  float rHratioQ = sumsides / rHSumQ;
969  if (adcsize != 12)
970  rHratioQ = -99;
971 
972  // Get the signal timing of this hit
973  float rHtime = 0;
974  rHtime = (*dRHIter).tpeak() / 50.;
975 
976  // Get pointer to the layer:
977  const CSCLayer* csclayer = cscGeom->layer(idrec);
978 
979  // Transform hit position from local chamber geometry to global CMS geom
980  GlobalPoint rhitglobal = csclayer->toGlobal(rhitlocal);
981  float grecx = rhitglobal.x();
982  float grecy = rhitglobal.y();
983 
984  // Fill the rechit position branch
985  if (writeTreeToFile && rhTreeCount < 1500000) {
986  histos->fillRechitTree(xreco, yreco, grecx, grecy, kEndcap, kStation, kRing, kChamber, kLayer);
987  rhTreeCount++;
988  }
989 
990  // Fill some histograms
991  // only fill if 3 strips were used in the hit
992  histos->fill2DHistByStation(
993  grecx, grecy, "hRHGlobal", "recHit Global Position", idrec, 100, -800., 800., 100, -800., 800., "recHits");
994  if (kStation == 1 && (kRing == 1 || kRing == 4))
995  histos->fill1DHistByType(rHSumQ, "hRHSumQ", "Sum 3x3 recHit Charge", idrec, 125, 0, 4000, "recHits");
996  else
997  histos->fill1DHistByType(rHSumQ, "hRHSumQ", "Sum 3x3 recHit Charge", idrec, 125, 0, 2000, "recHits");
998  histos->fill1DHistByType(rHratioQ, "hRHRatioQ", "Charge Ratio (Ql+Qr)/Qt", idrec, 120, -0.1, 1.1, "recHits");
999  histos->fill1DHistByType(rHtime, "hRHTiming", "recHit Timing", idrec, 200, -10, 10, "recHits");
1000  histos->fill1DHistByType(sqrt(xxerr), "hRHxerr", "RecHit Error on Local X", idrec, 100, -0.1, 2, "recHits");
1001  histos->fill1DHistByType(sqrt(yyerr), "hRHyerr", "RecHit Error on Local Y", idrec, 100, -0.1, 2, "recHits");
1002  histos->fill1DHistByType(xyerr, "hRHxyerr", "Corr. RecHit XY Error", idrec, 100, -1, 2, "recHits");
1003  if (adcsize == 12)
1004  histos->fill1DHistByType(stpos, "hRHstpos", "Reconstructed Position on Strip", idrec, 120, -0.6, 0.6, "recHits");
1005  histos->fill1DHistByType(
1006  sterr, "hRHsterr", "Estimated Error on Strip Measurement", idrec, 120, -0.05, 0.25, "recHits");
1007  histos->fillProfile(
1008  chamberSerial(idrec), rHSumQ, "hRHSumQProfile", "Sum 3x3 recHit Charge", 601, -0.5, 600.5, 0, 4000, "recHits");
1009  histos->fillProfile(
1010  chamberSerial(idrec), rHtime, "hRHTimingProfile", "recHit Timing", 601, -0.5, 600.5, -11, 11, "recHits");
1011  if (detailedAnalysis) {
1012  if (kStation == 1 && (kRing == 1 || kRing == 4))
1013  histos->fill1DHistByLayer(rHSumQ, "hRHSumQ", "Sum 3x3 recHit Charge", idrec, 125, 0, 4000, "RHQByLayer");
1014  else
1015  histos->fill1DHistByLayer(rHSumQ, "hRHSumQ", "Sum 3x3 recHit Charge", idrec, 125, 0, 2000, "RHQByLayer");
1016  histos->fill1DHistByLayer(rHratioQ, "hRHRatioQ", "Charge Ratio (Ql+Qr)/Qt", idrec, 120, -0.1, 1.1, "RHQByLayer");
1017  histos->fill1DHistByLayer(rHtime, "hRHTiming", "recHit Timing", idrec, 200, -10, 10, "RHTimingByLayer");
1018  histos->fill2DHistByLayer(xreco,
1019  yreco,
1020  "hRHLocalXY",
1021  "recHit Local Position",
1022  idrec,
1023  50,
1024  -100.,
1025  100.,
1026  75,
1027  -150.,
1028  150.,
1029  "RHLocalXYByLayer");
1030  histos->fill1DHistByLayer(
1031  sqrt(xxerr), "hRHxerr", "RecHit Error on Local X", idrec, 100, -0.1, 2, "RHErrorsByLayer");
1032  histos->fill1DHistByLayer(
1033  sqrt(yyerr), "hRHyerr", "RecHit Error on Local Y", idrec, 100, -0.1, 2, "RHErrorsByLayer");
1034  histos->fill1DHistByType(
1035  stpos, "hRHstpos", "Reconstructed Position on Strip", idrec, 120, -0.6, 0.6, "RHStripPosByLayer");
1036  histos->fill1DHistByType(
1037  sterr, "hRHsterr", "Estimated Error on Strip Measurement", idrec, 120, -0.05, 0.25, "RHStripPosByLayer");
1038  }
1039 
1040  } //end rechit loop
1041 
1042  if (nRecHits == 0)
1043  nRecHits = -1;
1044 
1045  histos->fill1DHist(nRecHits, "hRHnrechits", "recHits per Event (all chambers)", 201, -0.5, 200.5, "recHits");
1046 }
1047 
1048 // ==============================================
1049 //
1050 // look at SIMHITS
1051 //
1052 // ==============================================
1053 
1056  for (dSHrecIter = recHits->begin(); dSHrecIter != recHits->end(); dSHrecIter++) {
1057  CSCDetId idrec = (CSCDetId)(*dSHrecIter).cscDetId();
1058  LocalPoint rhitlocal = (*dSHrecIter).localPosition();
1059  float xreco = rhitlocal.x();
1060  float yreco = rhitlocal.y();
1061  float xError = sqrt((*dSHrecIter).localPositionError().xx());
1062  float yError = sqrt((*dSHrecIter).localPositionError().yy());
1063  float simHitXres = -99;
1064  float simHitYres = -99;
1065  float xPull = -99;
1066  float yPull = -99;
1067  float mindiffX = 99;
1068  float mindiffY = 10;
1069  // If MC, find closest muon simHit to check resolution:
1070  PSimHitContainer::const_iterator dSHsimIter;
1071  for (dSHsimIter = simHits->begin(); dSHsimIter != simHits->end(); dSHsimIter++) {
1072  // Get DetID for this simHit:
1073  CSCDetId sId = (CSCDetId)(*dSHsimIter).detUnitId();
1074  // Check if the simHit detID matches that of current recHit
1075  // and make sure it is a muon hit:
1076  if (sId == idrec && abs((*dSHsimIter).particleType()) == 13) {
1077  // Get the position of this simHit in local coordinate system:
1078  LocalPoint sHitlocal = (*dSHsimIter).localPosition();
1079  // Now we need to make reasonably sure that this simHit is
1080  // responsible for this recHit:
1081  if ((sHitlocal.x() - xreco) < mindiffX && (sHitlocal.y() - yreco) < mindiffY) {
1082  simHitXres = (sHitlocal.x() - xreco);
1083  simHitYres = (sHitlocal.y() - yreco);
1084  mindiffX = (sHitlocal.x() - xreco);
1085  xPull = simHitXres / xError;
1086  yPull = simHitYres / yError;
1087  }
1088  }
1089  }
1090 
1091  histos->fill1DHistByType(
1092  simHitXres, "hSimXResid", "SimHitX - Reconstructed X", idrec, 100, -1.0, 1.0, "Resolution");
1093  histos->fill1DHistByType(
1094  simHitYres, "hSimYResid", "SimHitY - Reconstructed Y", idrec, 100, -5.0, 5.0, "Resolution");
1095  histos->fill1DHistByType(xPull, "hSimXPull", "Local X Pulls", idrec, 100, -5.0, 5.0, "Resolution");
1096  histos->fill1DHistByType(yPull, "hSimYPull", "Local Y Pulls", idrec, 100, -5.0, 5.0, "Resolution");
1097  }
1098 }
1099 
1100 // ==============================================
1101 //
1102 // look at SEGMENTs
1103 //
1104 // ===============================================
1105 
1106 void CSCValidation::doSegments(edm::Handle<CSCSegmentCollection> cscSegments, edm::ESHandle<CSCGeometry> cscGeom) {
1107  // get CSC segment collection
1108  int nSegments = cscSegments->size();
1109 
1110  // -----------------------
1111  // loop over segments
1112  // -----------------------
1113  for (CSCSegmentCollection::const_iterator dSiter = cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
1114  //
1115  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
1116  int kEndcap = id.endcap();
1117  int kRing = id.ring();
1118  int kStation = id.station();
1119  int kChamber = id.chamber();
1120 
1121  //
1122  float chisq = (*dSiter).chi2();
1123  int nhits = (*dSiter).nRecHits();
1124  int nDOF = 2 * nhits - 4;
1125  double chisqProb = ChiSquaredProbability((double)chisq, nDOF);
1126  LocalPoint localPos = (*dSiter).localPosition();
1127  float segX = localPos.x();
1128  float segY = localPos.y();
1129  LocalVector segDir = (*dSiter).localDirection();
1130  double theta = segDir.theta();
1131 
1132  // global transformation
1133  float globX = 0.;
1134  float globY = 0.;
1135  float globTheta = 0.;
1136  float globPhi = 0.;
1137  const CSCChamber* cscchamber = cscGeom->chamber(id);
1138  if (cscchamber) {
1139  GlobalPoint globalPosition = cscchamber->toGlobal(localPos);
1140  globX = globalPosition.x();
1141  globY = globalPosition.y();
1142  GlobalVector globalDirection = cscchamber->toGlobal(segDir);
1143  globTheta = globalDirection.theta();
1144  globPhi = globalDirection.phi();
1145  }
1146 
1147  // Fill segment position branch
1148  if (writeTreeToFile && segTreeCount < 1500000) {
1149  histos->fillSegmentTree(segX, segY, globX, globY, kEndcap, kStation, kRing, kChamber);
1150  segTreeCount++;
1151  }
1152 
1153  // Fill histos
1154  histos->fill2DHistByStation(globX,
1155  globY,
1156  "hSGlobal",
1157  "Segment Global Positions;global x (cm)",
1158  id,
1159  100,
1160  -800.,
1161  800.,
1162  100,
1163  -800.,
1164  800.,
1165  "Segments");
1166  histos->fill1DHistByType(nhits, "hSnHits", "N hits on Segments", id, 8, -0.5, 7.5, "Segments");
1167  histos->fill1DHistByType(theta, "hSTheta", "local theta segments", id, 128, -3.2, 3.2, "Segments");
1168  histos->fill1DHistByType((chisq / nDOF), "hSChiSq", "segments chi-squared/ndof", id, 110, -0.05, 10.5, "Segments");
1169  histos->fill1DHistByType(
1170  chisqProb, "hSChiSqProb", "segments chi-squared probability", id, 110, -0.05, 1.05, "Segments");
1171  histos->fill1DHist(globTheta, "hSGlobalTheta", "segment global theta", 128, 0, 3.2, "Segments");
1172  histos->fill1DHist(globPhi, "hSGlobalPhi", "segment global phi", 128, -3.2, 3.2, "Segments");
1173  histos->fillProfile(
1174  chamberSerial(id), nhits, "hSnHitsProfile", "N hits on Segments", 601, -0.5, 600.5, -0.5, 7.5, "Segments");
1175  if (detailedAnalysis) {
1176  histos->fill1DHistByChamber(nhits, "hSnHits", "N hits on Segments", id, 8, -0.5, 7.5, "HitsOnSegmentByChamber");
1177  histos->fill1DHistByChamber(theta, "hSTheta", "local theta segments", id, 128, -3.2, 3.2, "DetailedSegments");
1178  histos->fill1DHistByChamber(
1179  (chisq / nDOF), "hSChiSq", "segments chi-squared/ndof", id, 110, -0.05, 10.5, "SegChi2ByChamber");
1180  histos->fill1DHistByChamber(
1181  chisqProb, "hSChiSqProb", "segments chi-squared probability", id, 110, -0.05, 1.05, "SegChi2ByChamber");
1182  }
1183 
1184  } // end segment loop
1185 
1186  if (nSegments == 0)
1187  nSegments = -1;
1188 
1189  histos->fill1DHist(nSegments, "hSnSegments", "Segments per Event", 31, -0.5, 30.5, "Segments");
1190 }
1191 
1192 // ==============================================
1193 //
1194 // look at hit Resolution
1195 //
1196 // ===============================================
1197 
1198 void CSCValidation::doResolution(edm::Handle<CSCSegmentCollection> cscSegments, edm::ESHandle<CSCGeometry> cscGeom) {
1199  for (CSCSegmentCollection::const_iterator dSiter = cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
1200  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
1201 
1202  //
1203  // try to get the CSC recHits that contribute to this segment.
1204  std::vector<CSCRecHit2D> theseRecHits = (*dSiter).specificRecHits();
1205  int nRH = (*dSiter).nRecHits();
1206  CLHEP::HepMatrix sp(6, 1);
1207  CLHEP::HepMatrix se(6, 1);
1208  for (std::vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
1209  CSCDetId idRH = (CSCDetId)(*iRH).cscDetId();
1210  int kRing = idRH.ring();
1211  int kStation = idRH.station();
1212  int kLayer = idRH.layer();
1213 
1214  // Find the strip containing this hit
1215  int centerid = iRH->nStrips() / 2;
1216  int centerStrip = iRH->channels(centerid);
1217 
1218  // If this segment has 6 hits, find the position of each hit on the strip in units of stripwidth and store values
1219  if (nRH == 6) {
1220  float stpos = (*iRH).positionWithinStrip();
1221  se(kLayer, 1) = (*iRH).errorWithinStrip();
1222  // Take into account half-strip staggering of layers (ME1/1 has no staggering)
1223  if (kStation == 1 && (kRing == 1 || kRing == 4))
1224  sp(kLayer, 1) = stpos + centerStrip;
1225  else {
1226  if (kLayer == 1 || kLayer == 3 || kLayer == 5)
1227  sp(kLayer, 1) = stpos + centerStrip;
1228  if (kLayer == 2 || kLayer == 4 || kLayer == 6)
1229  sp(kLayer, 1) = stpos - 0.5 + centerStrip;
1230  }
1231  }
1232  }
1233 
1234  float residual = -99;
1235  float pull = -99;
1236  // Fit all points except layer 3, then compare expected value for layer 3 to reconstructed value
1237  if (nRH == 6) {
1238  float expected = fitX(sp, se);
1239  residual = expected - sp(3, 1);
1240  pull = residual / se(3, 1);
1241  }
1242 
1243  // Fill histos
1244  histos->fill1DHistByType(
1245  residual, "hSResid", "Fitted Position on Strip - Reconstructed for Layer 3", id, 100, -0.5, 0.5, "Resolution");
1246  histos->fill1DHistByType(pull, "hSStripPosPull", "Strip Measurement Pulls", id, 100, -5.0, 5.0, "Resolution");
1247  histos->fillProfile(chamberSerial(id),
1248  residual,
1249  "hSResidProfile",
1250  "Fitted Position on Strip - Reconstructed for Layer 3",
1251  601,
1252  -0.5,
1253  600.5,
1254  -0.5,
1255  0.5,
1256  "Resolution");
1257  if (detailedAnalysis) {
1258  histos->fill1DHistByChamber(residual,
1259  "hSResid",
1260  "Fitted Position on Strip - Reconstructed for Layer 3",
1261  id,
1262  100,
1263  -0.5,
1264  0.5,
1265  "DetailedResolution");
1266  histos->fill1DHistByChamber(pull, "hSStripPosPull", "Strip Measurement Pulls", id, 100, -5.0, 5.0, "Resolution");
1267  }
1268  }
1269 }
1270 
1271 // ==============================================
1272 //
1273 // look at Standalone Muons
1274 //
1275 // ==============================================
1276 
1277 void CSCValidation::doStandalone(Handle<reco::TrackCollection> saMuons) {
1278  int nSAMuons = saMuons->size();
1279  histos->fill1DHist(nSAMuons, "trNSAMuons", "N Standalone Muons per Event", 6, -0.5, 5.5, "STAMuons");
1280 
1281  for (reco::TrackCollection::const_iterator muon = saMuons->begin(); muon != saMuons->end(); ++muon) {
1282  float preco = muon->p();
1283  float ptreco = muon->pt();
1284  int n = muon->recHitsSize();
1285  float chi2 = muon->chi2();
1286  float normchi2 = muon->normalizedChi2();
1287 
1288  // loop over hits
1289  int nDTHits = 0;
1290  int nCSCHits = 0;
1291  int nCSCHitsp = 0;
1292  int nCSCHitsm = 0;
1293  int nRPCHits = 0;
1294  int nRPCHitsp = 0;
1295  int nRPCHitsm = 0;
1296  int np = 0;
1297  int nm = 0;
1298  std::vector<CSCDetId> staChambers;
1299  for (trackingRecHit_iterator hit = muon->recHitsBegin(); hit != muon->recHitsEnd(); ++hit) {
1300  const DetId detId((*hit)->geographicalId());
1301  if (detId.det() == DetId::Muon) {
1302  if (detId.subdetId() == MuonSubdetId::RPC) {
1303  RPCDetId rpcId(detId.rawId());
1304  nRPCHits++;
1305  if (rpcId.region() == 1) {
1306  nRPCHitsp++;
1307  np++;
1308  }
1309  if (rpcId.region() == -1) {
1310  nRPCHitsm++;
1311  nm++;
1312  }
1313  }
1314  if (detId.subdetId() == MuonSubdetId::DT) {
1315  nDTHits++;
1316  } else if (detId.subdetId() == MuonSubdetId::CSC) {
1317  CSCDetId cscId(detId.rawId());
1318  staChambers.push_back(detId.rawId());
1319  nCSCHits++;
1320  if (cscId.endcap() == 1) {
1321  nCSCHitsp++;
1322  np++;
1323  }
1324  if (cscId.endcap() == 2) {
1325  nCSCHitsm++;
1326  nm++;
1327  }
1328  }
1329  }
1330  }
1331 
1332  GlobalPoint innerPnt(muon->innerPosition().x(), muon->innerPosition().y(), muon->innerPosition().z());
1333  GlobalPoint outerPnt(muon->outerPosition().x(), muon->outerPosition().y(), muon->outerPosition().z());
1334  GlobalVector innerKin(muon->innerMomentum().x(), muon->innerMomentum().y(), muon->innerMomentum().z());
1335  GlobalVector outerKin(muon->outerMomentum().x(), muon->outerMomentum().y(), muon->outerMomentum().z());
1336  GlobalVector deltaPnt = innerPnt - outerPnt;
1337  double crudeLength = deltaPnt.mag();
1338  double deltaPhi = innerPnt.phi() - outerPnt.phi();
1339  double innerGlobalPolarAngle = innerKin.theta();
1340  double outerGlobalPolarAngle = outerKin.theta();
1341 
1342  // fill histograms
1343  histos->fill1DHist(n, "trN", "N hits on a STA Muon Track", 51, -0.5, 50.5, "STAMuons");
1344  if (np != 0)
1345  histos->fill1DHist(np, "trNp", "N hits on a STA Muon Track (plus endcap)", 51, -0.5, 50.5, "STAMuons");
1346  if (nm != 0)
1347  histos->fill1DHist(nm, "trNm", "N hits on a STA Muon Track (minus endcap)", 51, -0.5, 50.5, "STAMuons");
1348  histos->fill1DHist(nDTHits, "trNDT", "N DT hits on a STA Muon Track", 51, -0.5, 50.5, "STAMuons");
1349  histos->fill1DHist(nCSCHits, "trNCSC", "N CSC hits on a STA Muon Track", 51, -0.5, 50.5, "STAMuons");
1350  if (nCSCHitsp != 0)
1351  histos->fill1DHist(nCSCHitsp, "trNCSCp", "N CSC hits on a STA Muon Track (+ endcap)", 51, -0.5, 50.5, "STAMuons");
1352  if (nCSCHitsm != 0)
1353  histos->fill1DHist(nCSCHitsm, "trNCSCm", "N CSC hits on a STA Muon Track (- endcap)", 51, -0.5, 50.5, "STAMuons");
1354  histos->fill1DHist(nRPCHits, "trNRPC", "N RPC hits on a STA Muon Track", 51, -0.5, 50.5, "STAMuons");
1355  if (nRPCHitsp != 0)
1356  histos->fill1DHist(nRPCHitsp, "trNRPCp", "N RPC hits on a STA Muon Track (+ endcap)", 51, -0.5, 50.5, "STAMuons");
1357  if (nRPCHitsm != 0)
1358  histos->fill1DHist(nRPCHitsm, "trNRPCm", "N RPC hits on a STA Muon Track (- endcap)", 51, -0.5, 50.5, "STAMuons");
1359  histos->fill1DHist(preco, "trP", "STA Muon Momentum", 100, 0, 300, "STAMuons");
1360  histos->fill1DHist(ptreco, "trPT", "STA Muon pT", 100, 0, 40, "STAMuons");
1361  histos->fill1DHist(chi2, "trChi2", "STA Muon Chi2", 100, 0, 200, "STAMuons");
1362  histos->fill1DHist(normchi2, "trNormChi2", "STA Muon Normalized Chi2", 100, 0, 10, "STAMuons");
1363  histos->fill1DHist(crudeLength, "trLength", "Straight Line Length of STA Muon", 120, 0., 2400., "STAMuons");
1364  histos->fill1DHist(
1365  deltaPhi, "trDeltaPhi", "Delta-Phi Between Inner and Outer STA Muon Pos.", 100, -0.5, 0.5, "STAMuons");
1366  histos->fill1DHist(
1367  innerGlobalPolarAngle, "trInnerPolar", "Polar Angle of Inner P Vector (STA muons)", 128, 0, 3.2, "STAMuons");
1368  histos->fill1DHist(
1369  outerGlobalPolarAngle, "trOuterPolar", "Polar Angle of Outer P Vector (STA muons)", 128, 0, 3.2, "STAMuons");
1370  histos->fill1DHist(innerPnt.phi(), "trInnerPhi", "Phi of Inner Position (STA muons)", 256, -3.2, 3.2, "STAMuons");
1371  histos->fill1DHist(outerPnt.phi(), "trOuterPhi", "Phi of Outer Position (STA muons)", 256, -3.2, 3.2, "STAMuons");
1372  }
1373 }
1374 
1375 //--------------------------------------------------------------
1376 // Compute a serial number for the chamber.
1377 // This is useful when filling histograms and working with arrays.
1378 //--------------------------------------------------------------
1379 int CSCValidation::chamberSerial(CSCDetId id) {
1380  int st = id.station();
1381  int ri = id.ring();
1382  int ch = id.chamber();
1383  int ec = id.endcap();
1384  int kSerial = ch;
1385  if (st == 1 && ri == 1)
1386  kSerial = ch;
1387  if (st == 1 && ri == 2)
1388  kSerial = ch + 36;
1389  if (st == 1 && ri == 3)
1390  kSerial = ch + 72;
1391  if (st == 1 && ri == 4)
1392  kSerial = ch;
1393  if (st == 2 && ri == 1)
1394  kSerial = ch + 108;
1395  if (st == 2 && ri == 2)
1396  kSerial = ch + 126;
1397  if (st == 3 && ri == 1)
1398  kSerial = ch + 162;
1399  if (st == 3 && ri == 2)
1400  kSerial = ch + 180;
1401  if (st == 4 && ri == 1)
1402  kSerial = ch + 216;
1403  if (st == 4 && ri == 2)
1404  kSerial = ch + 234;
1405  if (ec == 2)
1406  kSerial = kSerial + 300;
1407  return kSerial;
1408 }
1409 
1410 //--------------------------------------------------------------
1411 // Compute a serial number for the ring.
1412 // This is useful when filling histograms and working with arrays.
1413 //--------------------------------------------------------------
1414 int CSCValidation::ringSerial(CSCDetId id) {
1415  int st = id.station();
1416  int ri = id.ring();
1417  int ec = id.endcap();
1418  int kSerial = 0;
1419  if (st == 1 && ri == 1)
1420  kSerial = ri;
1421  if (st == 1 && ri == 2)
1422  kSerial = ri;
1423  if (st == 1 && ri == 3)
1424  kSerial = ri;
1425  if (st == 1 && ri == 4)
1426  kSerial = 1;
1427  if (st == 2)
1428  kSerial = ri + 3;
1429  if (st == 3)
1430  kSerial = ri + 5;
1431  if (st == 4)
1432  kSerial = ri + 7;
1433  if (ec == 2)
1434  kSerial = kSerial * (-1);
1435  return kSerial;
1436 }
1437 
1438 //-------------------------------------------------------------------------------------
1439 // Fits a straight line to a set of 5 points with errors. Functions assumes 6 points
1440 // and removes hit in layer 3. It then returns the expected position value in layer 3
1441 // based on the fit.
1442 //-------------------------------------------------------------------------------------
1443 float CSCValidation::fitX(const CLHEP::HepMatrix& points, const CLHEP::HepMatrix& errors) {
1444  float S = 0;
1445  float Sx = 0;
1446  float Sy = 0;
1447  float Sxx = 0;
1448  float Sxy = 0;
1449  float sigma2 = 0;
1450 
1451  for (int i = 1; i < 7; i++) {
1452  if (i != 3) {
1453  sigma2 = errors(i, 1) * errors(i, 1);
1454  S = S + (1 / sigma2);
1455  Sy = Sy + (points(i, 1) / sigma2);
1456  Sx = Sx + ((i) / sigma2);
1457  Sxx = Sxx + (i * i) / sigma2;
1458  Sxy = Sxy + (((i)*points(i, 1)) / sigma2);
1459  }
1460  }
1461 
1462  float delta = S * Sxx - Sx * Sx;
1463  float intercept = (Sxx * Sy - Sx * Sxy) / delta;
1464  float slope = (S * Sxy - Sx * Sy) / delta;
1465 
1466  //float chi = 0;
1467  //float chi2 = 0;
1468 
1469  // calculate chi2 (not currently used)
1470  //for (int i=1;i<7;i++){
1471  // chi = (points(i,1) - intercept - slope*i)/(errors(i,1));
1472  // chi2 = chi2 + chi*chi;
1473  //}
1474 
1475  return (intercept + slope * 3);
1476 }
1477 
1478 //----------------------------------------------------------------------------
1479 // Calculate basic efficiencies for recHits and Segments
1480 // Author: S. Stoynev
1481 //----------------------------------------------------------------------------
1482 
1483 void CSCValidation::doEfficiencies(edm::Handle<CSCWireDigiCollection> wires,
1487  edm::ESHandle<CSCGeometry> cscGeom) {
1488  bool allWires[2][4][4][36][6];
1489  bool allStrips[2][4][4][36][6];
1490  bool AllRecHits[2][4][4][36][6];
1491  bool AllSegments[2][4][4][36];
1492 
1493  //bool MultiSegments[2][4][4][36];
1494  for (int iE = 0; iE < 2; iE++) {
1495  for (int iS = 0; iS < 4; iS++) {
1496  for (int iR = 0; iR < 4; iR++) {
1497  for (int iC = 0; iC < 36; iC++) {
1498  AllSegments[iE][iS][iR][iC] = false;
1499  //MultiSegments[iE][iS][iR][iC] = false;
1500  for (int iL = 0; iL < 6; iL++) {
1501  allWires[iE][iS][iR][iC][iL] = false;
1502  allStrips[iE][iS][iR][iC][iL] = false;
1503  AllRecHits[iE][iS][iR][iC][iL] = false;
1504  }
1505  }
1506  }
1507  }
1508  }
1509 
1510  if (useDigis) {
1511  // Wires
1512  for (CSCWireDigiCollection::DigiRangeIterator dWDiter = wires->begin(); dWDiter != wires->end(); dWDiter++) {
1513  CSCDetId idrec = (CSCDetId)(*dWDiter).first;
1514  std::vector<CSCWireDigi>::const_iterator wireIter = (*dWDiter).second.first;
1515  std::vector<CSCWireDigi>::const_iterator lWire = (*dWDiter).second.second;
1516  for (; wireIter != lWire; ++wireIter) {
1517  allWires[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1518  true;
1519  break;
1520  }
1521  }
1522 
1523  //---- STRIPS
1524  for (CSCStripDigiCollection::DigiRangeIterator dSDiter = strips->begin(); dSDiter != strips->end(); dSDiter++) {
1525  CSCDetId idrec = (CSCDetId)(*dSDiter).first;
1526  std::vector<CSCStripDigi>::const_iterator stripIter = (*dSDiter).second.first;
1527  std::vector<CSCStripDigi>::const_iterator lStrip = (*dSDiter).second.second;
1528  for (; stripIter != lStrip; ++stripIter) {
1529  std::vector<int> myADCVals = stripIter->getADCCounts();
1530  bool thisStripFired = false;
1531  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1532  float threshold = 13.3;
1533  float diff = 0.;
1534  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
1535  diff = (float)myADCVals[iCount] - thisPedestal;
1536  if (diff > threshold) {
1537  thisStripFired = true;
1538  break;
1539  }
1540  }
1541  if (thisStripFired) {
1542  allStrips[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1543  true;
1544  break;
1545  }
1546  }
1547  }
1548  }
1549 
1550  // Rechits
1551  for (CSCRecHit2DCollection::const_iterator recEffIt = recHits->begin(); recEffIt != recHits->end(); recEffIt++) {
1552  //CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
1553  CSCDetId idrec = (CSCDetId)(*recEffIt).cscDetId();
1554  AllRecHits[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1555  true;
1556  }
1557 
1558  std::vector<unsigned int> seg_ME2(2, 0);
1559  std::vector<unsigned int> seg_ME3(2, 0);
1560  std::vector<std::pair<CSCDetId, CSCSegment> > theSegments(4);
1561  // Segments
1562  for (CSCSegmentCollection::const_iterator segEffIt = cscSegments->begin(); segEffIt != cscSegments->end();
1563  segEffIt++) {
1564  CSCDetId idseg = (CSCDetId)(*segEffIt).cscDetId();
1565  //if(AllSegments[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber()]){
1566  //MultiSegments[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber()] = true;
1567  //}
1568  AllSegments[idseg.endcap() - 1][idseg.station() - 1][idseg.ring() - 1][idseg.chamber() - 1] = true;
1569  // "Intrinsic" efficiency measurement relies on "good" segment extrapolation - we need the pre-selection below
1570  // station 2 "good" segment will be used for testing efficiencies in ME1 and ME3
1571  // station 3 "good" segment will be used for testing efficiencies in ME2 and ME4
1572  if (2 == idseg.station() || 3 == idseg.station()) {
1573  unsigned int seg_tmp;
1574  if (2 == idseg.station()) {
1575  ++seg_ME2[idseg.endcap() - 1];
1576  seg_tmp = seg_ME2[idseg.endcap() - 1];
1577  } else {
1578  ++seg_ME3[idseg.endcap() - 1];
1579  seg_tmp = seg_ME3[idseg.endcap() - 1];
1580  }
1581  // is the segment good
1582  if (1 == seg_tmp && 6 == (*segEffIt).nRecHits() && (*segEffIt).chi2() / (*segEffIt).degreesOfFreedom() < 3.) {
1583  std::pair<CSCDetId, CSCSegment> specSeg = make_pair((CSCDetId)(*segEffIt).cscDetId(), *segEffIt);
1584  theSegments[2 * (idseg.endcap() - 1) + (idseg.station() - 2)] = specSeg;
1585  }
1586  }
1587  /*
1588  if(2==idseg.station()){
1589  ++seg_ME2[idseg.endcap() -1];
1590  if(1==seg_ME2[idseg.endcap() -1] && 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1591  std::pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1592  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1593  }
1594  }
1595  else if(3==idseg.station()){
1596  ++seg_ME3[idseg.endcap() -1];
1597  if(1==seg_ME3[idseg.endcap() -1] && 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1598  std::pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1599  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1600  }
1601  }
1602  */
1603  }
1604  // Simple efficiency calculations
1605  for (int iE = 0; iE < 2; iE++) {
1606  for (int iS = 0; iS < 4; iS++) {
1607  for (int iR = 0; iR < 4; iR++) {
1608  for (int iC = 0; iC < 36; iC++) {
1609  int NumberOfLayers = 0;
1610  for (int iL = 0; iL < 6; iL++) {
1611  if (AllRecHits[iE][iS][iR][iC][iL]) {
1612  NumberOfLayers++;
1613  }
1614  }
1615  int bin = 0;
1616  if (iS == 0)
1617  bin = iR + 1 + (iE * 10);
1618  else
1619  bin = (iS + 1) * 2 + (iR + 1) + (iE * 10);
1620  if (NumberOfLayers > 1) {
1621  //if(!(MultiSegments[iE][iS][iR][iC])){
1622  if (AllSegments[iE][iS][iR][iC]) {
1623  //---- Efficient segment events
1624  //hSSTE->AddBinContent(bin);
1625  hSSTE->Fill(bin - 0.5);
1626  if (NumberOfLayers > 3)
1627  hSSTETight->Fill(bin - 0.5);
1628  }
1629  //---- All segment events (normalization)
1630  //hSSTE->AddBinContent(20+bin);
1631  hSSTE->Fill(20 + bin - 0.5);
1632  if (NumberOfLayers > 3)
1633  hSSTETight->Fill(20 + bin - 0.5);
1634  //} //}
1635  }
1636  if (AllSegments[iE][iS][iR][iC]) {
1637  if (NumberOfLayers == 6) {
1638  //---- Efficient rechit events
1639  //hRHSTE->AddBinContent(bin);
1640  hRHSTE->Fill(bin - 0.5);
1641  hRHSTETight->Fill(bin - 0.5);
1642  ;
1643  }
1644  //---- All rechit events (normalization)
1645  //hRHSTE->AddBinContent(20+bin);
1646  hRHSTE->Fill(20 + bin - 0.5);
1647  if (NumberOfLayers > 3)
1648  hRHSTETight->Fill(20 + bin - 0.5);
1649  ;
1650  }
1651  }
1652  }
1653  }
1654  }
1655 
1656  // pick a segment only if there are no others in the station
1657  std::vector<std::pair<CSCDetId, CSCSegment>*> theSeg;
1658  if (1 == seg_ME2[0])
1659  theSeg.push_back(&theSegments[0]);
1660  if (1 == seg_ME3[0])
1661  theSeg.push_back(&theSegments[1]);
1662  if (1 == seg_ME2[1])
1663  theSeg.push_back(&theSegments[2]);
1664  if (1 == seg_ME3[1])
1665  theSeg.push_back(&theSegments[3]);
1666 
1667  // Needed for plots
1668  // at the end the chamber types will be numbered as 1 to 20
1669  // (ME-4/2, ME-4/1, -ME3/2, -ME3/1, ..., +ME3/1, +ME3/2, ME+4/1, ME+4/2 )
1670  std::map<std::string, float> chamberTypes;
1671  chamberTypes["ME1/a"] = 0.5;
1672  chamberTypes["ME1/b"] = 1.5;
1673  chamberTypes["ME1/2"] = 2.5;
1674  chamberTypes["ME1/3"] = 3.5;
1675  chamberTypes["ME2/1"] = 4.5;
1676  chamberTypes["ME2/2"] = 5.5;
1677  chamberTypes["ME3/1"] = 6.5;
1678  chamberTypes["ME3/2"] = 7.5;
1679  chamberTypes["ME4/1"] = 8.5;
1680  chamberTypes["ME4/2"] = 9.5;
1681 
1682  if (!theSeg.empty()) {
1683  std::map<int, GlobalPoint> extrapolatedPoint;
1684  std::map<int, GlobalPoint>::iterator it;
1685  const CSCGeometry::ChamberContainer& ChamberContainer = cscGeom->chambers();
1686  // Pick which chamber with which segment to test
1687  for (size_t nCh = 0; nCh < ChamberContainer.size(); nCh++) {
1688  const CSCChamber* cscchamber = ChamberContainer[nCh];
1689  std::pair<CSCDetId, CSCSegment>* thisSegment = nullptr;
1690  for (size_t iSeg = 0; iSeg < theSeg.size(); ++iSeg) {
1691  if (cscchamber->id().endcap() == theSeg[iSeg]->first.endcap()) {
1692  if (1 == cscchamber->id().station() || 3 == cscchamber->id().station()) {
1693  if (2 == theSeg[iSeg]->first.station()) {
1694  thisSegment = theSeg[iSeg];
1695  }
1696  } else if (2 == cscchamber->id().station() || 4 == cscchamber->id().station()) {
1697  if (3 == theSeg[iSeg]->first.station()) {
1698  thisSegment = theSeg[iSeg];
1699  }
1700  }
1701  }
1702  }
1703  // this chamber is to be tested with thisSegment
1704  if (thisSegment) {
1705  CSCSegment* seg = &(thisSegment->second);
1706  const CSCChamber* segChamber = cscGeom->chamber(thisSegment->first);
1707  LocalPoint localCenter(0., 0., 0);
1708  GlobalPoint cscchamberCenter = cscchamber->toGlobal(localCenter);
1709  // try to save some time (extrapolate a segment to a certain position only once)
1710  it = extrapolatedPoint.find(int(cscchamberCenter.z()));
1711  if (it == extrapolatedPoint.end()) {
1712  GlobalPoint segPos = segChamber->toGlobal(seg->localPosition());
1713  GlobalVector segDir = segChamber->toGlobal(seg->localDirection());
1714  double paramaterLine = lineParametrization(segPos.z(), cscchamberCenter.z(), segDir.z());
1715  double xExtrapolated = extrapolate1D(segPos.x(), segDir.x(), paramaterLine);
1716  double yExtrapolated = extrapolate1D(segPos.y(), segDir.y(), paramaterLine);
1717  GlobalPoint globP(xExtrapolated, yExtrapolated, cscchamberCenter.z());
1718  extrapolatedPoint[int(cscchamberCenter.z())] = globP;
1719  }
1720  // Where does the extrapolated point lie in the (tested) chamber local frame? Here:
1721  LocalPoint extrapolatedPointLocal = cscchamber->toLocal(extrapolatedPoint[int(cscchamberCenter.z())]);
1722  const CSCLayer* layer_p = cscchamber->layer(1); //layer 1
1723  const CSCLayerGeometry* layerGeom = layer_p->geometry();
1724  const std::array<const float, 4>& layerBounds = layerGeom->parameters();
1725  float shiftFromEdge = 15.; //cm
1726  float shiftFromDeadZone = 10.;
1727  // is the extrapolated point within a sensitive region
1728  bool pass = withinSensitiveRegion(extrapolatedPointLocal,
1729  layerBounds,
1730  cscchamber->id().station(),
1731  cscchamber->id().ring(),
1732  shiftFromEdge,
1733  shiftFromDeadZone);
1734  if (pass) { // the extrapolation point of the segment lies within sensitive region of that chamber
1735  // how many rechit layers are there in the chamber?
1736  // 0 - maybe the muon died or is deflected at large angle? do not use that case
1737  // 1 - could be noise...
1738  // 2 or more - this is promissing; this is our definition of a reliable signal; use it below
1739  // is other definition better?
1740  int nRHLayers = 0;
1741  for (int iL = 0; iL < 6; ++iL) {
1742  if (AllRecHits[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1743  [cscchamber->id().chamber() - 1][iL]) {
1744  ++nRHLayers;
1745  }
1746  }
1747  //std::cout<<" nRHLayers = "<<nRHLayers<<std::endl;
1748  float verticalScale = chamberTypes[cscchamber->specs()->chamberTypeName()];
1749  if (cscchamberCenter.z() < 0) {
1750  verticalScale = -verticalScale;
1751  }
1752  verticalScale += 10.5;
1753  hSensitiveAreaEvt->Fill(float(cscchamber->id().chamber()), verticalScale);
1754  if (nRHLayers > 1) { // this chamber contains a reliable signal
1755  //chamberTypes[cscchamber->specs()->chamberTypeName()];
1756  // "intrinsic" efficiencies
1757  //std::cout<<" verticalScale = "<<verticalScale<<" chType = "<<cscchamber->specs()->chamberTypeName()<<std::endl;
1758  // this is the denominator forr all efficiencies
1759  hEffDenominator->Fill(float(cscchamber->id().chamber()), verticalScale);
1760  if (nRHLayers > 3)
1761  hEffDenominatorTight->Fill(float(cscchamber->id().chamber()), verticalScale);
1762  // Segment efficiency
1763  if (AllSegments[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1764  [cscchamber->id().chamber() - 1]) {
1765  hSSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale));
1766  if (nRHLayers > 3)
1767  hSSTE2Tight->Fill(float(cscchamber->id().chamber()), float(verticalScale));
1768  }
1769 
1770  for (int iL = 0; iL < 6; ++iL) {
1771  float weight = 1. / 6.;
1772  // one shold account for the weight in the efficiency...
1773  // Rechit efficiency
1774  if (AllRecHits[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1775  [cscchamber->id().chamber() - 1][iL]) {
1776  hRHSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1777  if (nRHLayers > 3)
1778  hRHSTE2Tight->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1779  }
1780  if (useDigis) {
1781  // Wire efficiency
1782  if (allWires[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1783  [cscchamber->id().chamber() - 1][iL]) {
1784  // one shold account for the weight in the efficiency...
1785  hWireSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1786  if (nRHLayers > 3)
1787  hWireSTE2Tight->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1788  }
1789  // Strip efficiency
1790  if (allStrips[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1]
1791  [cscchamber->id().ring() - 1][cscchamber->id().chamber() - 1][iL]) {
1792  // one shold account for the weight in the efficiency...
1793  hStripSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1794  if (nRHLayers > 3)
1795  hStripSTE2Tight->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1796  }
1797  }
1798  }
1799  }
1800  }
1801  }
1802  }
1803  }
1804  //
1805 }
1806 
1807 void CSCValidation::getEfficiency(float bin, float Norm, std::vector<float>& eff) {
1808  //---- Efficiency with binomial error
1809  float Efficiency = 0.;
1810  float EffError = 0.;
1811  if (fabs(Norm) > 0.000000001) {
1812  Efficiency = bin / Norm;
1813  if (bin < Norm) {
1814  EffError = sqrt((1. - Efficiency) * Efficiency / Norm);
1815  }
1816  }
1817  eff[0] = Efficiency;
1818  eff[1] = EffError;
1819 }
1820 
1821 void CSCValidation::histoEfficiency(TH1F* readHisto, TH1F* writeHisto) {
1822  std::vector<float> eff(2);
1823  int Nbins = readHisto->GetSize() - 2; //without underflows and overflows
1824  std::vector<float> bins(Nbins);
1825  std::vector<float> Efficiency(Nbins);
1826  std::vector<float> EffError(Nbins);
1827  float Num = 1;
1828  float Den = 1;
1829  for (int i = 0; i < 20; i++) {
1830  Num = readHisto->GetBinContent(i + 1);
1831  Den = readHisto->GetBinContent(i + 21);
1832  getEfficiency(Num, Den, eff);
1833  Efficiency[i] = eff[0];
1834  EffError[i] = eff[1];
1835  writeHisto->SetBinContent(i + 1, Efficiency[i]);
1836  writeHisto->SetBinError(i + 1, EffError[i]);
1837  }
1838 }
1839 
1840 bool CSCValidation::withinSensitiveRegion(LocalPoint localPos,
1841  const std::array<const float, 4>& layerBounds,
1842  int station,
1843  int ring,
1844  float shiftFromEdge,
1845  float shiftFromDeadZone) {
1846  //---- check if it is in a good local region (sensitive area - geometrical and HV boundaries excluded)
1847  bool pass = false;
1848 
1849  float y_center = 0.;
1850  double yUp = layerBounds[3] + y_center;
1851  double yDown = -layerBounds[3] + y_center;
1852  double xBound1Shifted = layerBounds[0] - shiftFromEdge; //
1853  double xBound2Shifted = layerBounds[1] - shiftFromEdge; //
1854  double lineSlope = (yUp - yDown) / (xBound2Shifted - xBound1Shifted);
1855  double lineConst = yUp - lineSlope * xBound2Shifted;
1856  double yBorder = lineSlope * abs(localPos.x()) + lineConst;
1857 
1858  //bool withinChamberOnly = false;// false = "good region"; true - boundaries only
1859  std::vector<float> deadZoneCenter(6);
1860  float cutZone = shiftFromDeadZone; //cm
1861  //---- hardcoded... not good
1862  if (station > 1 && station < 5) {
1863  if (2 == ring) {
1864  deadZoneCenter[0] = -162.48;
1865  deadZoneCenter[1] = -81.8744;
1866  deadZoneCenter[2] = -21.18165;
1867  deadZoneCenter[3] = 39.51105;
1868  deadZoneCenter[4] = 100.2939;
1869  deadZoneCenter[5] = 160.58;
1870 
1871  if (localPos.y() > yBorder &&
1872  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
1873  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
1874  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone) ||
1875  (localPos.y() > deadZoneCenter[3] + cutZone && localPos.y() < deadZoneCenter[4] - cutZone) ||
1876  (localPos.y() > deadZoneCenter[4] + cutZone && localPos.y() < deadZoneCenter[5] - cutZone))) {
1877  pass = true;
1878  }
1879  } else if (1 == ring) {
1880  if (2 == station) {
1881  deadZoneCenter[0] = -95.80;
1882  deadZoneCenter[1] = -27.47;
1883  deadZoneCenter[2] = 33.67;
1884  deadZoneCenter[3] = 90.85;
1885  } else if (3 == station) {
1886  deadZoneCenter[0] = -89.305;
1887  deadZoneCenter[1] = -39.705;
1888  deadZoneCenter[2] = 20.195;
1889  deadZoneCenter[3] = 77.395;
1890  } else if (4 == station) {
1891  deadZoneCenter[0] = -75.645;
1892  deadZoneCenter[1] = -26.055;
1893  deadZoneCenter[2] = 23.855;
1894  deadZoneCenter[3] = 70.575;
1895  }
1896  if (localPos.y() > yBorder &&
1897  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
1898  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
1899  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
1900  pass = true;
1901  }
1902  }
1903  } else if (1 == station) {
1904  if (3 == ring) {
1905  deadZoneCenter[0] = -83.155;
1906  deadZoneCenter[1] = -22.7401;
1907  deadZoneCenter[2] = 27.86665;
1908  deadZoneCenter[3] = 81.005;
1909  if (localPos.y() > yBorder &&
1910  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
1911  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
1912  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
1913  pass = true;
1914  }
1915  } else if (2 == ring) {
1916  deadZoneCenter[0] = -86.285;
1917  deadZoneCenter[1] = -32.88305;
1918  deadZoneCenter[2] = 32.867423;
1919  deadZoneCenter[3] = 88.205;
1920  if (localPos.y() > (yBorder) &&
1921  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
1922  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
1923  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
1924  pass = true;
1925  }
1926  } else if (1 == ring) { // ME1/1b
1927  deadZoneCenter[0] = -31.5;
1928  deadZoneCenter[1] = 86.0;
1929  if (localPos.y() > (yBorder) &&
1930  (localPos.y() > deadZoneCenter[0] && localPos.y() < deadZoneCenter[1] - cutZone)) {
1931  pass = true;
1932  }
1933  } else if (4 == ring) { // ME1/1a
1934  deadZoneCenter[0] = -86.0;
1935  deadZoneCenter[1] = -31.5;
1936  if (localPos.y() > (yBorder) &&
1937  (localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1])) {
1938  pass = true;
1939  }
1940  }
1941  }
1942  return pass;
1943 }
1944 
1945 //---------------------------------------------------------------------------------------
1946 // Given a set of digis, the CSCDetId, and the central strip of your choosing, returns
1947 // the avg. Signal-Pedestal for 6 time bin x 5 strip .
1948 //
1949 // Author: P. Jindal
1950 //---------------------------------------------------------------------------------------
1951 
1952 float CSCValidation::getSignal(const CSCStripDigiCollection& stripdigis, CSCDetId idCS, int centerStrip) {
1953  float SigADC[5];
1954  float TotalADC = 0;
1955  SigADC[0] = 0;
1956  SigADC[1] = 0;
1957  SigADC[2] = 0;
1958  SigADC[3] = 0;
1959  SigADC[4] = 0;
1960 
1961  // Loop over strip digis
1963 
1964  for (sIt = stripdigis.begin(); sIt != stripdigis.end(); sIt++) {
1965  CSCDetId id = (CSCDetId)(*sIt).first;
1966  if (id == idCS) {
1967  // First, find the Signal-Pedestal for center strip
1968  std::vector<CSCStripDigi>::const_iterator digiItr = (*sIt).second.first;
1969  std::vector<CSCStripDigi>::const_iterator last = (*sIt).second.second;
1970  for (; digiItr != last; ++digiItr) {
1971  int thisStrip = digiItr->getStrip();
1972  if (thisStrip == (centerStrip)) {
1973  std::vector<int> myADCVals = digiItr->getADCCounts();
1974  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1975  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1976  SigADC[0] = thisSignal - 6 * thisPedestal;
1977  }
1978  // Now,find the Signal-Pedestal for neighbouring 4 strips
1979  if (thisStrip == (centerStrip + 1)) {
1980  std::vector<int> myADCVals = digiItr->getADCCounts();
1981  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1982  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1983  SigADC[1] = thisSignal - 6 * thisPedestal;
1984  }
1985  if (thisStrip == (centerStrip + 2)) {
1986  std::vector<int> myADCVals = digiItr->getADCCounts();
1987  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1988  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1989  SigADC[2] = thisSignal - 6 * thisPedestal;
1990  }
1991  if (thisStrip == (centerStrip - 1)) {
1992  std::vector<int> myADCVals = digiItr->getADCCounts();
1993  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1994  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1995  SigADC[3] = thisSignal - 6 * thisPedestal;
1996  }
1997  if (thisStrip == (centerStrip - 2)) {
1998  std::vector<int> myADCVals = digiItr->getADCCounts();
1999  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
2000  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
2001  SigADC[4] = thisSignal - 6 * thisPedestal;
2002  }
2003  }
2004  TotalADC = 0.2 * (SigADC[0] + SigADC[1] + SigADC[2] + SigADC[3] + SigADC[4]);
2005  }
2006  }
2007  return TotalADC;
2008 }
2009 
2010 //---------------------------------------------------------------------------------------
2011 // Look at non-associated recHits
2012 // Author: P. Jindal
2013 //---------------------------------------------------------------------------------------
2014 
2015 void CSCValidation::doNoiseHits(edm::Handle<CSCRecHit2DCollection> recHits,
2020  for (recIt = recHits->begin(); recIt != recHits->end(); recIt++) {
2021  CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
2022 
2023  //Store the Rechits into a Map
2024  AllRechits.insert(std::pair<CSCDetId, CSCRecHit2D>(idrec, *recIt));
2025 
2026  // Find the strip containing this hit
2027  int centerid = recIt->nStrips() / 2;
2028  int centerStrip = recIt->channels(centerid);
2029 
2030  float rHsignal = getthisSignal(*strips, idrec, centerStrip);
2031  histos->fill1DHist(
2032  rHsignal, "hrHSignal", "Signal in the 4th time bin for centre strip", 1100, -99, 1000, "recHits");
2033  }
2034 
2035  for (CSCSegmentCollection::const_iterator it = cscSegments->begin(); it != cscSegments->end(); it++) {
2036  std::vector<CSCRecHit2D> theseRecHits = (*it).specificRecHits();
2037  for (std::vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
2038  CSCDetId idRH = (CSCDetId)(*iRH).cscDetId();
2039  LocalPoint lpRH = (*iRH).localPosition();
2040  float xrec = lpRH.x();
2041  float yrec = lpRH.y();
2042  float zrec = lpRH.z();
2043  bool RHalreadyinMap = false;
2044  //Store the rechits associated with segments into a Map
2045  multimap<CSCDetId, CSCRecHit2D>::iterator segRHit;
2046  segRHit = SegRechits.find(idRH);
2047  if (segRHit != SegRechits.end()) {
2048  for (; segRHit != SegRechits.upper_bound(idRH); ++segRHit) {
2049  //for( segRHit = SegRechits.begin(); segRHit != SegRechits.end() ;++segRHit){
2050  LocalPoint lposRH = (segRHit->second).localPosition();
2051  float xpos = lposRH.x();
2052  float ypos = lposRH.y();
2053  float zpos = lposRH.z();
2054  if (xrec == xpos && yrec == ypos && zrec == zpos) {
2055  RHalreadyinMap = true;
2056  //std::cout << " Already exists " <<std ::endl;
2057  break;
2058  }
2059  }
2060  }
2061  if (!RHalreadyinMap) {
2062  SegRechits.insert(std::pair<CSCDetId, CSCRecHit2D>(idRH, *iRH));
2063  }
2064  }
2065  }
2066 
2067  findNonAssociatedRecHits(cscGeom, strips);
2068 }
2069 
2070 //---------------------------------------------------------------------------------------
2071 // Given the list of all rechits and the rechits on a segment finds the rechits
2072 // not associated to a segment and stores in a list
2073 //
2074 //---------------------------------------------------------------------------------------
2075 
2076 void CSCValidation::findNonAssociatedRecHits(edm::ESHandle<CSCGeometry> cscGeom,
2078  for (std::multimap<CSCDetId, CSCRecHit2D>::iterator allRHiter = AllRechits.begin(); allRHiter != AllRechits.end();
2079  ++allRHiter) {
2080  CSCDetId idRH = allRHiter->first;
2081  LocalPoint lpRH = (allRHiter->second).localPosition();
2082  float xrec = lpRH.x();
2083  float yrec = lpRH.y();
2084  float zrec = lpRH.z();
2085 
2086  bool foundmatch = false;
2087  multimap<CSCDetId, CSCRecHit2D>::iterator segRHit;
2088  segRHit = SegRechits.find(idRH);
2089  if (segRHit != SegRechits.end()) {
2090  for (; segRHit != SegRechits.upper_bound(idRH); ++segRHit) {
2091  LocalPoint lposRH = (segRHit->second).localPosition();
2092  float xpos = lposRH.x();
2093  float ypos = lposRH.y();
2094  float zpos = lposRH.z();
2095 
2096  if (xrec == xpos && yrec == ypos && zrec == zpos) {
2097  foundmatch = true;
2098  }
2099 
2100  float d = 0.;
2101  float dclose = 1000.;
2102 
2103  if (!foundmatch) {
2104  d = sqrt(pow(xrec - xpos, 2) + pow(yrec - ypos, 2) + pow(zrec - zpos, 2));
2105  if (d < dclose) {
2106  dclose = d;
2107  if (distRHmap.find((allRHiter->second)) ==
2108  distRHmap.end()) { // entry for rechit does not yet exist, create one
2109  distRHmap.insert(make_pair(allRHiter->second, dclose));
2110  } else {
2111  // we already have an entry for the detid.
2112  distRHmap.erase(allRHiter->second);
2113  distRHmap.insert(
2114  make_pair(allRHiter->second, dclose)); // fill rechits for the segment with the given detid
2115  }
2116  }
2117  }
2118  }
2119  }
2120  if (!foundmatch) {
2121  NonAssociatedRechits.insert(std::pair<CSCDetId, CSCRecHit2D>(idRH, allRHiter->second));
2122  }
2123  }
2124 
2125  for (std::map<CSCRecHit2D, float, ltrh>::iterator iter = distRHmap.begin(); iter != distRHmap.end(); ++iter) {
2126  histos->fill1DHist(iter->second,
2127  "hdistRH",
2128  "Distance of Non Associated RecHit from closest Segment RecHit",
2129  500,
2130  0.,
2131  100.,
2132  "NonAssociatedRechits");
2133  }
2134 
2135  for (std::multimap<CSCDetId, CSCRecHit2D>::iterator iter = NonAssociatedRechits.begin();
2136  iter != NonAssociatedRechits.end();
2137  ++iter) {
2138  CSCDetId idrec = iter->first;
2139  int kEndcap = idrec.endcap();
2140  int cEndcap = idrec.endcap();
2141  if (kEndcap == 2)
2142  cEndcap = -1;
2143  int kRing = idrec.ring();
2144  int kStation = idrec.station();
2145  int kChamber = idrec.chamber();
2146  int kLayer = idrec.layer();
2147 
2148  // Store rechit as a Local Point:
2149  LocalPoint rhitlocal = (iter->second).localPosition();
2150  float xreco = rhitlocal.x();
2151  float yreco = rhitlocal.y();
2152 
2153  // Find the strip containing this hit
2154  int centerid = (iter->second).nStrips() / 2;
2155  int centerStrip = (iter->second).channels(centerid);
2156 
2157  // Find the charge associated with this hit
2158  float rHSumQ = 0;
2159  float sumsides = 0.;
2160  int adcsize = (iter->second).nStrips() * (iter->second).nTimeBins();
2161  for (unsigned int i = 0; i < (iter->second).nStrips(); i++) {
2162  for (unsigned int j = 0; j < (iter->second).nTimeBins() - 1; j++) {
2163  rHSumQ += (iter->second).adcs(i, j);
2164  if (i != 1)
2165  sumsides += (iter->second).adcs(i, j);
2166  }
2167  }
2168 
2169  float rHratioQ = sumsides / rHSumQ;
2170  if (adcsize != 12)
2171  rHratioQ = -99;
2172 
2173  // Get the signal timing of this hit
2174  float rHtime = (iter->second).tpeak() / 50;
2175 
2176  // Get the width of this hit
2177  int rHwidth = getWidth(*strips, idrec, centerStrip);
2178 
2179  // Get pointer to the layer:
2180  const CSCLayer* csclayer = cscGeom->layer(idrec);
2181 
2182  // Transform hit position from local chamber geometry to global CMS geom
2183  GlobalPoint rhitglobal = csclayer->toGlobal(rhitlocal);
2184  float grecx = rhitglobal.x();
2185  float grecy = rhitglobal.y();
2186 
2187  // Simple occupancy variables
2188  int kCodeBroad = cEndcap * (4 * (kStation - 1) + kRing);
2189  int kCodeNarrow = cEndcap * (100 * (kRing - 1) + kChamber);
2190 
2191  //Fill the non-associated rechits parameters in histogram
2192  histos->fill1DHist(
2193  kCodeBroad, "hNARHCodeBroad", "broad scope code for recHits", 33, -16.5, 16.5, "NonAssociatedRechits");
2194  if (kStation == 1)
2195  histos->fill1DHist(kCodeNarrow,
2196  "hNARHCodeNarrow1",
2197  "narrow scope recHit code station 1",
2198  801,
2199  -400.5,
2200  400.5,
2201  "NonAssociatedRechits");
2202  if (kStation == 2)
2203  histos->fill1DHist(kCodeNarrow,
2204  "hNARHCodeNarrow2",
2205  "narrow scope recHit code station 2",
2206  801,
2207  -400.5,
2208  400.5,
2209  "NonAssociatedRechits");
2210  if (kStation == 3)
2211  histos->fill1DHist(kCodeNarrow,
2212  "hNARHCodeNarrow3",
2213  "narrow scope recHit code station 3",
2214  801,
2215  -400.5,
2216  400.5,
2217  "NonAssociatedRechits");
2218  if (kStation == 4)
2219  histos->fill1DHist(kCodeNarrow,
2220  "hNARHCodeNarrow4",
2221  "narrow scope recHit code station 4",
2222  801,
2223  -400.5,
2224  400.5,
2225  "NonAssociatedRechits");
2226  histos->fill1DHistByType(kLayer, "hNARHLayer", "RecHits per Layer", idrec, 8, -0.5, 7.5, "NonAssociatedRechits");
2227  histos->fill1DHistByType(xreco, "hNARHX", "Local X of recHit", idrec, 160, -80., 80., "NonAssociatedRechits");
2228  histos->fill1DHistByType(yreco, "hNARHY", "Local Y of recHit", idrec, 60, -180., 180., "NonAssociatedRechits");
2229  if (kStation == 1 && (kRing == 1 || kRing == 4))
2230  histos->fill1DHistByType(
2231  rHSumQ, "hNARHSumQ", "Sum 3x3 recHit Charge", idrec, 250, 0, 4000, "NonAssociatedRechits");
2232  else
2233  histos->fill1DHistByType(
2234  rHSumQ, "hNARHSumQ", "Sum 3x3 recHit Charge", idrec, 250, 0, 2000, "NonAssociatedRechits");
2235  histos->fill1DHistByType(
2236  rHratioQ, "hNARHRatioQ", "Ratio (Ql+Qr)/Qt)", idrec, 120, -0.1, 1.1, "NonAssociatedRechits");
2237  histos->fill1DHistByType(rHtime, "hNARHTiming", "recHit Timing", idrec, 200, -10, 10, "NonAssociatedRechits");
2238  histos->fill2DHistByStation(grecx,
2239  grecy,
2240  "hNARHGlobal",
2241  "recHit Global Position",
2242  idrec,
2243  400,
2244  -800.,
2245  800.,
2246  400,
2247  -800.,
2248  800.,
2249  "NonAssociatedRechits");
2250  histos->fill1DHistByType(
2251  rHwidth, "hNARHwidth", "width for Non associated recHit", idrec, 21, -0.5, 20.5, "NonAssociatedRechits");
2252  }
2253 
2254  for (std::multimap<CSCDetId, CSCRecHit2D>::iterator iter = SegRechits.begin(); iter != SegRechits.end(); ++iter) {
2255  CSCDetId idrec = iter->first;
2256  int kEndcap = idrec.endcap();
2257  int cEndcap = idrec.endcap();
2258  if (kEndcap == 2)
2259  cEndcap = -1;
2260  int kRing = idrec.ring();
2261  int kStation = idrec.station();
2262  int kChamber = idrec.chamber();
2263  int kLayer = idrec.layer();
2264 
2265  // Store rechit as a Local Point:
2266  LocalPoint rhitlocal = (iter->second).localPosition();
2267  float xreco = rhitlocal.x();
2268  float yreco = rhitlocal.y();
2269 
2270  // Find the strip containing this hit
2271  int centerid = (iter->second).nStrips() / 2;
2272  int centerStrip = (iter->second).channels(centerid);
2273 
2274  // Find the charge associated with this hit
2275 
2276  float rHSumQ = 0;
2277  float sumsides = 0.;
2278  int adcsize = (iter->second).nStrips() * (iter->second).nTimeBins();
2279  for (unsigned int i = 0; i < (iter->second).nStrips(); i++) {
2280  for (unsigned int j = 0; j < (iter->second).nTimeBins() - 1; j++) {
2281  rHSumQ += (iter->second).adcs(i, j);
2282  if (i != 1)
2283  sumsides += (iter->second).adcs(i, j);
2284  }
2285  }
2286 
2287  float rHratioQ = sumsides / rHSumQ;
2288  if (adcsize != 12)
2289  rHratioQ = -99;
2290 
2291  // Get the signal timing of this hit
2292  float rHtime = (iter->second).tpeak() / 50;
2293 
2294  // Get the width of this hit
2295  int rHwidth = getWidth(*strips, idrec, centerStrip);
2296 
2297  // Get pointer to the layer:
2298  const CSCLayer* csclayer = cscGeom->layer(idrec);
2299 
2300  // Transform hit position from local chamber geometry to global CMS geom
2301  GlobalPoint rhitglobal = csclayer->toGlobal(rhitlocal);
2302  float grecx = rhitglobal.x();
2303  float grecy = rhitglobal.y();
2304 
2305  // Simple occupancy variables
2306  int kCodeBroad = cEndcap * (4 * (kStation - 1) + kRing);
2307  int kCodeNarrow = cEndcap * (100 * (kRing - 1) + kChamber);
2308 
2309  //Fill the non-associated rechits global position in histogram
2310  histos->fill1DHist(
2311  kCodeBroad, "hSegRHCodeBroad", "broad scope code for recHits", 33, -16.5, 16.5, "AssociatedRechits");
2312  if (kStation == 1)
2313  histos->fill1DHist(kCodeNarrow,
2314  "hSegRHCodeNarrow1",
2315  "narrow scope recHit code station 1",
2316  801,
2317  -400.5,
2318  400.5,
2319  "AssociatedRechits");
2320  if (kStation == 2)
2321  histos->fill1DHist(kCodeNarrow,
2322  "hSegRHCodeNarrow2",
2323  "narrow scope recHit code station 2",
2324  801,
2325  -400.5,
2326  400.5,
2327  "AssociatedRechits");
2328  if (kStation == 3)
2329  histos->fill1DHist(kCodeNarrow,
2330  "hSegRHCodeNarrow3",
2331  "narrow scope recHit code station 3",
2332  801,
2333  -400.5,
2334  400.5,
2335  "AssociatedRechits");
2336  if (kStation == 4)
2337  histos->fill1DHist(kCodeNarrow,
2338  "hSegRHCodeNarrow4",
2339  "narrow scope recHit code station 4",
2340  801,
2341  -400.5,
2342  400.5,
2343  "AssociatedRechits");
2344  histos->fill1DHistByType(kLayer, "hSegRHLayer", "RecHits per Layer", idrec, 8, -0.5, 7.5, "AssociatedRechits");
2345  histos->fill1DHistByType(xreco, "hSegRHX", "Local X of recHit", idrec, 160, -80., 80., "AssociatedRechits");
2346  histos->fill1DHistByType(yreco, "hSegRHY", "Local Y of recHit", idrec, 60, -180., 180., "AssociatedRechits");
2347  if (kStation == 1 && (kRing == 1 || kRing == 4))
2348  histos->fill1DHistByType(rHSumQ, "hSegRHSumQ", "Sum 3x3 recHit Charge", idrec, 250, 0, 4000, "AssociatedRechits");
2349  else
2350  histos->fill1DHistByType(rHSumQ, "hSegRHSumQ", "Sum 3x3 recHit Charge", idrec, 250, 0, 2000, "AssociatedRechits");
2351  histos->fill1DHistByType(rHratioQ, "hSegRHRatioQ", "Ratio (Ql+Qr)/Qt)", idrec, 120, -0.1, 1.1, "AssociatedRechits");
2352  histos->fill1DHistByType(rHtime, "hSegRHTiming", "recHit Timing", idrec, 200, -10, 10, "AssociatedRechits");
2353  histos->fill2DHistByStation(grecx,
2354  grecy,
2355  "hSegRHGlobal",
2356  "recHit Global Position",
2357  idrec,
2358  400,
2359  -800.,
2360  800.,
2361  400,
2362  -800.,
2363  800.,
2364  "AssociatedRechits");
2365  histos->fill1DHistByType(
2366  rHwidth, "hSegRHwidth", "width for Non associated recHit", idrec, 21, -0.5, 20.5, "AssociatedRechits");
2367  }
2368 
2369  distRHmap.clear();
2370  AllRechits.clear();
2371  SegRechits.clear();
2372  NonAssociatedRechits.clear();
2373 }
2374 
2375 float CSCValidation::getthisSignal(const CSCStripDigiCollection& stripdigis, CSCDetId idRH, int centerStrip) {
2376  // Loop over strip digis responsible for this recHit
2378  float thisADC = 0.;
2379  //bool foundRHid = false;
2380  // std::cout<<"iD S/R/C/L = "<<idRH<<" "<<idRH.station()<<"/"<<idRH.ring()<<"/"<<idRH.chamber()<<"/"<<idRH.layer()<<std::endl;
2381  for (sIt = stripdigis.begin(); sIt != stripdigis.end(); sIt++) {
2382  CSCDetId id = (CSCDetId)(*sIt).first;
2383  //std::cout<<"STRIPS: id S/R/C/L = "<<id<<" "<<id.station()<<"/"<<id.ring()<<"/"<<id.chamber()<<"/"<<id.layer()<<std::endl;
2384  if (id == idRH) {
2385  //foundRHid = true;
2386  vector<CSCStripDigi>::const_iterator digiItr = (*sIt).second.first;
2387  vector<CSCStripDigi>::const_iterator last = (*sIt).second.second;
2388  //if(digiItr == last ) {std::cout << " Attention1 :: Size of digi collection is zero " << std::endl;}
2389  int St = idRH.station();
2390  int Rg = idRH.ring();
2391  if (St == 1 && Rg == 4) {
2392  while (centerStrip > 16)
2393  centerStrip -= 16;
2394  }
2395  for (; digiItr != last; ++digiItr) {
2396  int thisStrip = digiItr->getStrip();
2397  //std::cout<<" thisStrip = "<<thisStrip<<" centerStrip = "<<centerStrip<<std::endl;
2398  std::vector<int> myADCVals = digiItr->getADCCounts();
2399  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
2400  float Signal = (float)myADCVals[3];
2401  if (thisStrip == (centerStrip)) {
2402  thisADC = Signal - thisPedestal;
2403  //if(thisADC >= 0. && thisADC <2.) {std::cout << " Attention2 :: The Signal is equal to the pedestal " << std::endl;
2404  //}
2405  //if(thisADC < 0.) {std::cout << " Attention3 :: The Signal is less than the pedestal " << std::endl;
2406  //}
2407  }
2408  if (thisStrip == (centerStrip + 1)) {
2409  std::vector<int> myADCVals = digiItr->getADCCounts();
2410  }
2411  if (thisStrip == (centerStrip - 1)) {
2412  std::vector<int> myADCVals = digiItr->getADCCounts();
2413  }
2414  }
2415  }
2416  }
2417  //if(!foundRHid){std::cout << " Attention4 :: Did not find a matching RH id in the Strip Digi collection " << std::endl;}
2418  return thisADC;
2419 }
2420 
2421 //---------------------------------------------------------------------------------------
2422 //
2423 // Function is meant to take the DetId and center strip number of a recHit and return
2424 // the width in terms of strips
2425 //---------------------------------------------------------------------------------------
2426 
2427 int CSCValidation::getWidth(const CSCStripDigiCollection& stripdigis, CSCDetId idRH, int centerStrip) {
2428  int width = 1;
2429  int widthpos = 0;
2430  int widthneg = 0;
2431 
2432  // Loop over strip digis responsible for this recHit and sum charge
2434 
2435  for (sIt = stripdigis.begin(); sIt != stripdigis.end(); sIt++) {
2436  CSCDetId id = (CSCDetId)(*sIt).first;
2437  if (id == idRH) {
2438  std::vector<CSCStripDigi>::const_iterator digiItr = (*sIt).second.first;
2439  std::vector<CSCStripDigi>::const_iterator first = (*sIt).second.first;
2440  std::vector<CSCStripDigi>::const_iterator last = (*sIt).second.second;
2441  std::vector<CSCStripDigi>::const_iterator it = (*sIt).second.first;
2442  std::vector<CSCStripDigi>::const_iterator itr = (*sIt).second.first;
2443  //std::cout << " IDRH " << id <<std::endl;
2444  int St = idRH.station();
2445  int Rg = idRH.ring();
2446  if (St == 1 && Rg == 4) {
2447  while (centerStrip > 16)
2448  centerStrip -= 16;
2449  }
2450  for (; digiItr != last; ++digiItr) {
2451  int thisStrip = digiItr->getStrip();
2452  if (thisStrip == (centerStrip)) {
2453  it = digiItr;
2454  for (; it != last; ++it) {
2455  int strip = it->getStrip();
2456  std::vector<int> myADCVals = it->getADCCounts();
2457  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
2458  if (((float)myADCVals[3] - thisPedestal) < 6 || widthpos == 10 || it == last) {
2459  break;
2460  }
2461  if (strip != centerStrip) {
2462  widthpos += 1;
2463  }
2464  }
2465  itr = digiItr;
2466  for (; itr != first; --itr) {
2467  int strip = itr->getStrip();
2468  std::vector<int> myADCVals = itr->getADCCounts();
2469  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
2470  if (((float)myADCVals[3] - thisPedestal) < 6 || widthneg == 10 || itr == first) {
2471  break;
2472  }
2473  if (strip != centerStrip) {
2474  widthneg += 1;
2475  }
2476  }
2477  }
2478  }
2479  }
2480  }
2481  //std::cout << "Widthneg - " << widthneg << "Widthpos + " << widthpos << std::endl;
2482  width = width + widthneg + widthpos;
2483  //std::cout << "Width " << width << std::endl;
2484  return width;
2485 }
2486 
2487 //---------------------------------------------------------------------------
2488 // Module for looking at gas gains
2489 // Author N. Terentiev
2490 //---------------------------------------------------------------------------
2491 
2492 void CSCValidation::doGasGain(const CSCWireDigiCollection& wirecltn,
2493  const CSCStripDigiCollection& strpcltn,
2494  const CSCRecHit2DCollection& rechitcltn) {
2495  int channel = 0, mult, wire, layer, idlayer, idchamber, ring;
2496  int wire_strip_rechit_present;
2497  std::string name, title, endcapstr;
2498  ostringstream ss;
2499  CSCIndexer indexer;
2500  std::map<int, int>::iterator intIt;
2501 
2502  m_single_wire_layer.clear();
2503 
2504  if (firstEvent) {
2505  // HV segments, their # and location in terms of wire groups
2506 
2507  m_wire_hvsegm.clear();
2508  std::map<int, std::vector<int> >::iterator intvecIt;
2509  // ME1a ME1b ME1/2 ME1/3 ME2/1 ME2/2 ME3/1 ME3/2 ME4/1 ME4/2
2510  int csctype[10] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10};
2511  int hvsegm_layer[10] = {1, 1, 3, 3, 3, 5, 3, 5, 3, 5};
2512  int id;
2513  nmbhvsegm.clear();
2514  for (int i = 0; i < 10; i++)
2515  nmbhvsegm.push_back(hvsegm_layer[i]);
2516  // For ME1/1a
2517  std::vector<int> zer_1_1a(49, 0);
2518  id = csctype[0];
2519  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2520  m_wire_hvsegm[id] = zer_1_1a;
2521  intvecIt = m_wire_hvsegm.find(id);
2522  for (int wire = 1; wire <= 48; wire++)
2523  intvecIt->second[wire] = 1; // Segment 1
2524 
2525  // For ME1/1b
2526  std::vector<int> zer_1_1b(49, 0);
2527  id = csctype[1];
2528  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2529  m_wire_hvsegm[id] = zer_1_1b;
2530  intvecIt = m_wire_hvsegm.find(id);
2531  for (int wire = 1; wire <= 48; wire++)
2532  intvecIt->second[wire] = 1; // Segment 1
2533 
2534  // For ME1/2
2535  std::vector<int> zer_1_2(65, 0);
2536  id = csctype[2];
2537  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2538  m_wire_hvsegm[id] = zer_1_2;
2539  intvecIt = m_wire_hvsegm.find(id);
2540  for (int wire = 1; wire <= 24; wire++)
2541  intvecIt->second[wire] = 1; // Segment 1
2542  for (int wire = 25; wire <= 48; wire++)
2543  intvecIt->second[wire] = 2; // Segment 2
2544  for (int wire = 49; wire <= 64; wire++)
2545  intvecIt->second[wire] = 3; // Segment 3
2546 
2547  // For ME1/3
2548  std::vector<int> zer_1_3(33, 0);
2549  id = csctype[3];
2550  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2551  m_wire_hvsegm[id] = zer_1_3;
2552  intvecIt = m_wire_hvsegm.find(id);
2553  for (int wire = 1; wire <= 12; wire++)
2554  intvecIt->second[wire] = 1; // Segment 1
2555  for (int wire = 13; wire <= 22; wire++)
2556  intvecIt->second[wire] = 2; // Segment 2
2557  for (int wire = 23; wire <= 32; wire++)
2558  intvecIt->second[wire] = 3; // Segment 3
2559 
2560  // For ME2/1
2561  std::vector<int> zer_2_1(113, 0);
2562  id = csctype[4];
2563  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2564  m_wire_hvsegm[id] = zer_2_1;
2565  intvecIt = m_wire_hvsegm.find(id);
2566  for (int wire = 1; wire <= 44; wire++)
2567  intvecIt->second[wire] = 1; // Segment 1
2568  for (int wire = 45; wire <= 80; wire++)
2569  intvecIt->second[wire] = 2; // Segment 2
2570  for (int wire = 81; wire <= 112; wire++)
2571  intvecIt->second[wire] = 3; // Segment 3
2572 
2573  // For ME2/2
2574  std::vector<int> zer_2_2(65, 0);
2575  id = csctype[5];
2576  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2577  m_wire_hvsegm[id] = zer_2_2;
2578  intvecIt = m_wire_hvsegm.find(id);
2579  for (int wire = 1; wire <= 16; wire++)
2580  intvecIt->second[wire] = 1; // Segment 1
2581  for (int wire = 17; wire <= 28; wire++)
2582  intvecIt->second[wire] = 2; // Segment 2
2583  for (int wire = 29; wire <= 40; wire++)
2584  intvecIt->second[wire] = 3; // Segment 3
2585  for (int wire = 41; wire <= 52; wire++)
2586  intvecIt->second[wire] = 4; // Segment 4
2587  for (int wire = 53; wire <= 64; wire++)
2588  intvecIt->second[wire] = 5; // Segment 5
2589 
2590  // For ME3/1
2591  std::vector<int> zer_3_1(97, 0);
2592  id = csctype[6];
2593  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2594  m_wire_hvsegm[id] = zer_3_1;
2595  intvecIt = m_wire_hvsegm.find(id);
2596  for (int wire = 1; wire <= 32; wire++)
2597  intvecIt->second[wire] = 1; // Segment 1
2598  for (int wire = 33; wire <= 64; wire++)
2599  intvecIt->second[wire] = 2; // Segment 2
2600  for (int wire = 65; wire <= 96; wire++)
2601  intvecIt->second[wire] = 3; // Segment 3
2602 
2603  // For ME3/2
2604  std::vector<int> zer_3_2(65, 0);
2605  id = csctype[7];
2606  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2607  m_wire_hvsegm[id] = zer_3_2;
2608  intvecIt = m_wire_hvsegm.find(id);
2609  for (int wire = 1; wire <= 16; wire++)
2610  intvecIt->second[wire] = 1; // Segment 1
2611  for (int wire = 17; wire <= 28; wire++)
2612  intvecIt->second[wire] = 2; // Segment 2
2613  for (int wire = 29; wire <= 40; wire++)
2614  intvecIt->second[wire] = 3; // Segment 3
2615  for (int wire = 41; wire <= 52; wire++)
2616  intvecIt->second[wire] = 4; // Segment 4
2617  for (int wire = 53; wire <= 64; wire++)
2618  intvecIt->second[wire] = 5; // Segment 5
2619 
2620  // For ME4/1
2621  std::vector<int> zer_4_1(97, 0);
2622  id = csctype[8];
2623  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2624  m_wire_hvsegm[id] = zer_4_1;
2625  intvecIt = m_wire_hvsegm.find(id);
2626  for (int wire = 1; wire <= 32; wire++)
2627  intvecIt->second[wire] = 1; // Segment 1
2628  for (int wire = 33; wire <= 64; wire++)
2629  intvecIt->second[wire] = 2; // Segment 2
2630  for (int wire = 65; wire <= 96; wire++)
2631  intvecIt->second[wire] = 3; // Segment 3
2632 
2633  // For ME4/2
2634  std::vector<int> zer_4_2(65, 0);
2635  id = csctype[9];
2636  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2637  m_wire_hvsegm[id] = zer_4_2;
2638  intvecIt = m_wire_hvsegm.find(id);
2639  for (int wire = 1; wire <= 16; wire++)
2640  intvecIt->second[wire] = 1; // Segment 1
2641  for (int wire = 17; wire <= 28; wire++)
2642  intvecIt->second[wire] = 2; // Segment 2
2643  for (int wire = 29; wire <= 40; wire++)
2644  intvecIt->second[wire] = 3; // Segment 3
2645  for (int wire = 41; wire <= 52; wire++)
2646  intvecIt->second[wire] = 4; // Segment 4
2647  for (int wire = 53; wire <= 64; wire++)
2648  intvecIt->second[wire] = 5; // Segment 5
2649 
2650  } // end of if(nEventsAnalyzed==1)
2651 
2652  // do wires, strips and rechits present?
2653  wire_strip_rechit_present = 0;
2654  if (wirecltn.begin() != wirecltn.end())
2655  wire_strip_rechit_present = wire_strip_rechit_present + 1;
2656  if (strpcltn.begin() != strpcltn.end())
2657  wire_strip_rechit_present = wire_strip_rechit_present + 2;
2658  if (rechitcltn.begin() != rechitcltn.end())
2659  wire_strip_rechit_present = wire_strip_rechit_present + 4;
2660 
2661  if (wire_strip_rechit_present == 7) {
2662  // std::cout<<"Event "<<nEventsAnalyzed<<std::endl;
2663  // std::cout<<std::endl;
2664 
2665  // cycle on wire collection for all CSC to select single wire hit layers
2667 
2668  for (wiredetUnitIt = wirecltn.begin(); wiredetUnitIt != wirecltn.end(); ++wiredetUnitIt) {
2669  const CSCDetId id = (*wiredetUnitIt).first;
2670  idlayer = indexer.dbIndex(id, channel);
2671  // looping in the layer of given CSC
2672  mult = 0;
2673  wire = 0;
2674  const CSCWireDigiCollection::Range& range = (*wiredetUnitIt).second;
2675  for (CSCWireDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
2676  wire = (*digiIt).getWireGroup();
2677  mult++;
2678  } // end of digis loop in layer
2679 
2680  // select layers with single wire hit
2681  if (mult == 1) {
2682  if (m_single_wire_layer.find(idlayer) == m_single_wire_layer.end())
2683  m_single_wire_layer[idlayer] = wire;
2684  } // end of if(mult==1)
2685  } // end of cycle on detUnit
2686 
2687  // Looping thru rechit collection
2690 
2691  for (recIt = rechitcltn.begin(); recIt != rechitcltn.end(); ++recIt) {
2692  CSCDetId id = (CSCDetId)(*recIt).cscDetId();
2693  idlayer = indexer.dbIndex(id, channel);
2694  idchamber = idlayer / 10;
2695  layer = id.layer();
2696  // select layer with single wire rechit
2697  if (m_single_wire_layer.find(idlayer) != m_single_wire_layer.end()) {
2698  if (recIt->nStrips() == 3) {
2699  // get 3X3 ADC Sum
2700  unsigned int binmx = 0;
2701  float adcmax = 0.0;
2702 
2703  for (unsigned int i = 0; i < recIt->nStrips(); i++)
2704  for (unsigned int j = 0; j < recIt->nTimeBins(); j++)
2705  if (recIt->adcs(i, j) > adcmax) {
2706  adcmax = recIt->adcs(i, j);
2707  binmx = j;
2708  }
2709 
2710  float adc_3_3_sum = 0.0;
2711  //well, this really only works for 3 strips in readout - not sure the right fix for general case
2712  for (unsigned int i = 0; i < recIt->nStrips(); i++)
2713  for (unsigned int j = binmx - 1; j <= binmx + 1; j++)
2714  adc_3_3_sum += recIt->adcs(i, j);
2715 
2716  if (adc_3_3_sum > 0.0 && adc_3_3_sum < 2000.0) {
2717  // temporary fix for ME1/1a to avoid triple entries
2718  int flag = 0;
2719  if (id.station() == 1 && id.ring() == 4 && recIt->channels(1) > 16)
2720  flag = 1;
2721  // end of temporary fix
2722  if (flag == 0) {
2723  wire = m_single_wire_layer[idlayer];
2724  int chambertype = id.iChamberType(id.station(), id.ring());
2725  int hvsgmtnmb = m_wire_hvsegm[chambertype][wire];
2726  int nmbofhvsegm = nmbhvsegm[chambertype - 1];
2727  int location = (layer - 1) * nmbofhvsegm + hvsgmtnmb;
2728 
2729  ss << "gas_gain_rechit_adc_3_3_sum_location_ME_" << idchamber;
2730  name = ss.str();
2731  ss.str("");
2732  if (id.endcap() == 1)
2733  endcapstr = "+";
2734  ring = id.ring();
2735  if (id.station() == 1 && id.ring() == 4)
2736  ring = 1;
2737  if (id.endcap() == 2)
2738  endcapstr = "-";
2739  ss << "Gas Gain Rechit ADC3X3 Sum ME" << endcapstr << id.station() << "/" << ring << "/" << id.chamber();
2740  title = ss.str();
2741  ss.str("");
2742  float x = location;
2743  float y = adc_3_3_sum;
2744  histos->fill2DHist(x, y, name, title, 30, 1.0, 31.0, 50, 0.0, 2000.0, "GasGain");
2745 
2746  /*
2747  std::cout<<idchamber<<" "<<id.station()<<" "<<id.ring()<<" "
2748  <<id.chamber()<<" "<<layer<<" "<< wire<<" "<<m_strip[1]<<" "<<
2749  chambertype<<" "<< hvsgmtnmb<<" "<< nmbofhvsegm<<" "<<
2750  location<<" "<<adc_3_3_sum<<std::endl;
2751  */
2752  } // end of if flag==0
2753  } // end if(adcsum>0.0 && adcsum<2000.0)
2754  } // end of if if(m_strip.size()==3
2755  } // end of if single wire
2756  } // end of looping thru rechit collection
2757  } // end of if wire and strip and rechit present
2758 }
2759 
2760 //---------------------------------------------------------------------------
2761 // Module for looking at AFEB Timing
2762 // Author N. Terentiev
2763 //---------------------------------------------------------------------------
2764 
2765 void CSCValidation::doAFEBTiming(const CSCWireDigiCollection& wirecltn) {
2766  ostringstream ss;
2767  std::string name, title, endcapstr;
2768  float x, y;
2769  int wire, wiretbin, nmbwiretbin, layer, afeb, idlayer, idchamber;
2770  int channel = 0; // for CSCIndexer::dbIndex(id, channel); irrelevant here
2771  CSCIndexer indexer;
2772 
2773  if (wirecltn.begin() != wirecltn.end()) {
2774  //std::cout<<std::endl;
2775  //std::cout<<"Event "<<nEventsAnalyzed<<std::endl;
2776  //std::cout<<std::endl;
2777 
2778  // cycle on wire collection for all CSC
2780  for (wiredetUnitIt = wirecltn.begin(); wiredetUnitIt != wirecltn.end(); ++wiredetUnitIt) {
2781  const CSCDetId id = (*wiredetUnitIt).first;
2782  idlayer = indexer.dbIndex(id, channel);
2783  idchamber = idlayer / 10;
2784  layer = id.layer();
2785 
2786  if (id.endcap() == 1)
2787  endcapstr = "+";
2788  if (id.endcap() == 2)
2789  endcapstr = "-";
2790 
2791  // looping in the layer of given CSC
2792 
2793  const CSCWireDigiCollection::Range& range = (*wiredetUnitIt).second;
2794  for (CSCWireDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
2795  wire = (*digiIt).getWireGroup();
2796  wiretbin = (*digiIt).getTimeBin();
2797  nmbwiretbin = (*digiIt).getTimeBinsOn().size();
2798  afeb = 3 * ((wire - 1) / 8) + (layer + 1) / 2;
2799 
2800  // Anode wire group time bin vs afeb for each CSC
2801  x = afeb;
2802  y = wiretbin;
2803  ss << "afeb_time_bin_vs_afeb_occupancy_ME_" << idchamber;
2804  name = ss.str();
2805  ss.str("");
2806  ss << "Time Bin vs AFEB Occupancy ME" << endcapstr << id.station() << "/" << id.ring() << "/" << id.chamber();
2807  title = ss.str();
2808  ss.str("");
2809  histos->fill2DHist(x, y, name, title, 42, 1., 43., 16, 0., 16., "AFEBTiming");
2810 
2811  // Number of anode wire group time bin vs afeb for each CSC
2812  x = afeb;
2813  y = nmbwiretbin;
2814  ss << "nmb_afeb_time_bins_vs_afeb_ME_" << idchamber;
2815  name = ss.str();
2816  ss.str("");
2817  ss << "Number of Time Bins vs AFEB ME" << endcapstr << id.station() << "/" << id.ring() << "/" << id.chamber();
2818  title = ss.str();
2819  ss.str("");
2820  histos->fill2DHist(x, y, name, title, 42, 1., 43., 16, 0., 16., "AFEBTiming");
2821 
2822  } // end of digis loop in layer
2823  } // end of wire collection loop
2824  } // end of if(wirecltn.begin() != wirecltn.end())
2825 }
2826 
2827 //---------------------------------------------------------------------------
2828 // Module for looking at Comparator Timing
2829 // Author N. Terentiev
2830 //---------------------------------------------------------------------------
2831 
2832 void CSCValidation::doCompTiming(const CSCComparatorDigiCollection& compars) {
2833  ostringstream ss;
2835  float x, y;
2836  int strip, tbin, cfeb, idlayer, idchamber;
2837  int channel = 0; // for CSCIndexer::dbIndex(id, channel); irrelevant here
2838  CSCIndexer indexer;
2839 
2840  if (compars.begin() != compars.end()) {
2841  //std::cout<<std::endl;
2842  //std::cout<<"Event "<<nEventsAnalyzed<<std::endl;
2843  //std::cout<<std::endl;
2844 
2845  // cycle on comparators collection for all CSC
2847  for (compdetUnitIt = compars.begin(); compdetUnitIt != compars.end(); ++compdetUnitIt) {
2848  const CSCDetId id = (*compdetUnitIt).first;
2849  idlayer = indexer.dbIndex(id, channel); // channel irrelevant here
2850  idchamber = idlayer / 10;
2851 
2852  if (id.endcap() == 1)
2853  endcap = "+";
2854  if (id.endcap() == 2)
2855  endcap = "-";
2856  // looping in the layer of given CSC
2857  const CSCComparatorDigiCollection::Range& range = (*compdetUnitIt).second;
2858  for (CSCComparatorDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
2859  strip = (*digiIt).getStrip();
2860  /*
2861  if(id.station()==1 && (id.ring()==1 || id.ring()==4))
2862  std::cout<<idchamber<<" "<<id.station()<<" "<<id.ring()<<" "
2863  <<strip <<std::endl;
2864  */
2865  indexer.dbIndex(id, strip); // strips 1-16 of ME1/1a
2866  // become strips 65-80 of ME1/1
2867  tbin = (*digiIt).getTimeBin();
2868  cfeb = (strip - 1) / 16 + 1;
2869 
2870  // time bin vs cfeb for each CSC
2871 
2872  x = cfeb;
2873  y = tbin;
2874  ss << "comp_time_bin_vs_cfeb_occupancy_ME_" << idchamber;
2875  name = ss.str();
2876  ss.str("");
2877  ss << "Comparator Time Bin vs CFEB Occupancy ME" << endcap << id.station() << "/" << id.ring() << "/"
2878  << id.chamber();
2879  title = ss.str();
2880  ss.str("");
2881  histos->fill2DHist(x, y, name, title, 5, 1., 6., 16, 0., 16., "CompTiming");
2882 
2883  } // end of digis loop in layer
2884  } // end of collection loop
2885  } // end of if(compars.begin() !=compars.end())
2886 }
2887 
2888 //---------------------------------------------------------------------------
2889 // Module for looking at Strip Timing
2890 // Author N. Terentiev
2891 //---------------------------------------------------------------------------
2892 
2893 void CSCValidation::doADCTiming(const CSCRecHit2DCollection& rechitcltn) {
2894  float adc_3_3_sum, adc_3_3_wtbin, x, y;
2895  int cfeb, idchamber, ring;
2896 
2897  std::string name, title, endcapstr;
2898  ostringstream ss;
2899  std::vector<float> zer(6, 0.0);
2900 
2901  CSCIndexer indexer;
2902  std::map<int, int>::iterator intIt;
2903 
2904  if (rechitcltn.begin() != rechitcltn.end()) {
2905  // std::cout<<"Event "<<nEventsAnalyzed <<std::endl;
2906 
2907  // Looping thru rechit collection
2910  for (recIt = rechitcltn.begin(); recIt != rechitcltn.end(); ++recIt) {
2911  CSCDetId id = (CSCDetId)(*recIt).cscDetId();
2912  // getting strips comprising rechit
2913  if (recIt->nStrips() == 3) {
2914  // get 3X3 ADC Sum
2915  // get 3X3 ADC Sum
2916  unsigned int binmx = 0;
2917  float adcmax = 0.0;
2918 
2919  for (unsigned int i = 0; i < recIt->nStrips(); i++)
2920  for (unsigned int j = 0; j < recIt->nTimeBins(); j++)
2921  if (recIt->adcs(i, j) > adcmax) {
2922  adcmax = recIt->adcs(i, j);
2923  binmx = j;
2924  }
2925 
2926  adc_3_3_sum = 0.0;
2927  //well, this really only works for 3 strips in readout - not sure the right fix for general case
2928  for (unsigned int i = 0; i < recIt->nStrips(); i++)
2929  for (unsigned int j = binmx - 1; j <= binmx + 1; j++)
2930  adc_3_3_sum += recIt->adcs(i, j);
2931 
2932  // ADC weighted time bin
2933  if (adc_3_3_sum > 100.0) {
2934  int centerStrip = recIt->channels(1); //take central from 3 strips;
2935  // temporary fix
2936  int flag = 0;
2937  if (id.station() == 1 && id.ring() == 4 && centerStrip > 16)
2938  flag = 1;
2939  // end of temporary fix
2940  if (flag == 0) {
2941  adc_3_3_wtbin = (*recIt).tpeak() / 50; //getTiming(strpcltn, id, centerStrip);
2942  idchamber = indexer.dbIndex(id, centerStrip) / 10; //strips 1-16 ME1/1a
2943  // become strips 65-80 ME1/1 !!!
2944  /*
2945  if(id.station()==1 && (id.ring()==1 || id.ring()==4))
2946  std::cout<<idchamber<<" "<<id.station()<<" "<<id.ring()<<" "<<m_strip[1]<<" "<<
2947  " "<<centerStrip<<
2948  " "<<adc_3_3_wtbin<<" "<<adc_3_3_sum<<std::endl;
2949  */
2950  ss << "adc_3_3_weight_time_bin_vs_cfeb_occupancy_ME_" << idchamber;
2951  name = ss.str();
2952  ss.str("");
2953 
2954  std::string endcapstr;
2955  if (id.endcap() == 1)
2956  endcapstr = "+";
2957  if (id.endcap() == 2)
2958  endcapstr = "-";
2959  ring = id.ring();
2960  if (id.ring() == 4)
2961  ring = 1;
2962  ss << "ADC 3X3 Weighted Time Bin vs CFEB Occupancy ME" << endcapstr << id.station() << "/" << ring << "/"
2963  << id.chamber();
2964  title = ss.str();
2965  ss.str("");
2966 
2967  cfeb = (centerStrip - 1) / 16 + 1;
2968  x = cfeb;
2969  y = adc_3_3_wtbin;
2970  histos->fill2DHist(x, y, name, title, 5, 1., 6., 80, -8., 8., "ADCTiming");
2971  } // end of if flag==0
2972  } // end of if (adc_3_3_sum > 100.0)
2973  } // end of if if(m_strip.size()==3
2974  } // end of the pass thru CSCRecHit2DCollection
2975  } // end of if (rechitcltn.begin() != rechitcltn.end())
2976 }
2977 
2978 //---------------------------------------------------------------------------------------
2979 // Construct histograms for monitoring the trigger and offline timing
2980 // Author: A. Deisher
2981 //---------------------------------------------------------------------------------------
2982 
2983 void CSCValidation::doTimeMonitoring(edm::Handle<CSCRecHit2DCollection> recHits,
2990  const edm::EventSetup& eventSetup,
2991  const edm::Event& event) {
2992  map<CSCDetId, float> segment_median_map; //structure for storing the median time for segments in a chamber
2993  map<CSCDetId, GlobalPoint> segment_position_map; //structure for storing the global position for segments in a chamber
2994 
2995  // -----------------------
2996  // loop over segments
2997  // -----------------------
2998  for (CSCSegmentCollection::const_iterator dSiter = cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
2999  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
3000  LocalPoint localPos = (*dSiter).localPosition();
3001  GlobalPoint globalPosition = GlobalPoint(0.0, 0.0, 0.0);
3002  const CSCChamber* cscchamber = cscGeom->chamber(id);
3003  if (cscchamber) {
3004  globalPosition = cscchamber->toGlobal(localPos);
3005  }
3006 
3007  // try to get the CSC recHits that contribute to this segment.
3008  std::vector<CSCRecHit2D> theseRecHits = (*dSiter).specificRecHits();
3009  int nRH = (*dSiter).nRecHits();
3010  if (nRH < 4)
3011  continue;
3012 
3013  //Store the recHit times of a segment in a vector for later sorting
3014  vector<float> non_zero;
3015 
3016  for (vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
3017  non_zero.push_back(iRH->tpeak());
3018 
3019  } // end rechit loop
3020 
3021  //Sort the vector of hit times for this segment and average the center two
3022  sort(non_zero.begin(), non_zero.end());
3023  int middle_index = non_zero.size() / 2;
3024  float average_two = (non_zero.at(middle_index - 1) + non_zero.at(middle_index)) / 2.;
3025  if (non_zero.size() % 2)
3026  average_two = non_zero.at(middle_index);
3027 
3028  //If we've vetoed events with multiple segments per chamber, this should never overwrite informations
3029  segment_median_map[id] = average_two;
3030  segment_position_map[id] = globalPosition;
3031 
3032  double distToIP = sqrt(globalPosition.x() * globalPosition.x() + globalPosition.y() * globalPosition.y() +
3033  globalPosition.z() * globalPosition.z());
3034 
3035  histos->fillProfile(chamberSerial(id),
3036  average_two,
3037  "timeChamber",
3038  "Segment mean time",
3039  601,
3040  -0.5,
3041  600.5,
3042  -400.,
3043  400.,
3044  "TimeMonitoring");
3045  histos->fillProfileByType(id.chamber(),
3046  average_two,
3047  "timeChamberByType",
3048  "Segment mean time by chamber",
3049  id,
3050  36,
3051  0.5,
3052  36.5,
3053  -400,
3054  400.,
3055  "TimeMonitoring");
3056  histos->fill2DHist(distToIP,
3057  average_two,
3058  "seg_time_vs_distToIP",
3059  "Segment time vs. Distance to IP",
3060  80,
3061  600.,
3062  1400.,
3063  800,
3064  -400,
3065  400.,
3066  "TimeMonitoring");
3067  histos->fill2DHist(globalPosition.z(),
3068  average_two,
3069  "seg_time_vs_globZ",
3070  "Segment time vs. z position",
3071  240,
3072  -1200,
3073  1200,
3074  800,
3075  -400.,
3076  400.,
3077  "TimeMonitoring");
3078  histos->fill2DHist(fabs(globalPosition.z()),
3079  average_two,
3080  "seg_time_vs_absglobZ",
3081  "Segment time vs. abs(z position)",
3082  120,
3083  0.,
3084  1200.,
3085  800,
3086  -400.,
3087  400.,
3088  "TimeMonitoring");
3089 
3090  } //end segment loop
3091 
3092  //Now that the information for each segment we're interest in is stored, it is time to go through the pairs and make plots
3093  map<CSCDetId, float>::const_iterator it_outer; //for the outer loop
3094  map<CSCDetId, float>::const_iterator it_inner; //for the nested inner loop
3095  for (it_outer = segment_median_map.begin(); it_outer != segment_median_map.end(); it_outer++) {
3096  CSCDetId id_outer = it_outer->first;
3097  float t_outer = it_outer->second;
3098 
3099  //begin the inner loop
3100  for (it_inner = segment_median_map.begin(); it_inner != segment_median_map.end(); it_inner++) {
3101  CSCDetId id_inner = it_inner->first;
3102  float t_inner = it_inner->second;
3103 
3104  // we're looking at ordered pairs, so combinations will be double counted
3105  // (chamber a, chamber b) will be counted as well as (chamber b, chamber a)
3106  // We will avoid (chamber a, chamber a) with the following line
3107  if (chamberSerial(id_outer) == chamberSerial(id_inner))
3108  continue;
3109 
3110  // Calculate expected TOF (in ns units)
3111  // GlobalPoint gp_outer = segment_position_map.find(id_outer)->second;
3112  // GlobalPoint gp_inner = segment_position_map.find(id_inner)->second;
3113  // GlobalVector flight = gp_outer - gp_inner; //in cm
3114  // float TOF = flight.mag()/30.0; //to ns
3115 
3116  //Plot t(ME+) - t(ME-) for chamber pairs in the same stations and rings but opposite endcaps
3117  if (id_outer.endcap() == 1 && id_inner.endcap() == 2 && id_outer.station() == id_inner.station() &&
3118  id_outer.ring() == id_inner.ring()) {
3119  histos->fill1DHist(t_outer - t_inner,
3120  "diff_opposite_endcaps",
3121  "#Delta t [ME+]-[ME-] for chambers in same station and ring",
3122  800,
3123  -400.,
3124  400.,
3125  "TimeMonitoring");
3126  histos->fill1DHistByType(t_outer - t_inner,
3127  "diff_opposite_endcaps_byType",
3128  "#Delta t [ME+]-[ME-] for chambers in same station and ring",
3129  id_outer,
3130  800,
3131  -400.,
3132  400.,
3133  "TimeMonitoring");
3134  }
3135 
3136  } //end inner loop of segment pairs
3137  } //end outer loop of segment pairs
3138 
3139  //if the digis, return here
3140  if (!useDigis)
3141  return;
3142 
3143  //looking for the global trigger number
3144  vector<L1MuGMTReadoutRecord> L1Mrec = pCollection->getRecords();
3145  vector<L1MuGMTReadoutRecord>::const_iterator igmtrr;
3146  int L1GMT_BXN = -100;
3147  bool has_CSCTrigger = false;
3148  bool has_beamHaloTrigger = false;
3149  for (igmtrr = L1Mrec.begin(); igmtrr != L1Mrec.end(); igmtrr++) {
3150  std::vector<L1MuRegionalCand>::const_iterator iter1;
3151  std::vector<L1MuRegionalCand> rmc;
3152  // CSC
3153  int icsc = 0;
3154  rmc = igmtrr->getCSCCands();
3155  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
3156  if (!(*iter1).empty()) {
3157  icsc++;
3158  int kQuality = (*iter1).quality(); // kQuality = 1 means beam halo
3159  if (kQuality == 1)
3160  has_beamHaloTrigger = true;
3161  }
3162  }
3163  if (igmtrr->getBxInEvent() == 0 && icsc > 0) {
3164  //printf("L1 CSCCands exist. L1MuGMTReadoutRecord BXN = %d \n", igmtrr->getBxNr());
3165  L1GMT_BXN = igmtrr->getBxNr();
3166  has_CSCTrigger = true;
3167  } else if (igmtrr->getBxInEvent() == 0) {
3168  //printf("L1 CSCCands do not exist. L1MuGMTReadoutRecord BXN = %d \n", igmtrr->getBxNr());
3169  L1GMT_BXN = igmtrr->getBxNr();
3170  }
3171  }
3172 
3173  // *************************************************
3174  // *** ALCT Digis **********************************
3175  // *************************************************
3176 
3177  int n_alcts = 0;
3178  map<CSCDetId, int> ALCT_KeyWG_map; //structure for storing the key wire group for the first ALCT for each chamber
3179  for (CSCALCTDigiCollection::DigiRangeIterator j = alcts->begin(); j != alcts->end(); j++) {
3180  const CSCALCTDigiCollection::Range& range = (*j).second;
3181  const CSCDetId& idALCT = (*j).first;
3182  for (CSCALCTDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
3183  // Valid digi in the chamber (or in neighbouring chamber)
3184  if ((*digiIt).isValid()) {
3185  n_alcts++;
3186  histos->fill1DHist((*digiIt).getBX(), "ALCT_getBX", "ALCT.getBX()", 11, -0.5, 10.5, "TimeMonitoring");
3187  histos->fill1DHist(
3188  (*digiIt).getFullBX(), "ALCT_getFullBX", "ALCT.getFullBX()", 3601, -0.5, 3600.5, "TimeMonitoring");
3189  //if we don't already have digi information stored for this chamber, then we fill it
3190  if (ALCT_KeyWG_map.find(idALCT.chamberId()) == ALCT_KeyWG_map.end()) {
3191  ALCT_KeyWG_map[idALCT.chamberId()] = (*digiIt).getKeyWG();
3192  //printf("I did fill ALCT info for Chamber %d %d %d %d \n",idALCT.chamberId().endcap(), idALCT.chamberId().station(), idALCT.chamberId().ring(), idALCT.chamberId().chamber());
3193  }
3194  }
3195  }
3196  }
3197 
3198  // *************************************************
3199  // *** CLCT Digis **********************************
3200  // *************************************************
3201  int n_clcts = 0;
3202  map<CSCDetId, int> CLCT_getFullBx_map; //structure for storing the pretrigger bxn for the first CLCT for each chamber
3203  for (CSCCLCTDigiCollection::DigiRangeIterator j = clcts->begin(); j != clcts->end(); j++) {
3204  const CSCCLCTDigiCollection::Range& range = (*j).second;
3205  const CSCDetId& idCLCT = (*j).first;
3206  for (CSCCLCTDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
3207  // Valid digi in the chamber (or in neighbouring chamber)
3208  if ((*digiIt).isValid()) {
3209  n_clcts++;
3210  histos->fill1DHist((*digiIt).getBX(), "CLCT_getBX", "CLCT.getBX()", 11, -0.5, 10.5, "TimeMonitoring");
3211  histos->fill1DHist(
3212  (*digiIt).getFullBX(), "CLCT_getFullBX", "CLCT.getFullBX()", 3601, -0.5, 3600.5, "TimeMonitoring");
3213  //if we don't already have digi information stored for this chamber, then we fill it
3214  if (CLCT_getFullBx_map.find(idCLCT.chamberId()) == CLCT_getFullBx_map.end()) {
3215  CLCT_getFullBx_map[idCLCT.chamberId()] = (*digiIt).getFullBX();
3216  //printf("I did fill CLCT info for Chamber %d %d %d %d \n",idCLCT.chamberId().endcap(), idCLCT.chamberId().station(), idCLCT.chamberId().ring(), idCLCT.chamberId().chamber());
3217  }
3218  }
3219  }
3220  }
3221 
3222  // *************************************************
3223  // *** CorrelatedLCT Digis *************************
3224  // *************************************************
3225  int n_correlatedlcts = 0;
3226  for (CSCCorrelatedLCTDigiCollection::DigiRangeIterator j = correlatedlcts->begin(); j != correlatedlcts->end(); j++) {
3227  const CSCCorrelatedLCTDigiCollection::Range& range = (*j).second;
3228  for (CSCCorrelatedLCTDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
3229  if ((*digiIt).isValid()) {
3230  n_correlatedlcts++;
3231  histos->fill1DHist(
3232  (*digiIt).getBX(), "CorrelatedLCTS_getBX", "CorrelatedLCT.getBX()", 11, -0.5, 10.5, "TimeMonitoring");
3233  }
3234  }
3235  }
3236 
3237  int nRecHits = recHits->size();
3238  int nSegments = cscSegments->size();
3239  if (has_CSCTrigger) {
3240  histos->fill1DHist(L1GMT_BXN, "BX_L1CSCCand", "BX of L1 CSC Cand", 4001, -0.5, 4000.5, "TimeMonitoring");
3241  histos->fill2DHist(L1GMT_BXN,
3242  n_alcts,
3243  "n_ALCTs_v_BX_L1CSCCand",
3244  "Number of ALCTs vs. BX of L1 CSC Cand",
3245  4001,
3246  -0.5,
3247  4000.5,
3248  51,
3249  -0.5,
3250  50.5,
3251  "TimeMonitoring");
3252  histos->fill2DHist(L1GMT_BXN,
3253  n_clcts,
3254  "n_CLCTs_v_BX_L1CSCCand",
3255  "Number of CLCTs vs. BX of L1 CSC Cand",
3256  4001,
3257  -0.5,
3258  4000.5,
3259  51,
3260  -0.5,
3261  50.5,
3262  "TimeMonitoring");
3263  histos->fill2DHist(L1GMT_BXN,
3264  n_correlatedlcts,
3265  "n_CorrelatedLCTs_v_BX_L1CSCCand",
3266  "Number of CorrelatedLCTs vs. BX of L1 CSC Cand",
3267  4001,
3268  -0.5,
3269  4000.5,
3270  51,
3271  -0.5,
3272  50.5,
3273  "TimeMonitoring");
3274  histos->fill2DHist(L1GMT_BXN,
3275  nRecHits,
3276  "n_RecHits_v_BX_L1CSCCand",
3277  "Number of RecHits vs. BX of L1 CSC Cand",
3278  4001,
3279  -0.5,
3280  4000.5,
3281  101,
3282  -0.5,
3283  100.5,
3284  "TimeMonitoring");
3285  histos->fill2DHist(L1GMT_BXN,
3286  nSegments,
3287  "n_Segments_v_BX_L1CSCCand",
3288  "Number of Segments vs. BX of L1 CSC Cand",
3289  4001,
3290  -0.5,
3291  4000.5,
3292  51,
3293  -0.5,
3294  50.5,
3295  "TimeMonitoring");
3296  }
3297  if (has_CSCTrigger && has_beamHaloTrigger) {
3298  histos->fill1DHist(
3299  L1GMT_BXN, "BX_L1CSCCand_w_beamHalo", "BX of L1 CSC (w beamHalo bit)", 4001, -0.5, 4000.5, "TimeMonitoring");
3300  histos->fill2DHist(L1GMT_BXN,
3301  n_alcts,
3302  "n_ALCTs_v_BX_L1CSCCand_w_beamHalo",
3303  "Number of ALCTs vs. BX of L1 CSC Cand (w beamHalo bit)",
3304  4001,
3305  -0.5,
3306  4000.5,
3307  51,
3308  -0.5,
3309  50.5,
3310  "TimeMonitoring");
3311  histos->fill2DHist(L1GMT_BXN,
3312  n_clcts,
3313  "n_CLCTs_v_BX_L1CSCCand_w_beamHalo",
3314  "Number of CLCTs vs. BX of L1 CSC Cand (w beamHalo bit)",
3315  4001,
3316  -0.5,
3317  4000.5,
3318  51,
3319  -0.5,
3320  50.5,
3321  "TimeMonitoring");
3322  histos->fill2DHist(L1GMT_BXN,
3323  n_correlatedlcts,
3324  "n_CorrelatedLCTs_v_BX_L1CSCCand_w_beamHalo",
3325  "Number of CorrelatedLCTs vs. BX of L1 CSC Cand (w beamHalo bit)",
3326  4001,
3327  -0.5,
3328  4000.5,
3329  51,
3330  -0.5,
3331  50.5,
3332  "TimeMonitoring");
3333  histos->fill2DHist(L1GMT_BXN,
3334  nRecHits,
3335  "n_RecHits_v_BX_L1CSCCand_w_beamHalo",
3336  "Number of RecHits vs. BX of L1 CSC Cand (w beamHalo bit)",
3337  4001,
3338  -0.5,
3339  4000.5,
3340  101,
3341  -0.5,
3342  100.5,
3343  "TimeMonitoring");
3344  histos->fill2DHist(L1GMT_BXN,
3345  nSegments,
3346  "n_Segments_v_BX_L1CSCCand_w_beamHalo",
3347  "Number of Segments vs. BX of L1 CSC Cand (w beamHalo bit)",
3348  4001,
3349  -0.5,
3350  4000.5,
3351  51,
3352  -0.5,
3353  50.5,
3354  "TimeMonitoring");
3355  }
3356 
3357  // *******************************************************************
3358  // Get information from the TMB header.
3359  // Can this eventually come out of the digis?
3360  // Taking code from EventFilter/CSCRawToDigis/CSCDCCUnpacker.cc
3361  // *******************************************************************
3362 
3363  edm::ESHandle<CSCCrateMap> hcrate = eventSetup.getHandle(crateToken_);
3364  const CSCCrateMap* pcrate = hcrate.product();
3365 
3368  event.getByToken(rd_token, rawdata);
3369  // If set selective unpacking mode
3370  // hardcoded examiner mask below to check for DCC and DDU level errors will be used first
3371  // then examinerMask for CSC level errors will be used during unpacking of each CSC block
3372  unsigned long dccBinCheckMask = 0x06080016;
3373  unsigned int examinerMask = 0x1FEBF3F6;
3374  unsigned int errorMask = 0x0;
3375 
3376  for (int id = FEDNumbering::MINCSCFEDID; id <= FEDNumbering::MAXCSCFEDID; ++id) {
3377  // loop over DCCs
3380 
3382  const FEDRawData& fedData = rawdata->FEDData(id);
3383  unsigned long length = fedData.size();
3384 
3385  if (length >= 32) {
3386  std::stringstream examiner_out, examiner_err;
3388  CSCDCCExaminer* examiner = new CSCDCCExaminer();
3389  if (examinerMask & 0x40000)
3390  examiner->crcCFEB(true);
3391  if (examinerMask & 0x8000)
3392  examiner->crcTMB(true);
3393  if (examinerMask & 0x0400)
3394  examiner->crcALCT(true);
3395  examiner->setMask(examinerMask);
3396  const short unsigned int* data = (short unsigned int*)fedData.data();
3397 
3398  bool goodEvent;
3399  if (examiner->check(data, long(fedData.size() / 2)) < 0) {
3400  goodEvent = false;
3401  } else {
3402  goodEvent = !(examiner->errors() & dccBinCheckMask);
3403  }
3404 
3405  if (goodEvent) {
3407  CSCDCCExaminer* ptrExaminer = examiner;
3408  CSCDCCEventData dccData((short unsigned int*)fedData.data(), ptrExaminer);
3409 
3411  const std::vector<CSCDDUEventData>& dduData = dccData.dduData();
3412 
3414  CSCDetId layer(1, 1, 1, 1, 1);
3415 
3416  for (unsigned int iDDU = 0; iDDU < dduData.size(); ++iDDU) { // loop over DDUs
3419  if (dduData[iDDU].trailer().errorstat() & errorMask) {
3420  LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "DDU# " << iDDU << " has serious error - no digis unpacked! "
3421  << std::hex << dduData[iDDU].trailer().errorstat();
3422  continue; // to next iteration of DDU loop
3423  }
3424 
3426  const std::vector<CSCEventData>& cscData = dduData[iDDU].cscData();
3427  for (unsigned int iCSC = 0; iCSC < cscData.size(); ++iCSC) { // loop over CSCs
3428 
3429  int vmecrate = cscData[iCSC].dmbHeader()->crateID();
3430  int dmb = cscData[iCSC].dmbHeader()->dmbID();
3431 
3433  // SKIPPING MTCC redefinition of vmecrate
3434 
3435  int icfeb = 0;
3436  int ilayer = 0;
3437 
3438  if ((vmecrate >= 1) && (vmecrate <= 60) && (dmb >= 1) && (dmb <= 10) && (dmb != 6)) {
3439  layer = pcrate->detId(vmecrate, dmb, icfeb, ilayer);
3440  } else {
3441  LogTrace("CSCTimingAlignment|CSCDCCUnpacker|CSCRawToDigi") << " detID input out of range!!! ";
3442  LogTrace("CSCTimingAlignment|CSCDCCUnpacker|CSCRawToDigi")
3443  << " skipping chamber vme= " << vmecrate << " dmb= " << dmb;
3444  continue; // to next iteration of iCSC loop
3445  }
3446 
3448  int nalct = cscData[iCSC].dmbHeader()->nalct();
3449  bool goodALCT = false;
3450  //if (nalct&&(cscData[iCSC].dataPresent>>6&0x1)==1) {
3451  if (nalct && cscData[iCSC].alctHeader()) {
3452  if (cscData[iCSC].alctHeader()->check()) {
3453  goodALCT = true;
3454  }
3455  }
3456 
3458  int nclct = cscData[iCSC].dmbHeader()->nclct();
3459  bool goodTMB = false;
3460  if (nclct && cscData[iCSC].tmbData()) {
3461  if (cscData[iCSC].tmbHeader()->check()) {
3462  if (cscData[iCSC].comparatorData()->check())
3463  goodTMB = true;
3464  }
3465  }
3466 
3467  if (goodTMB && goodALCT) {
3468  if (ALCT_KeyWG_map.find(layer) == ALCT_KeyWG_map.end()) {
3469  printf("no ALCT info for Chamber %d %d %d %d \n",
3470  layer.endcap(),
3471  layer.station(),
3472  layer.ring(),
3473  layer.chamber());
3474  continue;
3475  }
3476  if (CLCT_getFullBx_map.find(layer) == CLCT_getFullBx_map.end()) {
3477  printf("no CLCT info for Chamber %d %d %d %d \n",
3478  layer.endcap(),
3479  layer.station(),
3480  layer.ring(),
3481  layer.chamber());
3482  continue;
3483  }
3484  int ALCT0Key = ALCT_KeyWG_map.find(layer)->second;
3485  int CLCTPretrigger = CLCT_getFullBx_map.find(layer)->second;
3486 
3487  const CSCTMBHeader* tmbHead = cscData[iCSC].tmbHeader();
3488 
3489  histos->fill1DHistByStation(tmbHead->BXNCount(),
3490  "TMB_BXNCount",
3491  "TMB_BXNCount",
3492  layer.chamberId(),
3493  3601,
3494  -0.5,
3495  3600.5,
3496  "TimeMonitoring");
3497  histos->fill1DHistByStation(tmbHead->ALCTMatchTime(),
3498  "TMB_ALCTMatchTime",
3499  "TMB_ALCTMatchTime",
3500  layer.chamberId(),
3501  7,
3502  -0.5,
3503  6.5,
3504  "TimeMonitoring");
3505 
3506  histos->fill1DHist(
3507  tmbHead->BXNCount(), "TMB_BXNCount", "TMB_BXNCount", 3601, -0.5, 3600.5, "TimeMonitoring");
3508  histos->fill1DHist(
3509  tmbHead->ALCTMatchTime(), "TMB_ALCTMatchTime", "TMB_ALCTMatchTime", 7, -0.5, 6.5, "TimeMonitoring");
3510 
3511  histos->fill1DHistByType(tmbHead->ALCTMatchTime(),
3512  "TMB_ALCTMatchTime",
3513  "TMB_ALCTMatchTime",
3514  layer.chamberId(),
3515  7,
3516  -0.5,
3517  6.5,
3518  "TimeMonitoring");
3519 
3520  histos->fillProfile(chamberSerial(layer.chamberId()),
3521  tmbHead->ALCTMatchTime(),
3522  "prof_TMB_ALCTMatchTime",
3523  "prof_TMB_ALCTMatchTime",
3524  601,
3525  -0.5,
3526  600.5,
3527  -0.5,
3528  7.5,
3529  "TimeMonitoring");
3530  histos->fillProfile(ALCT0Key,
3531  tmbHead->ALCTMatchTime(),
3532  "prof_TMB_ALCTMatchTime_v_ALCT0KeyWG",
3533  "prof_TMB_ALCTMatchTime_v_ALCT0KeyWG",
3534  128,
3535  -0.5,
3536  127.5,
3537  0,
3538  7,
3539  "TimeMonitoring");
3540  histos->fillProfileByType(ALCT0Key,
3541  tmbHead->ALCTMatchTime(),
3542  "prf_TMB_ALCTMatchTime_v_ALCT0KeyWG",
3543  "prf_TMB_ALCTMatchTime_v_ALCT0KeyWG",
3544  layer.chamberId(),
3545  128,
3546  -0.5,
3547  127.5,
3548  0,
3549  7,
3550  "TimeMonitoring");
3551 
3552  //Attempt to make a few sum plots
3553 
3554  int TMB_ALCT_rel_L1A = tmbHead->BXNCount() - (CLCTPretrigger + 2 + tmbHead->ALCTMatchTime());
3555  if (TMB_ALCT_rel_L1A > 3563)
3556  TMB_ALCT_rel_L1A = TMB_ALCT_rel_L1A - 3564;
3557  if (TMB_ALCT_rel_L1A < 0)
3558  TMB_ALCT_rel_L1A = TMB_ALCT_rel_L1A + 3564;
3559 
3560  //Plot TMB_ALCT_rel_L1A
3561  histos->fill1DHist(
3562  TMB_ALCT_rel_L1A, "h1D_TMB_ALCT_rel_L1A", "h1D_TMB_ALCT_rel_L1A", 11, 144.5, 155.5, "TimeMonitoring");
3563  histos->fill2DHist(chamberSerial(layer.chamberId()),
3564  TMB_ALCT_rel_L1A,
3565  "h2D_TMB_ALCT_rel_L1A",
3566  "h2D_TMB_ALCT_rel_L1A",
3567  601,
3568  -0.5,
3569  600.5,
3570  11,
3571  144.5,
3572  155.5,
3573  "TimeMonitoring");
3574  histos->fill2DHist(ringSerial(layer.chamberId()),
3575  TMB_ALCT_rel_L1A,
3576  "h2D_TMB_ALCT_rel_L1A_by_ring",
3577  "h2D_TMB_ALCT_rel_L1A_by_ring",
3578  19,
3579  -9.5,
3580  9.5,
3581  11,
3582  144.5,
3583  155.5,
3584  "TimeMonitoring");
3585  histos->fillProfile(chamberSerial(layer.chamberId()),
3586  TMB_ALCT_rel_L1A,
3587  "prof_TMB_ALCT_rel_L1A",
3588  "prof_TMB_ALCT_rel_L1A",
3589  601,
3590  -0.5,
3591  600.5,
3592  145,
3593  155,
3594  "TimeMonitoring");
3595  histos->fillProfile(ringSerial(layer.chamberId()),
3596  TMB_ALCT_rel_L1A,
3597  "prof_TMB_ALCT_rel_L1A_by_ring",
3598  "prof_TMB_ALCT_rel_L1A_by_ring",
3599  19,
3600  -9.5,
3601  9.5,
3602  145,
3603  155,
3604  "TimeMonitoring");
3605 
3606  histos->fill2DHist(ALCT0Key,
3607  TMB_ALCT_rel_L1A,
3608  "h2D_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3609  "h2D_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3610  128,
3611  -0.5,
3612  127.5,
3613  11,
3614  144.5,
3615  155.5,
3616  "TimeMonitoring");
3617  histos->fillProfile(ALCT0Key,
3618  TMB_ALCT_rel_L1A,
3619  "prof_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3620  "prof_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3621  128,
3622  -0.5,
3623  127.5,
3624  145,
3625  155,
3626  "TimeMonitoring");
3627  histos->fillProfileByType(ALCT0Key,
3628  TMB_ALCT_rel_L1A,
3629  "prf_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3630  "prf_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3631  layer.chamberId(),
3632  128,
3633  -0.5,
3634  127.5,
3635  145,
3636  155,
3637  "TimeMonitoring");
3638  }
3639 
3640  } // end CSCData loop
3641  } // end ddu data loop
3642  } // end if goodEvent
3643  if (examiner != nullptr)
3644  delete examiner;
3645  } // end if non-zero fed data
3646  } // end DCC loop for NON-REFERENCE
3647 }
3648 
3649 void CSCValidation::beginJob() { std::cout << "CSCValidation starting..." << std::endl; }
3650 
3651 void CSCValidation::endJob() { std::cout << "CSCValidation: Events analyzed " << nEventsAnalyzed << std::endl; }
3652 
01/20/05 A.Tumanov
void crcCFEB(bool enable)
const CSCLayer * layer(CSCDetId id) const
Return the layer corresponding to the given id.
Definition: CSCChamber.cc:30
LocalPoint localPosition() const override
Definition: CSCSegment.h:39
const CSCChamber * chamber(CSCDetId id) const
Return the chamber corresponding to given DetId.
Definition: CSCGeometry.cc:100
LocalPoint toLocal(const GlobalPoint &gp) const
Conversion to the R.F. of the GeomDet.
Definition: GeomDet.h:58
T z() const
Definition: PV3DBase.h:61
for(int i=first, nt=offsets[nh];i< nt;i+=gridDim.x *blockDim.x)
Geom::Phi< T > phi() const
Definition: PV3DBase.h:66
static const double slope[3]
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
size_t size() const
Lenght of the data buffer in bytes.
Definition: FEDRawData.h:48
Definition: weight.py:1
GainContainer gains
Definition: CSCDBGains.h:24
int layer() const
Definition: CSCDetId.h:56
std::string chamberTypeName() const
void crcALCT(bool enable)
example_stream void analyze(const edm::Event &, const edm::EventSetup &) override
nStrips
1.2 is to make the matching window safely the two nearest strips 0.35 is the size of an ME0 chamber i...
#define LogTrace(id)
const CSCLayerGeometry * geometry() const
Definition: CSCLayer.h:44
void beginJob()
Definition: Breakpoints.cc:14
LocalVector localDirection() const override
Local direction.
Definition: CSCSegment.h:42
C::const_iterator const_iterator
constant access iterator type
Definition: RangeMap.h:43
float yy() const
Definition: LocalError.h:24
T x() const
Definition: PV3DBase.h:59
T y() const
Definition: PV3DBase.h:60
uint16_t ALCTMatchTime() const
Definition: CSCTMBHeader.h:44
const std::vector< CSCDDUEventData > & dduData() const
accessor to dduData
T const * product() const
Definition: ESHandle.h:86
uint16_t BXNCount() const
Definition: CSCTMBHeader.h:43
int np
Definition: AMPTWrapper.h:43
int dbIndex(const CSCDetId &id, int &channel)
Definition: CSCIndexer.cc:235
T sqrt(T t)
Definition: SSEVec.h:19
void crcTMB(bool enable)
T mag() const
Definition: PV3DBase.h:64
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
float ChiSquaredProbability(double chiSquared, double nrDOF)
int chamber() const
Definition: CSCDetId.h:62
#define DEFINE_FWK_MODULE(type)
Definition: MakerMacros.h:16
static const std::string kLayer("layer")
d
Definition: ztail.py:151
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:49
const FEDRawData & FEDData(int fedid) const
retrieve data for fed
float xy() const
Definition: LocalError.h:23
Definition: DetId.h:17
std::vector< L1MuGMTReadoutRecord > const & getRecords() const
CSCDetId detId(int vme, int dmb, int cfeb, int layer=0) const
Definition: CSCCrateMap.cc:9
int station() const
Definition: CSCDetId.h:79
CSCDetId chamberId() const
Definition: CSCDetId.h:47
virtual const std::array< const float, 4 > parameters() const
std::pair< const_iterator, const_iterator > Range
static constexpr int RPC
Definition: MuonSubdetId.h:13
int endcap() const
Definition: CSCDetId.h:85
std::vector< DigiType >::const_iterator const_iterator
int32_t check(const uint16_t *&buffer, int32_t length)
histos
Definition: combine.py:4
std::vector< const CSCChamber * > ChamberContainer
Definition: CSCGeometry.h:30
PedestalContainer pedestals
HLT enums.
char data[epos_bytes_allocation]
Definition: EPOS_Wrapper.h:80
ExaminerStatusType errors(void) const
float x
const unsigned char * data() const
Return a const pointer to the beginning of the data buffer.
Definition: FEDRawData.cc:24
strips
#turn off noise in all subdetectors simHcalUnsuppressedDigis.doNoise = False mix.digitizers.hcal.doNoise = False simEcalUnsuppressedDigis.doNoise = False mix.digitizers.ecal.doNoise = False simEcalUnsuppressedDigis.doESNoise = False simSiPixelDigis.AddNoise = False mix.digitizers.pixel.AddNoise = False simSiStripDigis.Noise = False mix.digitizers.strip.AddNoise = False
Definition: DigiDM_cff.py:32
Definition: errors.py:1
CrosstalkContainer crosstalk
NoiseMatrixContainer matrix
static constexpr int DT
Definition: MuonSubdetId.h:11
int ring() const
Definition: CSCDetId.h:68
const ChamberContainer & chambers() const
Return a vector of all chambers.
Definition: CSCGeometry.cc:96
const CSCLayer * layer(CSCDetId id) const
Return the layer corresponding to given DetId.
Definition: CSCGeometry.cc:105
static constexpr int CSC
Definition: MuonSubdetId.h:12
Geom::Theta< T > theta() const
if(threadIdxLocalY==0 &&threadIdxLocalX==0)
const CSCChamberSpecs * specs() const
Definition: CSCChamber.h:39
void setMask(ExaminerMaskType mask)
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29
float xx() const
Definition: LocalError.h:22
Definition: event.py:1
Geom::Theta< T > theta() const
Definition: PV3DBase.h:72
#define LogDebug(id)
CSCDetId id() const
Get the (concrete) DetId.
Definition: CSCChamber.h:34