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ApeEstimator.cc
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1 // -*- C++ -*-
2 //
3 // Package: ApeEstimator
4 // Class: ApeEstimator
5 //
13 //
14 // Original Author: Johannes Hauk
15 // Created: Tue Jan 6 15:02:09 CET 2009
16 // Modified by: Christian Schomakers (RWTH Aachen)
17 // $Id: ApeEstimator.cc,v 1.27 2012/06/26 09:42:33 hauk Exp $
18 //
19 //
20 
21 // system include files
22 #include <memory>
23 #include <sstream>
24 #include <fstream>
25 
26 // user include files
37 
40 
60 
68 
72 //added by Ajay 6Nov 2014
73 //.......................
76 
78 
79 //...............
80 //
81 
84 
86 
88 
93 
94 #include "TH1.h"
95 #include "TH2.h"
96 #include "TProfile.h"
97 #include "TFile.h"
98 #include "TTree.h"
99 #include "TF1.h"
100 #include "TString.h"
101 #include "TMath.h"
102 
105 
108 //ADDED BY LOIC QUERTENMONT
119 
120 //
121 // class decleration
122 //
123 
125 public:
126  explicit ApeEstimator(const edm::ParameterSet&);
127  ~ApeEstimator() override;
128 
129 private:
131  PositionAndError2() : posX(-999.F), posY(-999.F), errX2(-999.F), errY2(-999.F){};
132  PositionAndError2(float x, float y, float eX, float eY) : posX(x), posY(y), errX2(eX), errY2(eY){};
133  float posX;
134  float posY;
135  float errX2;
136  float errY2;
137  };
138  typedef std::pair<TrackStruct::HitState, PositionAndError2> StatePositionAndError2;
139 
140  void beginJob() override;
141  void analyze(const edm::Event&, const edm::EventSetup&) override;
142  void endJob() override;
143 
144  bool isHit2D(const TrackingRecHit&) const;
145 
146  void sectorBuilder();
147  bool checkIntervalsForSectors(const unsigned int sectorCounter, const std::vector<double>&) const;
148  bool checkModuleIds(const unsigned int, const std::vector<unsigned int>&) const;
149  bool checkModuleBools(const bool, const std::vector<unsigned int>&) const;
150  bool checkModuleDirections(const int, const std::vector<int>&) const;
151  bool checkModulePositions(const float, const std::vector<double>&) const;
152  void statistics(const TrackerSectorStruct&, const int) const;
153 
154  void residualErrorBinning();
155 
158  void bookTrackHists();
159 
162 
166 
167  void hitSelection();
168  void setHitSelectionMap(const std::string&);
169  void setHitSelectionMapUInt(const std::string&);
171  bool inDoubleInterval(const std::vector<double>&, const float) const;
172  bool inUintInterval(const std::vector<unsigned int>&, const unsigned int, const unsigned int = 999) const;
173 
178 
179  void calculateAPE();
180 
181  // ----------member data ---------------------------
185 
186  std::map<unsigned int, TrackerSectorStruct> m_tkSector_;
189 
192 
193  std::map<unsigned int, std::pair<double, double> > m_resErrBins_;
194  std::map<unsigned int, ReducedTrackerTreeVariables> m_tkTreeVar_;
195 
196  std::map<std::string, std::vector<double> > m_hitSelection_;
197  std::map<std::string, std::vector<unsigned int> > m_hitSelectionUInt_;
198 
199  bool trackCut_;
200 
201  const unsigned int maxTracksPerEvent_;
202  const unsigned int minGoodHitsPerTrack_;
203 
204  const bool analyzerMode_;
205 
206  const bool calculateApe_;
207 
209 };
210 
211 //
212 // constants, enums and typedefs
213 //
214 
215 //
216 // static data member definitions
217 //
218 
219 //
220 // constructors and destructor
221 //
223  : parameterSet_(iConfig),
224  magFieldToken_(esConsumes()),
225  lorentzAngleToken_(esConsumes()),
226  siStripClusterInfo_(consumesCollector(), std::string("")),
227  tjTagToken_(
228  consumes<TrajTrackAssociationCollection>(parameterSet_.getParameter<edm::InputTag>("tjTkAssociationMapTag"))),
229  offlinebeamSpot_(consumes<reco::BeamSpot>(edm::InputTag("offlineBeamSpot"))),
230  trackCut_(false),
231  maxTracksPerEvent_(parameterSet_.getParameter<unsigned int>("maxTracksPerEvent")),
232  minGoodHitsPerTrack_(parameterSet_.getParameter<unsigned int>("minGoodHitsPerTrack")),
233  analyzerMode_(parameterSet_.getParameter<bool>("analyzerMode")),
234  calculateApe_(parameterSet_.getParameter<bool>("calculateApe")) {
236 }
237 
239 
240 //
241 // member functions
242 //
243 
244 // -----------------------------------------------------------------------------------------------------------
245 
247  TFile* tkTreeFile(TFile::Open((parameterSet_.getParameter<std::string>("TrackerTreeFile")).c_str()));
248  if (tkTreeFile) {
249  edm::LogInfo("SectorBuilder") << "TrackerTreeFile OK";
250  } else {
251  edm::LogError("SectorBuilder") << "TrackerTreeFile not found";
252  return;
253  }
254  TTree* tkTree(nullptr);
255  tkTreeFile->GetObject("TrackerTreeGenerator/TrackerTree/TrackerTree", tkTree);
256  if (tkTree) {
257  edm::LogInfo("SectorBuilder") << "TrackerTree OK";
258  } else {
259  edm::LogError("SectorBuilder") << "TrackerTree not found in file";
260  return;
261  }
262  unsigned int rawId(999), subdetId(999), layer(999), side(999), half(999), rod(999), ring(999), petal(999), blade(999),
263  panel(999), outerInner(999), module(999), nStrips(999);
264  bool isDoubleSide(false), isRPhi(false), isStereo(false);
265  int uDirection(999), vDirection(999), wDirection(999);
266  float posR(999.F), posPhi(999.F), posEta(999.F), posX(999.F), posY(999.F), posZ(999.F);
267 
268  tkTree->SetBranchAddress("RawId", &rawId);
269  tkTree->SetBranchAddress("SubdetId", &subdetId);
270  tkTree->SetBranchAddress("Layer", &layer);
271  tkTree->SetBranchAddress("Side", &side);
272  tkTree->SetBranchAddress("Half", &half);
273  tkTree->SetBranchAddress("Rod", &rod);
274  tkTree->SetBranchAddress("Ring", &ring);
275  tkTree->SetBranchAddress("Petal", &petal);
276  tkTree->SetBranchAddress("Blade", &blade);
277  tkTree->SetBranchAddress("Panel", &panel);
278  tkTree->SetBranchAddress("OuterInner", &outerInner);
279  tkTree->SetBranchAddress("Module", &module);
280  tkTree->SetBranchAddress("NStrips", &nStrips);
281  tkTree->SetBranchAddress("IsDoubleSide", &isDoubleSide);
282  tkTree->SetBranchAddress("IsRPhi", &isRPhi);
283  tkTree->SetBranchAddress("IsStereo", &isStereo);
284  tkTree->SetBranchAddress("UDirection", &uDirection);
285  tkTree->SetBranchAddress("VDirection", &vDirection);
286  tkTree->SetBranchAddress("WDirection", &wDirection);
287  tkTree->SetBranchAddress("PosR", &posR);
288  tkTree->SetBranchAddress("PosPhi", &posPhi);
289  tkTree->SetBranchAddress("PosEta", &posEta);
290  tkTree->SetBranchAddress("PosX", &posX);
291  tkTree->SetBranchAddress("PosY", &posY);
292  tkTree->SetBranchAddress("PosZ", &posZ);
293 
294  int nModules(tkTree->GetEntries());
295  TrackerSectorStruct allSectors;
296 
297  //Loop over all Sectors
298  unsigned int sectorCounter(0);
299  std::vector<edm::ParameterSet> v_sectorDef(parameterSet_.getParameter<std::vector<edm::ParameterSet> >("Sectors"));
300  edm::LogInfo("SectorBuilder") << "There are " << v_sectorDef.size() << " Sectors definded";
301  for (auto const& parSet : v_sectorDef) {
302  ++sectorCounter;
303  const std::string& sectorName(parSet.getParameter<std::string>("name"));
304  std::vector<unsigned int> v_rawId(parSet.getParameter<std::vector<unsigned int> >("rawId")),
305  v_subdetId(parSet.getParameter<std::vector<unsigned int> >("subdetId")),
306  v_layer(parSet.getParameter<std::vector<unsigned int> >("layer")),
307  v_side(parSet.getParameter<std::vector<unsigned int> >("side")),
308  v_half(parSet.getParameter<std::vector<unsigned int> >("half")),
309  v_rod(parSet.getParameter<std::vector<unsigned int> >("rod")),
310  v_ring(parSet.getParameter<std::vector<unsigned int> >("ring")),
311  v_petal(parSet.getParameter<std::vector<unsigned int> >("petal")),
312  v_blade(parSet.getParameter<std::vector<unsigned int> >("blade")),
313  v_panel(parSet.getParameter<std::vector<unsigned int> >("panel")),
314  v_outerInner(parSet.getParameter<std::vector<unsigned int> >("outerInner")),
315  v_module(parSet.getParameter<std::vector<unsigned int> >("module")),
316  v_nStrips(parSet.getParameter<std::vector<unsigned int> >("nStrips")),
317  v_isDoubleSide(parSet.getParameter<std::vector<unsigned int> >("isDoubleSide")),
318  v_isRPhi(parSet.getParameter<std::vector<unsigned int> >("isRPhi")),
319  v_isStereo(parSet.getParameter<std::vector<unsigned int> >("isStereo"));
320  std::vector<int> v_uDirection(parSet.getParameter<std::vector<int> >("uDirection")),
321  v_vDirection(parSet.getParameter<std::vector<int> >("vDirection")),
322  v_wDirection(parSet.getParameter<std::vector<int> >("wDirection"));
323  std::vector<double> v_posR(parSet.getParameter<std::vector<double> >("posR")),
324  v_posPhi(parSet.getParameter<std::vector<double> >("posPhi")),
325  v_posEta(parSet.getParameter<std::vector<double> >("posEta")),
326  v_posX(parSet.getParameter<std::vector<double> >("posX")),
327  v_posY(parSet.getParameter<std::vector<double> >("posY")),
328  v_posZ(parSet.getParameter<std::vector<double> >("posZ"));
329 
330  if (!this->checkIntervalsForSectors(sectorCounter, v_posR) ||
331  !this->checkIntervalsForSectors(sectorCounter, v_posPhi) ||
332  !this->checkIntervalsForSectors(sectorCounter, v_posEta) ||
333  !this->checkIntervalsForSectors(sectorCounter, v_posX) ||
334  !this->checkIntervalsForSectors(sectorCounter, v_posY) ||
335  !this->checkIntervalsForSectors(sectorCounter, v_posZ))
336  continue;
337 
338  TrackerSectorStruct tkSector;
339  tkSector.name = sectorName;
340 
341  ReducedTrackerTreeVariables tkTreeVar;
342 
343  //Loop over all Modules
344  for (int module = 0; module < nModules; ++module) {
345  tkTree->GetEntry(module);
346 
347  if (sectorCounter == 1) {
348  tkTreeVar.subdetId = subdetId;
349  tkTreeVar.nStrips = nStrips;
350  tkTreeVar.uDirection = uDirection;
351  tkTreeVar.vDirection = vDirection;
352  tkTreeVar.wDirection = wDirection;
353  m_tkTreeVar_[rawId] = tkTreeVar;
354  }
355 
356  if (!this->checkModuleIds(rawId, v_rawId))
357  continue;
358  if (!this->checkModuleIds(subdetId, v_subdetId))
359  continue;
360  if (!this->checkModuleIds(layer, v_layer))
361  continue;
362  if (!this->checkModuleIds(side, v_side))
363  continue;
364  if (!this->checkModuleIds(half, v_half))
365  continue;
366  if (!this->checkModuleIds(rod, v_rod))
367  continue;
368  if (!this->checkModuleIds(ring, v_ring))
369  continue;
370  if (!this->checkModuleIds(petal, v_petal))
371  continue;
372  if (!this->checkModuleIds(blade, v_blade))
373  continue;
374  if (!this->checkModuleIds(panel, v_panel))
375  continue;
376  if (!this->checkModuleIds(outerInner, v_outerInner))
377  continue;
378  if (!this->checkModuleIds(module, v_module))
379  continue;
380  if (!this->checkModuleIds(nStrips, v_nStrips))
381  continue;
382  if (!this->checkModuleBools(isDoubleSide, v_isDoubleSide))
383  continue;
384  if (!this->checkModuleBools(isRPhi, v_isRPhi))
385  continue;
386  if (!this->checkModuleBools(isStereo, v_isStereo))
387  continue;
388  if (!this->checkModuleDirections(uDirection, v_uDirection))
389  continue;
390  if (!this->checkModuleDirections(vDirection, v_vDirection))
391  continue;
392  if (!this->checkModuleDirections(wDirection, v_wDirection))
393  continue;
394  if (!this->checkModulePositions(posR, v_posR))
395  continue;
396  if (!this->checkModulePositions(posPhi, v_posPhi))
397  continue;
398  if (!this->checkModulePositions(posEta, v_posEta))
399  continue;
400  if (!this->checkModulePositions(posX, v_posX))
401  continue;
402  if (!this->checkModulePositions(posY, v_posY))
403  continue;
404  if (!this->checkModulePositions(posZ, v_posZ))
405  continue;
406 
407  tkSector.v_rawId.push_back(rawId);
408  bool moduleSelected(false);
409  for (auto const& i_rawId : allSectors.v_rawId) {
410  if (rawId == i_rawId)
411  moduleSelected = true;
412  }
413  if (!moduleSelected)
414  allSectors.v_rawId.push_back(rawId);
415  }
416 
417  bool isPixel(false);
418  bool isStrip(false);
419  for (auto const& i_rawId : tkSector.v_rawId) {
420  switch (m_tkTreeVar_[i_rawId].subdetId) {
423  isPixel = true;
424  break;
429  isStrip = true;
430  break;
431  }
432  }
433 
434  if (isPixel && isStrip) {
435  edm::LogError("SectorBuilder")
436  << "Incorrect Sector Definition: there are pixel and strip modules within one sector"
437  << "\n... sector selection is not applied, sector " << sectorCounter << " is not built";
438  continue;
439  }
440  tkSector.isPixel = isPixel;
441 
442  m_tkSector_[sectorCounter] = tkSector;
443  edm::LogInfo("SectorBuilder") << "There are " << tkSector.v_rawId.size() << " Modules in Sector " << sectorCounter;
444  }
445  this->statistics(allSectors, nModules);
446  return;
447 }
448 
449 // -----------------------------------------------------------------------------------------------------------
450 
451 bool ApeEstimator::checkIntervalsForSectors(const unsigned int sectorCounter, const std::vector<double>& v_id) const {
452  if (v_id.empty())
453  return true;
454  if (v_id.size() % 2 == 1) {
455  edm::LogError("SectorBuilder")
456  << "Incorrect Sector Definition: Position Vectors need even number of arguments (Intervals)"
457  << "\n... sector selection is not applied, sector " << sectorCounter << " is not built";
458  return false;
459  }
460  int entry(0);
461  double intervalBegin(999.);
462  for (auto const& i_id : v_id) {
463  ++entry;
464  if (entry % 2 == 1)
465  intervalBegin = i_id;
466  if (entry % 2 == 0 && intervalBegin > i_id) {
467  edm::LogError("SectorBuilder") << "Incorrect Sector Definition (Position Vector Intervals): \t" << intervalBegin
468  << " is bigger than " << i_id << " but is expected to be smaller"
469  << "\n... sector selection is not applied, sector " << sectorCounter
470  << " is not built";
471  return false;
472  }
473  }
474  return true;
475 }
476 
477 bool ApeEstimator::checkModuleIds(const unsigned int id, const std::vector<unsigned int>& v_id) const {
478  if (v_id.empty())
479  return true;
480  for (auto const& i_id : v_id) {
481  if (id == i_id)
482  return true;
483  }
484  return false;
485 }
486 
487 bool ApeEstimator::checkModuleBools(const bool id, const std::vector<unsigned int>& v_id) const {
488  if (v_id.empty())
489  return true;
490  for (auto const& i_id : v_id) {
491  if (1 == i_id && id)
492  return true;
493  if (2 == i_id && !id)
494  return true;
495  }
496  return false;
497 }
498 
499 bool ApeEstimator::checkModuleDirections(const int id, const std::vector<int>& v_id) const {
500  if (v_id.empty())
501  return true;
502  for (auto const& i_id : v_id) {
503  if (id == i_id)
504  return true;
505  }
506  return false;
507 }
508 
509 bool ApeEstimator::checkModulePositions(const float id, const std::vector<double>& v_id) const {
510  if (v_id.empty())
511  return true;
512  int entry(0);
513  double intervalBegin(999.);
514  for (auto const& i_id : v_id) {
515  ++entry;
516  if (entry % 2 == 1)
517  intervalBegin = i_id;
518  if (entry % 2 == 0 && id >= intervalBegin && id < i_id)
519  return true;
520  }
521  return false;
522 }
523 
524 void ApeEstimator::statistics(const TrackerSectorStruct& allSectors, const int nModules) const {
525  bool commonModules(false);
526  for (std::map<unsigned int, TrackerSectorStruct>::const_iterator i_sector = m_tkSector_.begin();
527  i_sector != m_tkSector_.end();
528  ++i_sector) {
529  std::map<unsigned int, TrackerSectorStruct>::const_iterator i_sector2(i_sector);
530  for (++i_sector2; i_sector2 != m_tkSector_.end(); ++i_sector2) {
531  unsigned int nCommonModules(0);
532  for (auto const& i_module : (*i_sector).second.v_rawId) {
533  for (auto const& i_module2 : (*i_sector2).second.v_rawId) {
534  if (i_module2 == i_module)
535  ++nCommonModules;
536  }
537  }
538  if (nCommonModules == 0)
539  ; //edm::LogInfo("SectorBuilder")<<"Sector "<<(*i_sector).first<<" and Sector "<<(*i_sector2).first<< " have ZERO Modules in common";
540  else {
541  edm::LogError("SectorBuilder") << "Sector " << (*i_sector).first << " and Sector " << (*i_sector2).first
542  << " have " << nCommonModules << " Modules in common";
543  commonModules = true;
544  }
545  }
546  }
547  if (static_cast<int>(allSectors.v_rawId.size()) == nModules)
548  edm::LogInfo("SectorBuilder") << "ALL Tracker Modules are contained in the Sectors";
549  else
550  edm::LogWarning("SectorBuilder") << "There are " << allSectors.v_rawId.size() << " Modules in all Sectors"
551  << " out of " << nModules << " Tracker Modules";
552  if (!commonModules)
553  edm::LogInfo("SectorBuilder") << "There are ZERO modules associated to different sectors, no ambiguities exist";
554  else
555  edm::LogError("SectorBuilder")
556  << "There are modules associated to different sectors, APE value cannot be assigned reasonably";
557 }
558 
559 // -----------------------------------------------------------------------------------------------------------
560 
562  std::vector<double> v_residualErrorBinning(parameterSet_.getParameter<std::vector<double> >("residualErrorBinning"));
563  if (v_residualErrorBinning.size() == 1) {
564  edm::LogError("ResidualErrorBinning") << "Incorrect selection of Residual Error Bins (used for APE calculation): \t"
565  << "Only one argument passed, so no interval is specified"
566  << "\n... delete whole bin selection"; //m_resErrBins_ remains empty
567  return;
568  }
569  double xMin(0.), xMax(0.);
570  unsigned int binCounter(-1);
571  for (auto const& i_binning : v_residualErrorBinning) {
572  ++binCounter;
573  if (binCounter == 0) {
574  xMin = i_binning;
575  continue;
576  }
577  xMax = i_binning;
578  if (xMax <= xMin) {
579  edm::LogError("ResidualErrorBinning")
580  << "Incorrect selection of Residual Error Bins (used for APE calculation): \t" << xMin << " is bigger than "
581  << xMax << " but is expected to be smaller"
582  << "\n... delete whole bin selection";
583  m_resErrBins_.clear();
584  return;
585  }
586  m_resErrBins_[binCounter].first = xMin;
587  m_resErrBins_[binCounter].second = xMax;
588  xMin = xMax;
589  }
590  edm::LogInfo("ResidualErrorBinning")
591  << m_resErrBins_.size() << " Intervals of residual errors used for separate APE calculation sucessfully set";
592 }
593 
594 // -----------------------------------------------------------------------------------------------------------
595 
597  std::vector<unsigned int> v_errHists(parameterSet_.getParameter<std::vector<unsigned int> >("vErrHists"));
598  for (std::vector<unsigned int>::iterator i_errHists = v_errHists.begin(); i_errHists != v_errHists.end();
599  ++i_errHists) {
600  for (std::vector<unsigned int>::iterator i_errHists2 = i_errHists; i_errHists2 != v_errHists.end();) {
601  ++i_errHists2;
602  if (*i_errHists == *i_errHists2) {
603  edm::LogError("BookSectorHists") << "Value of vErrHists in config exists twice: " << *i_errHists
604  << "\n... delete one of both";
605  v_errHists.erase(i_errHists2);
606  }
607  }
608  }
609 
610  for (auto& i_sector : m_tkSector_) {
611  bool zoomHists(parameterSet_.getParameter<bool>("zoomHists"));
612 
613  double widthMax = zoomHists ? 20. : 200.;
614  double chargePixelMax = zoomHists ? 200000. : 2000000.;
615  double chargeStripMax = zoomHists ? 1000. : 10000.;
616  double sOverNMax = zoomHists ? 200. : 2000.;
617  double logClusterProbMin = zoomHists ? -5. : -15.;
618 
619  double resXAbsMax = zoomHists ? 0.5 : 5.;
620  double norResXAbsMax = zoomHists ? 10. : 50.;
621  double probXMin = zoomHists ? -0.01 : -0.1;
622  double probXMax = zoomHists ? 0.11 : 1.1;
623  double sigmaXMin = zoomHists ? 0. : -0.05;
624  double sigmaXMax = zoomHists ? 0.02 : 1.;
625  double sigmaX2Max = sigmaXMax * sigmaXMax;
626  double sigmaXHitMax = zoomHists ? 0.02 : 1.;
627  double phiSensXMax = zoomHists ? 31. : 93.;
628 
629  double norChi2Max = zoomHists ? 5. : 1000.;
630  double d0Max = zoomHists ? 0.02 : 40.; // cosmics: 100.|100.
631  double dzMax = zoomHists ? 15. : 100.; // cosmics: 200.|600.
632  double pMax = zoomHists ? 200. : 2000.;
633  double invPMax = zoomHists ? 0.05 : 10.; //begins at 20GeV, 0.1GeV
634 
635  edm::Service<TFileService> fileService;
636  if (!fileService) {
637  throw edm::Exception(edm::errors::Configuration, "TFileService is not registered in cfg file");
638  }
639 
640  std::stringstream sector;
641  sector << "Sector_" << i_sector.first;
642  TFileDirectory secDir = fileService->mkdir(sector.str());
643 
644  // Dummy histo containing the sector name as title
645  i_sector.second.Name = secDir.make<TH1F>("z_name", i_sector.second.name.c_str(), 1, 0, 1);
646 
647  // Do not book histos for empty sectors
648  if (i_sector.second.v_rawId.empty()) {
649  continue;
650  }
651  // Set parameters for correlationHists
652  i_sector.second.setCorrHistParams(&secDir, norResXAbsMax, sigmaXHitMax, sigmaXMax);
653 
654  // Book pixel or strip specific hists
655  const bool pixelSector(i_sector.second.isPixel);
656 
657  // Cluster Parameters
658  i_sector.second.m_correlationHistsX["WidthX"] = i_sector.second.bookCorrHistsX("WidthX",
659  "cluster width",
660  "w_{cl,x}",
661  "[# channels]",
662  static_cast<int>(widthMax),
663  static_cast<int>(widthMax),
664  0.,
665  widthMax,
666  "nph");
667  i_sector.second.m_correlationHistsX["BaryStripX"] = i_sector.second.bookCorrHistsX(
668  "BaryStripX", "barycenter of cluster charge", "b_{cl,x}", "[# channels]", 800, 100, -10., 790., "nph");
669 
670  if (pixelSector) {
671  i_sector.second.m_correlationHistsY["WidthY"] = i_sector.second.bookCorrHistsY("WidthY",
672  "cluster width",
673  "w_{cl,y}",
674  "[# channels]",
675  static_cast<int>(widthMax),
676  static_cast<int>(widthMax),
677  0.,
678  widthMax,
679  "nph");
680  i_sector.second.m_correlationHistsY["BaryStripY"] = i_sector.second.bookCorrHistsY(
681  "BaryStripY", "barycenter of cluster charge", "b_{cl,y}", "[# channels]", 800, 100, -10., 790., "nph");
682 
683  i_sector.second.m_correlationHistsX["ChargePixel"] = i_sector.second.bookCorrHistsX(
684  "ChargePixel", "cluster charge", "c_{cl}", "[e]", 100, 50, 0., chargePixelMax, "nph");
685  i_sector.second.m_correlationHistsX["ClusterProbXY"] = i_sector.second.bookCorrHistsX(
686  "ClusterProbXY", "cluster probability xy", "prob_{cl,xy}", "", 100, 50, 0., 1., "nph");
687  i_sector.second.m_correlationHistsX["ClusterProbQ"] = i_sector.second.bookCorrHistsX(
688  "ClusterProbQ", "cluster probability q", "prob_{cl,q}", "", 100, 50, 0., 1., "nph");
689  i_sector.second.m_correlationHistsX["ClusterProbXYQ"] = i_sector.second.bookCorrHistsX(
690  "ClusterProbXYQ", "cluster probability xyq", "prob_{cl,xyq}", "", 100, 50, 0., 1., "nph");
691  i_sector.second.m_correlationHistsX["LogClusterProb"] = i_sector.second.bookCorrHistsX(
692  "LogClusterProb", "cluster probability xy", "log(prob_{cl,xy})", "", 60, 30, logClusterProbMin, 0., "nph");
693  i_sector.second.m_correlationHistsX["IsOnEdge"] =
694  i_sector.second.bookCorrHistsX("IsOnEdge", "IsOnEdge", "isOnEdge", "", 2, 2, 0, 2, "nph");
695  i_sector.second.m_correlationHistsX["HasBadPixels"] =
696  i_sector.second.bookCorrHistsX("HasBadPixels", "HasBadPixels", "hasBadPixels", "", 2, 2, 0, 2, "nph");
697  i_sector.second.m_correlationHistsX["SpansTwoRoc"] =
698  i_sector.second.bookCorrHistsX("SpansTwoRoc", "SpansTwoRoc", "spansTwoRoc", "", 2, 2, 0, 2, "nph");
699  i_sector.second.m_correlationHistsX["QBin"] =
700  i_sector.second.bookCorrHistsX("QBin", "q bin", "q bin", "", 8, 8, 0, 8, "nph");
701 
702  i_sector.second.m_correlationHistsY["ChargePixel"] = i_sector.second.bookCorrHistsY(
703  "ChargePixel", "cluster charge", "c_{cl}", "[e]", 100, 50, 0., chargePixelMax, "nph");
704  i_sector.second.m_correlationHistsY["ClusterProbXY"] = i_sector.second.bookCorrHistsY(
705  "ClusterProbXY", "cluster probability xy", "prob_{cl,xy}", "", 100, 50, 0., 1., "nph");
706  i_sector.second.m_correlationHistsY["ClusterProbQ"] = i_sector.second.bookCorrHistsY(
707  "ClusterProbQ", "cluster probability q", "prob_{cl,q}", "", 100, 50, 0., 1., "nph");
708  i_sector.second.m_correlationHistsY["ClusterProbXYQ"] = i_sector.second.bookCorrHistsY(
709  "ClusterProbXYQ", "cluster probability xyq", "prob_{cl,xyq}", "", 100, 50, 0., 1., "nph");
710  i_sector.second.m_correlationHistsY["LogClusterProb"] = i_sector.second.bookCorrHistsY(
711  "LogClusterProb", "cluster probability xy", "log(prob_{cl,xy})", "", 60, 30, logClusterProbMin, 0., "nph");
712  i_sector.second.m_correlationHistsY["IsOnEdge"] =
713  i_sector.second.bookCorrHistsY("IsOnEdge", "IsOnEdge", "isOnEdge", "", 2, 2, 0, 2, "nph");
714  i_sector.second.m_correlationHistsY["HasBadPixels"] =
715  i_sector.second.bookCorrHistsY("HasBadPixels", "HasBadPixels", "hasBadPixels", "", 2, 2, 0, 2, "nph");
716  i_sector.second.m_correlationHistsY["SpansTwoRoc"] =
717  i_sector.second.bookCorrHistsY("SpansTwoRoc", "SpansTwoRoc", "spansTwoRoc", "", 2, 2, 0, 2, "nph");
718  i_sector.second.m_correlationHistsY["QBin"] =
719  i_sector.second.bookCorrHistsY("QBin", "q bin", "q bin", "", 8, 8, 0, 8, "nph");
720  }
721 
722  else {
723  i_sector.second.m_correlationHistsX["ChargeStrip"] = i_sector.second.bookCorrHistsX(
724  "ChargeStrip", "cluster charge", "c_{cl}", "[APV counts]", 100, 50, 0., chargeStripMax, "nph");
725  i_sector.second.m_correlationHistsX["MaxStrip"] = i_sector.second.bookCorrHistsX(
726  "MaxStrip", "strip with max. charge", "n_{cl,max}", "[# strips]", 800, 800, -10., 790., "npht");
727  i_sector.second.m_correlationHistsX["MaxCharge"] = i_sector.second.bookCorrHistsX(
728  "MaxCharge", "charge of strip with max. charge", "c_{cl,max}", "[APV counts]", 300, 75, -10., 290., "nph");
729  i_sector.second.m_correlationHistsX["MaxIndex"] = i_sector.second.bookCorrHistsX(
730  "MaxIndex", "cluster-index of strip with max. charge", "i_{cl,max}", "[# strips]", 10, 10, 0., 10., "nph");
731  i_sector.second.m_correlationHistsX["ChargeOnEdges"] =
732  i_sector.second.bookCorrHistsX("ChargeOnEdges",
733  "fraction of charge on edge strips",
734  "(c_{st,L}+c_{st,R})/c_{cl}",
735  "",
736  60,
737  60,
738  -0.1,
739  1.1,
740  "nph");
741  i_sector.second.m_correlationHistsX["ChargeAsymmetry"] =
742  i_sector.second.bookCorrHistsX("ChargeAsymmetry",
743  "asymmetry of charge on edge strips",
744  "(c_{st,L}-c_{st,R})/c_{cl}",
745  "",
746  110,
747  55,
748  -1.1,
749  1.1,
750  "nph");
751  i_sector.second.m_correlationHistsX["ChargeLRplus"] =
752  i_sector.second.bookCorrHistsX("ChargeLRplus",
753  "fraction of charge not on maxStrip",
754  "(c_{cl,L}+c_{cl,R})/c_{cl}",
755  "",
756  60,
757  60,
758  -0.1,
759  1.1,
760  "nph");
761  i_sector.second.m_correlationHistsX["ChargeLRminus"] =
762  i_sector.second.bookCorrHistsX("ChargeLRminus",
763  "asymmetry of charge L and R of maxStrip",
764  "(c_{cl,L}-c_{cl,R})/c_{cl}",
765  "",
766  110,
767  55,
768  -1.1,
769  1.1,
770  "nph");
771  i_sector.second.m_correlationHistsX["SOverN"] =
772  i_sector.second.bookCorrHistsX("SOverN", "signal over noise", "s/N", "", 100, 50, 0, sOverNMax, "nph");
773  i_sector.second.m_correlationHistsX["WidthProj"] = i_sector.second.bookCorrHistsX(
774  "WidthProj", "projected width", "w_{p}", "[# strips]", 200, 20, 0., widthMax, "nph");
775  i_sector.second.m_correlationHistsX["WidthDiff"] = i_sector.second.bookCorrHistsX("WidthDiff",
776  "width difference",
777  "w_{p} - w_{cl}",
778  "[# strips]",
779  200,
780  20,
781  -widthMax / 2.,
782  widthMax / 2.,
783  "nph");
784 
785  i_sector.second.WidthVsWidthProjected = secDir.make<TH2F>("h2_widthVsWidthProj",
786  "w_{cl} vs. w_{p};w_{p} [# strips];w_{cl} [# strips]",
787  static_cast<int>(widthMax),
788  0,
789  widthMax,
790  static_cast<int>(widthMax),
791  0,
792  widthMax);
793  i_sector.second.PWidthVsWidthProjected =
794  secDir.make<TProfile>("p_widthVsWidthProj",
795  "w_{cl} vs. w_{p};w_{p} [# strips];w_{cl} [# strips]",
796  static_cast<int>(widthMax),
797  0,
798  widthMax);
799 
800  i_sector.second.WidthDiffVsMaxStrip =
801  secDir.make<TH2F>("h2_widthDiffVsMaxStrip",
802  "(w_{p} - w_{cl}) vs. n_{cl,max};n_{cl,max};w_{p} - w_{cl} [# strips]",
803  800,
804  -10.,
805  790.,
806  static_cast<int>(widthMax),
807  -widthMax / 2.,
808  widthMax / 2.);
809  i_sector.second.PWidthDiffVsMaxStrip =
810  secDir.make<TProfile>("p_widthDiffVsMaxStrip",
811  "(w_{p} - w_{cl}) vs. n_{cl,max};n_{cl,max};w_{p} - w_{cl} [# strips]",
812  800,
813  -10.,
814  790.);
815 
816  i_sector.second.WidthDiffVsSigmaXHit =
817  secDir.make<TH2F>("h2_widthDiffVsSigmaXHit",
818  "(w_{p} - w_{cl}) vs. #sigma_{hit,x};#sigma_{hit,x} [cm];w_{p} - w_{cl} [# strips]",
819  100,
820  0.,
821  sigmaXMax,
822  100,
823  -10.,
824  10.);
825  i_sector.second.PWidthDiffVsSigmaXHit =
826  secDir.make<TProfile>("p_widthDiffVsSigmaXHit",
827  "(w_{p} - w_{cl}) vs. #sigma_{hit,x};#sigma_{hit,x} [cm];w_{p} - w_{cl} [# strips]",
828  100,
829  0.,
830  sigmaXMax);
831 
832  i_sector.second.WidthVsPhiSensX =
833  secDir.make<TH2F>("h2_widthVsPhiSensX",
834  "w_{cl} vs. #phi_{module,x};#phi_{module,x} [ ^{o}];w_{cl} [# strips]",
835  93,
836  -93,
837  93,
838  static_cast<int>(widthMax),
839  0,
840  widthMax);
841  i_sector.second.PWidthVsPhiSensX = secDir.make<TProfile>(
842  "p_widthVsPhiSensX", "w_{cl} vs. #phi_{module,x};#phi_{module,x} [ ^{o}];w_{cl} [# strips]", 93, -93, 93);
843  }
844 
845  // Hit Parameters (transform errors and residuals from [cm] in [mum])
846  i_sector.second.m_correlationHistsX["SigmaXHit"] = i_sector.second.bookCorrHistsX(
847  "SigmaXHit", "hit error", "#sigma_{hit,x}", "[#mum]", 105, 20, sigmaXMin * 10000., sigmaXMax * 10000., "np");
848  i_sector.second.m_correlationHistsX["SigmaXTrk"] = i_sector.second.bookCorrHistsX(
849  "SigmaXTrk", "track error", "#sigma_{trk,x}", "[#mum]", 105, 20, sigmaXMin * 10000., sigmaXMax * 10000., "np");
850  i_sector.second.m_correlationHistsX["SigmaX"] = i_sector.second.bookCorrHistsX(
851  "SigmaX", "residual error", "#sigma_{r,x}", "[#mum]", 105, 20, sigmaXMin * 10000., sigmaXMax * 10000., "np");
852  i_sector.second.m_correlationHistsX["PhiSens"] = i_sector.second.bookCorrHistsX(
853  "PhiSens", "track angle on sensor", "#phi_{module}", "[ ^{o}]", 96, 48, -3, 93, "nphtr");
854  i_sector.second.m_correlationHistsX["PhiSensX"] = i_sector.second.bookCorrHistsX(
855  "PhiSensX", "track angle on sensor", "#phi_{module,x}", "[ ^{o}]", 186, 93, -phiSensXMax, phiSensXMax, "nphtr");
856  i_sector.second.m_correlationHistsX["PhiSensY"] = i_sector.second.bookCorrHistsX(
857  "PhiSensY", "track angle on sensor", "#phi_{module,y}", "[ ^{o}]", 186, 93, -93, 93, "nphtr");
858 
859  i_sector.second.XHit = secDir.make<TH1F>("h_XHit", " hit measurement x_{hit};x_{hit} [cm];# hits", 100, -20, 20);
860  i_sector.second.XTrk = secDir.make<TH1F>("h_XTrk", "track prediction x_{trk};x_{trk} [cm];# hits", 100, -20, 20);
861  i_sector.second.SigmaX2 =
862  secDir.make<TH1F>("h_SigmaX2",
863  "squared residual error #sigma_{r,x}^{2};#sigma_{r,x}^{2} [#mum^{2}];# hits",
864  105,
865  sigmaXMin * 10000.,
866  sigmaX2Max * 10000. * 10000.); //no mistake !
867  i_sector.second.ResX = secDir.make<TH1F>(
868  "h_ResX", "residual r_{x};x_{trk}-x_{hit} [#mum];# hits", 100, -resXAbsMax * 10000., resXAbsMax * 10000.);
869  i_sector.second.NorResX =
870  secDir.make<TH1F>("h_NorResX",
871  "normalized residual r_{x}/#sigma_{r,x};(x_{trk}-x_{hit})/#sigma_{r,x};# hits",
872  100,
873  -norResXAbsMax,
874  norResXAbsMax);
875  i_sector.second.ProbX = secDir.make<TH1F>(
876  "h_ProbX", "residual probability;prob(r_{x}^{2}/#sigma_{r,x}^{2},1);# hits", 60, probXMin, probXMax);
877 
878  i_sector.second.PhiSensXVsBarycentreX =
879  secDir.make<TH2F>("h2_phiSensXVsBarycentreX",
880  "#phi_{module,x} vs. b_{cl,x};b_{cl,x} [# channels];#phi_{module,x} [ ^{o}]",
881  200,
882  -10.,
883  790.,
884  93,
885  -93,
886  93);
887  i_sector.second.PPhiSensXVsBarycentreX =
888  secDir.make<TProfile>("p_phiSensXVsBarycentreX",
889  "#phi_{module,x} vs. b_{cl,x};b_{cl,x} [# channels];#phi_{module,x} [ ^{o}]",
890  200,
891  -10.,
892  790.);
893 
894  if (pixelSector) {
895  i_sector.second.m_correlationHistsY["SigmaYHit"] = i_sector.second.bookCorrHistsY(
896  "SigmaYHit", "hit error", "#sigma_{hit,y}", "[#mum]", 105, 20, sigmaXMin * 10000., sigmaXMax * 10000., "np");
897  i_sector.second.m_correlationHistsY["SigmaYTrk"] = i_sector.second.bookCorrHistsY(
898  "SigmaYTrk", "track error", "#sigma_{trk,y}", "[#mum]", 105, 20, sigmaXMin * 10000., sigmaXMax * 10000., "np");
899  i_sector.second.m_correlationHistsY["SigmaY"] = i_sector.second.bookCorrHistsY(
900  "SigmaY", "residual error", "#sigma_{r,y}", "[#mum]", 105, 20, sigmaXMin * 10000., sigmaXMax * 10000., "np");
901  i_sector.second.m_correlationHistsY["PhiSens"] = i_sector.second.bookCorrHistsY(
902  "PhiSens", "track angle on sensor", "#phi_{module}", "[ ^{o}]", 96, 48, -3, 93, "nphtr");
903  i_sector.second.m_correlationHistsY["PhiSensX"] = i_sector.second.bookCorrHistsY("PhiSensX",
904  "track angle on sensor",
905  "#phi_{module,x}",
906  "[ ^{o}]",
907  186,
908  93,
909  -phiSensXMax,
910  phiSensXMax,
911  "nphtr");
912  i_sector.second.m_correlationHistsY["PhiSensY"] = i_sector.second.bookCorrHistsY(
913  "PhiSensY", "track angle on sensor", "#phi_{module,y}", "[ ^{o}]", 186, 93, -93, 93, "nphtr");
914 
915  i_sector.second.YHit = secDir.make<TH1F>("h_YHit", " hit measurement y_{hit};y_{hit} [cm];# hits", 100, -20, 20);
916  i_sector.second.YTrk = secDir.make<TH1F>("h_YTrk", "track prediction y_{trk};y_{trk} [cm];# hits", 100, -20, 20);
917  i_sector.second.SigmaY2 =
918  secDir.make<TH1F>("h_SigmaY2",
919  "squared residual error #sigma_{r,y}^{2};#sigma_{r,y}^{2} [#mum^{2}];# hits",
920  105,
921  sigmaXMin * 10000.,
922  sigmaX2Max * 10000. * 10000.); //no mistake !
923  i_sector.second.ResY = secDir.make<TH1F>(
924  "h_ResY", "residual r_{y};y_{trk}-y_{hit} [#mum];# hits", 100, -resXAbsMax * 10000., resXAbsMax * 10000.);
925  i_sector.second.NorResY =
926  secDir.make<TH1F>("h_NorResY",
927  "normalized residual r_{y}/#sigma_{r,y};(y_{trk}-y_{hit})/#sigma_{r,y};# hits",
928  100,
929  -norResXAbsMax,
930  norResXAbsMax);
931  i_sector.second.ProbY = secDir.make<TH1F>(
932  "h_ProbY", "residual probability;prob(r_{y}^{2}/#sigma_{r,y}^{2},1);# hits", 60, probXMin, probXMax);
933 
934  i_sector.second.PhiSensYVsBarycentreY =
935  secDir.make<TH2F>("h2_phiSensYVsBarycentreY",
936  "#phi_{module,y} vs. b_{cl,y};b_{cl,y} [# channels];#phi_{module,y} [ ^{o}]",
937  200,
938  -10.,
939  790.,
940  93,
941  -93,
942  93);
943  i_sector.second.PPhiSensYVsBarycentreY =
944  secDir.make<TProfile>("p_phiSensYVsBarycentreY",
945  "#phi_{module,y} vs. b_{cl,y};b_{cl,y} [# channels];#phi_{module,y} [ ^{o}]",
946  200,
947  -10.,
948  790.);
949  }
950 
951  // Track Parameters
952  i_sector.second.m_correlationHistsX["HitsValid"] =
953  i_sector.second.bookCorrHistsX("HitsValid", "# hits", "[valid]", 50, 0, 50, "npt");
954  i_sector.second.m_correlationHistsX["HitsInvalid"] =
955  i_sector.second.bookCorrHistsX("HitsInvalid", "# hits", "[invalid]", 20, 0, 20, "npt");
956  i_sector.second.m_correlationHistsX["Hits2D"] =
957  i_sector.second.bookCorrHistsX("Hits2D", "# hits", "[2D]", 20, 0, 20, "npt");
958  i_sector.second.m_correlationHistsX["LayersMissed"] =
959  i_sector.second.bookCorrHistsX("LayersMissed", "# layers", "[missed]", 10, 0, 10, "npt");
960  i_sector.second.m_correlationHistsX["HitsPixel"] =
961  i_sector.second.bookCorrHistsX("HitsPixel", "# hits", "[pixel]", 10, 0, 10, "npt");
962  i_sector.second.m_correlationHistsX["HitsStrip"] =
963  i_sector.second.bookCorrHistsX("HitsStrip", "# hits", "[strip]", 40, 0, 40, "npt");
964  i_sector.second.m_correlationHistsX["HitsGood"] =
965  i_sector.second.bookCorrHistsX("HitsGood", "# hits", "[good]", 50, 0, 50, "npt");
966  i_sector.second.m_correlationHistsX["NorChi2"] =
967  i_sector.second.bookCorrHistsX("NorChi2", "#chi^{2}/f", "", 50, 0, norChi2Max, "npr");
968  i_sector.second.m_correlationHistsX["Theta"] =
969  i_sector.second.bookCorrHistsX("Theta", "#theta", "[ ^{o}]", 40, -10, 190, "npt");
970  i_sector.second.m_correlationHistsX["Phi"] =
971  i_sector.second.bookCorrHistsX("Phi", "#phi", "[ ^{o}]", 76, -190, 190, "npt");
972  i_sector.second.m_correlationHistsX["D0Beamspot"] =
973  i_sector.second.bookCorrHistsX("D0Beamspot", "d_{0, BS}", "[cm]", 40, -d0Max, d0Max, "npt");
974  i_sector.second.m_correlationHistsX["Dz"] =
975  i_sector.second.bookCorrHistsX("Dz", "d_{z}", "[cm]", 40, -dzMax, dzMax, "npt");
976  i_sector.second.m_correlationHistsX["Pt"] =
977  i_sector.second.bookCorrHistsX("Pt", "p_{t}", "[GeV]", 50, 0, pMax, "npt");
978  i_sector.second.m_correlationHistsX["P"] = i_sector.second.bookCorrHistsX("P", "|p|", "[GeV]", 50, 0, pMax, "npt");
979  i_sector.second.m_correlationHistsX["InvP"] =
980  i_sector.second.bookCorrHistsX("InvP", "1/|p|", "[GeV^{-1}]", 25, 0, invPMax, "t");
981  i_sector.second.m_correlationHistsX["MeanAngle"] =
982  i_sector.second.bookCorrHistsX("MeanAngle", "<#phi_{module}>", "[ ^{o}]", 25, -5, 95, "npt");
983  //i_sector.second.m_correlationHistsX[""] = i_sector.second.bookCorrHistsX("","","",,,,"nphtr");
984 
985  if (pixelSector) {
986  i_sector.second.m_correlationHistsY["HitsValid"] =
987  i_sector.second.bookCorrHistsY("HitsValid", "# hits", "[valid]", 50, 0, 50, "npt");
988  i_sector.second.m_correlationHistsY["HitsInvalid"] =
989  i_sector.second.bookCorrHistsY("HitsInvalid", "# hits", "[invalid]", 20, 0, 20, "npt");
990  i_sector.second.m_correlationHistsY["Hits2D"] =
991  i_sector.second.bookCorrHistsY("Hits2D", "# hits", "[2D]", 20, 0, 20, "npt");
992  i_sector.second.m_correlationHistsY["LayersMissed"] =
993  i_sector.second.bookCorrHistsY("LayersMissed", "# layers", "[missed]", 10, 0, 10, "npt");
994  i_sector.second.m_correlationHistsY["HitsPixel"] =
995  i_sector.second.bookCorrHistsY("HitsPixel", "# hits", "[pixel]", 10, 0, 10, "npt");
996  i_sector.second.m_correlationHistsY["HitsStrip"] =
997  i_sector.second.bookCorrHistsY("HitsStrip", "# hits", "[strip]", 40, 0, 40, "npt");
998  i_sector.second.m_correlationHistsY["HitsGood"] =
999  i_sector.second.bookCorrHistsY("HitsGood", "# hits", "[good]", 50, 0, 50, "npt");
1000  i_sector.second.m_correlationHistsY["NorChi2"] =
1001  i_sector.second.bookCorrHistsY("NorChi2", "#chi^{2}/f", "", 50, 0, norChi2Max, "npr");
1002  i_sector.second.m_correlationHistsY["Theta"] =
1003  i_sector.second.bookCorrHistsY("Theta", "#theta", "[ ^{o}]", 40, -10, 190, "npt");
1004  i_sector.second.m_correlationHistsY["Phi"] =
1005  i_sector.second.bookCorrHistsY("Phi", "#phi", "[ ^{o}]", 76, -190, 190, "npt");
1006  i_sector.second.m_correlationHistsY["D0Beamspot"] =
1007  i_sector.second.bookCorrHistsY("D0Beamspot", "d_{0, BS}", "[cm]", 40, -d0Max, d0Max, "npt");
1008  i_sector.second.m_correlationHistsY["Dz"] =
1009  i_sector.second.bookCorrHistsY("Dz", "d_{z}", "[cm]", 40, -dzMax, dzMax, "npt");
1010  i_sector.second.m_correlationHistsY["Pt"] =
1011  i_sector.second.bookCorrHistsY("Pt", "p_{t}", "[GeV]", 50, 0, pMax, "npt");
1012  i_sector.second.m_correlationHistsY["P"] =
1013  i_sector.second.bookCorrHistsY("P", "|p|", "[GeV]", 50, 0, pMax, "npt");
1014  i_sector.second.m_correlationHistsY["InvP"] =
1015  i_sector.second.bookCorrHistsY("InvP", "1/|p|", "[GeV^{-1}]", 25, 0, invPMax, "t");
1016  i_sector.second.m_correlationHistsY["MeanAngle"] =
1017  i_sector.second.bookCorrHistsY("MeanAngle", "<#phi_{module}>", "[ ^{o}]", 25, -5, 95, "npt");
1018  }
1019 
1020  // (transform errors and residuals from [cm] in [mum])
1021  for (auto const& i_errHists : v_errHists) {
1022  double xMin(0.01 * (i_errHists - 1)), xMax(0.01 * (i_errHists));
1023  std::stringstream sigmaXHit, sigmaXTrk, sigmaX;
1024  sigmaXHit << "h_sigmaXHit_" << i_errHists;
1025  sigmaXTrk << "h_sigmaXTrk_" << i_errHists;
1026  sigmaX << "h_sigmaX_" << i_errHists;
1027  i_sector.second.m_sigmaX["sigmaXHit"].push_back(
1028  secDir.make<TH1F>(sigmaXHit.str().c_str(),
1029  "hit error #sigma_{hit,x};#sigma_{hit,x} [#mum];# hits",
1030  100,
1031  xMin * 10000.,
1032  xMax * 10000.));
1033  i_sector.second.m_sigmaX["sigmaXTrk"].push_back(
1034  secDir.make<TH1F>(sigmaXTrk.str().c_str(),
1035  "track error #sigma_{trk,x};#sigma_{trk,x} [#mum];# hits",
1036  100,
1037  xMin * 10000.,
1038  xMax * 10000.));
1039  i_sector.second.m_sigmaX["sigmaX"].push_back(
1040  secDir.make<TH1F>(sigmaX.str().c_str(),
1041  "residual error #sigma_{r,x};#sigma_{r,x} [#mum];# hits",
1042  100,
1043  xMin * 10000.,
1044  xMax * 10000.));
1045  if (pixelSector) {
1046  std::stringstream sigmaYHit, sigmaYTrk, sigmaY;
1047  sigmaYHit << "h_sigmaYHit_" << i_errHists;
1048  sigmaYTrk << "h_sigmaYTrk_" << i_errHists;
1049  sigmaY << "h_sigmaY_" << i_errHists;
1050  i_sector.second.m_sigmaY["sigmaYHit"].push_back(
1051  secDir.make<TH1F>(sigmaYHit.str().c_str(),
1052  "hit error #sigma_{hit,y};#sigma_{hit,y} [#mum];# hits",
1053  100,
1054  xMin * 10000.,
1055  xMax * 10000.));
1056  i_sector.second.m_sigmaY["sigmaYTrk"].push_back(
1057  secDir.make<TH1F>(sigmaYTrk.str().c_str(),
1058  "track error #sigma_{trk,y};#sigma_{trk,y} [#mum];# hits",
1059  100,
1060  xMin * 10000.,
1061  xMax * 10000.));
1062  i_sector.second.m_sigmaY["sigmaY"].push_back(
1063  secDir.make<TH1F>(sigmaY.str().c_str(),
1064  "residual error #sigma_{r,y};#sigma_{r,y} [#mum];# hits",
1065  100,
1066  xMin * 10000.,
1067  xMax * 10000.));
1068  }
1069  }
1070  }
1071 }
1072 
1074  std::vector<unsigned int> v_errHists(parameterSet_.getParameter<std::vector<unsigned int> >("vErrHists"));
1075  for (std::vector<unsigned int>::iterator i_errHists = v_errHists.begin(); i_errHists != v_errHists.end();
1076  ++i_errHists) {
1077  for (std::vector<unsigned int>::iterator i_errHists2 = i_errHists; i_errHists2 != v_errHists.end();) {
1078  ++i_errHists2;
1079  if (*i_errHists == *i_errHists2) {
1080  edm::LogError("BookSectorHists") << "Value of vErrHists in config exists twice: " << *i_errHists
1081  << "\n... delete one of both";
1082  v_errHists.erase(i_errHists2);
1083  }
1084  }
1085  }
1086 
1087  for (auto& i_sector : m_tkSector_) {
1088  edm::Service<TFileService> fileService;
1089  if (!fileService) {
1090  throw edm::Exception(edm::errors::Configuration, "TFileService is not registered in cfg file");
1091  }
1092 
1093  std::stringstream sector;
1094  sector << "Sector_" << i_sector.first;
1095  TFileDirectory secDir = fileService->mkdir(sector.str());
1096 
1097  // Dummy histo containing the sector name as title
1098  i_sector.second.Name = secDir.make<TH1F>("z_name", i_sector.second.name.c_str(), 1, 0, 1);
1099 
1100  // Do not book histos for empty sectors
1101  if (i_sector.second.v_rawId.empty()) {
1102  continue;
1103  }
1104 
1105  // Distributions in each interval (stay in [cm], to have all calculations in [cm])
1106  if (m_resErrBins_
1107  .empty()) { // default if no selection taken into account: calculate APE with one bin with residual error 0-100um
1108  m_resErrBins_[1].first = 0.;
1109  m_resErrBins_[1].second = 0.01;
1110  }
1111  for (auto const& i_errBins : m_resErrBins_) {
1112  std::stringstream interval;
1113  interval << "Interval_" << i_errBins.first;
1114  TFileDirectory intDir = secDir.mkdir(interval.str());
1115  i_sector.second.m_binnedHists[i_errBins.first]["sigmaX"] =
1116  intDir.make<TH1F>("h_sigmaX", "residual resolution #sigma_{x};#sigma_{x} [cm];# hits", 100, 0., 0.01);
1117  i_sector.second.m_binnedHists[i_errBins.first]["norResX"] = intDir.make<TH1F>(
1118  "h_norResX", "normalized residual r_{x}/#sigma_{r,x};(x_{trk}-x_{hit})/#sigma_{r,x};# hits", 100, -10, 10);
1119  if (i_sector.second.isPixel) {
1120  i_sector.second.m_binnedHists[i_errBins.first]["sigmaY"] =
1121  intDir.make<TH1F>("h_sigmaY", "residual resolution #sigma_{y};#sigma_{y} [cm];# hits", 100, 0., 0.01);
1122  i_sector.second.m_binnedHists[i_errBins.first]["norResY"] = intDir.make<TH1F>(
1123  "h_norResY", "normalized residual r_{y}/#sigma_{r,y};(y_{trk}-y_{hit})/#sigma_{r,y};# hits", 100, -10, 10);
1124  }
1125  }
1126 
1127  TFileDirectory resDir = secDir.mkdir("Results");
1128 
1129  // TTree containing rawIds of all modules in sector
1130  unsigned int rawId(0);
1131  i_sector.second.RawId = resDir.make<TTree>("rawIdTree", "Tree containing rawIds of all modules in sector");
1132  i_sector.second.RawId->Branch("RawId", &rawId, "RawId/i");
1133  for (auto const& i_rawId : i_sector.second.v_rawId) {
1134  rawId = i_rawId;
1135  i_sector.second.RawId->Fill();
1136  }
1137 
1138  // Result plots (one hist per sector containing one bin per interval)
1139  // (transform errors and residuals from [cm] in [mum])
1140  std::vector<double> v_binX(parameterSet_.getParameter<std::vector<double> >("residualErrorBinning"));
1141  for (auto& i_binX : v_binX) {
1142  i_binX *= 10000.;
1143  }
1144  i_sector.second.EntriesX =
1145  resDir.make<TH1F>("h_entriesX", "# hits used;#sigma_{x} [#mum];# hits", v_binX.size() - 1, &(v_binX[0]));
1146  if (i_sector.second.isPixel) {
1147  i_sector.second.EntriesY =
1148  resDir.make<TH1F>("h_entriesY", "# hits used;#sigma_{y} [#mum];# hits", v_binX.size() - 1, &(v_binX[0]));
1149  }
1150 
1151  // In fact these are un-needed Analyzer plots, but I want to have them always for every sector visible
1152  // (transform errors and residuals from [cm] in [mum])
1153  i_sector.second.ResX = resDir.make<TH1F>(
1154  "h_ResX", "residual r_{x};x_{trk}-x_{hit} [#mum];# hits", 100, -0.03 * 10000., 0.03 * 10000.);
1155  i_sector.second.NorResX = resDir.make<TH1F>(
1156  "h_NorResX", "normalized residual r_{x}/#sigma_{r,x};(x_{trk}-x_{hit})/#sigma_{r,x};# hits", 100, -5., 5.);
1157  if (i_sector.second.isPixel) {
1158  i_sector.second.ResY = resDir.make<TH1F>(
1159  "h_ResY", "residual r_{y};y_{trk}-y_{hit} [#mum];# hits", 100, -0.03 * 10000., 0.03 * 10000.);
1160  i_sector.second.NorResY = resDir.make<TH1F>(
1161  "h_NorResY", "normalized residual r_{y}/#sigma_{r,y};(y_{trk}-y_{hit})/#sigma_{r,y};# hits", 100, -5., 5.);
1162  }
1163  }
1164 }
1165 
1166 // -----------------------------------------------------------------------------------------------------------
1167 
1169  bool zoomHists(parameterSet_.getParameter<bool>("zoomHists"));
1170 
1171  int trackSizeBins = zoomHists ? 6 : 201;
1172  double trackSizeMax = trackSizeBins - 1;
1173 
1174  double chi2Max = zoomHists ? 100. : 2000.;
1175  double norChi2Max = zoomHists ? 5. : 1000.;
1176  double d0max = zoomHists ? 0.02 : 40.; // cosmics: 100.|100.
1177  double dzmax = zoomHists ? 15. : 100.; // cosmics: 200.|600.
1178  double pMax = zoomHists ? 200. : 2000.;
1179 
1180  edm::Service<TFileService> fileService;
1181  TFileDirectory evtDir = fileService->mkdir("EventVariables");
1183  evtDir.make<TH1F>("h_trackSize", "# tracks [all];# tracks;# events", trackSizeBins, -1, trackSizeMax);
1185  evtDir.make<TH1F>("h_trackSizeGood", "# tracks [good];# tracks;# events", trackSizeBins, -1, trackSizeMax);
1186  TFileDirectory trkDir = fileService->mkdir("TrackVariables");
1187  tkDetector_.HitsSize = trkDir.make<TH1F>("h_hitsSize", "# hits;# hits;# tracks", 51, -1, 50);
1188  tkDetector_.HitsValid = trkDir.make<TH1F>("h_hitsValid", "# hits [valid];# hits [valid];# tracks", 51, -1, 50);
1190  trkDir.make<TH1F>("h_hitsInvalid", "# hits [invalid];# hits [invalid];# tracks", 21, -1, 20);
1191  tkDetector_.Hits2D = trkDir.make<TH1F>("h_hits2D", "# hits [2D];# hits [2D];# tracks", 21, -1, 20);
1193  trkDir.make<TH1F>("h_layersMissed", "# layers [missed];# layers [missed];# tracks", 11, -1, 10);
1194  tkDetector_.HitsPixel = trkDir.make<TH1F>("h_hitsPixel", "# hits [pixel];# hits [pixel];# tracks", 11, -1, 10);
1195  tkDetector_.HitsStrip = trkDir.make<TH1F>("h_hitsStrip", "# hits [strip];# hits [strip];# tracks", 41, -1, 40);
1196  tkDetector_.Charge = trkDir.make<TH1F>("h_charge", "charge q;q [e];# tracks", 5, -2, 3);
1197  tkDetector_.Chi2 = trkDir.make<TH1F>("h_chi2", " #chi^{2};#chi^{2};# tracks", 100, 0, chi2Max);
1198  tkDetector_.Ndof = trkDir.make<TH1F>("h_ndof", "# degrees of freedom f;f;# tracks", 101, -1, 100);
1199  tkDetector_.NorChi2 = trkDir.make<TH1F>("h_norChi2", "normalized #chi^{2};#chi^{2}/f;# tracks", 200, 0, norChi2Max);
1200  tkDetector_.Prob = trkDir.make<TH1F>("h_prob", " #chi^{2} probability;prob(#chi^{2},f);# tracks", 50, 0, 1);
1201  tkDetector_.Eta = trkDir.make<TH1F>("h_eta", "pseudorapidity #eta;#eta;# tracks", 100, -5, 5);
1202  tkDetector_.EtaErr = trkDir.make<TH1F>("h_etaErr", "Error of #eta;#sigma(#eta);# tracks", 100, 0, 0.001);
1204  trkDir.make<TH1F>("h_etaSig", "Significance of #eta;#eta/#sigma(#eta);# tracks", 100, -20000, 20000);
1205  tkDetector_.Theta = trkDir.make<TH1F>("h_theta", "polar angle #theta;#theta [ ^{o}];# tracks", 100, -10, 190);
1206  tkDetector_.Phi = trkDir.make<TH1F>("h_phi", "azimuth angle #phi;#phi [ ^{o}];# tracks", 190, -190, 190);
1207  tkDetector_.PhiErr = trkDir.make<TH1F>("h_phiErr", "Error of #phi;#sigma(#phi) [ ^{o}];# tracks", 100, 0, 0.04);
1209  trkDir.make<TH1F>("h_phiSig", "Significance of #phi;#phi/#sigma(#phi) [ ^{o}];# tracks", 100, -50000, 50000);
1210  tkDetector_.D0Beamspot = trkDir.make<TH1F>(
1211  "h_d0Beamspot", "Closest approach d_{0} wrt. beamspot;d_{0, BS} [cm];# tracks", 200, -d0max, d0max);
1213  trkDir.make<TH1F>("h_d0BeamspotErr", "Error of d_{0, BS};#sigma(d_{0, BS}) [cm];# tracks", 200, 0, 0.01);
1214  tkDetector_.D0BeamspotSig = trkDir.make<TH1F>(
1215  "h_d0BeamspotSig", "Significance of d_{0, BS};d_{0, BS}/#sigma(d_{0, BS});# tracks", 100, -5, 5);
1216  tkDetector_.Dz = trkDir.make<TH1F>("h_dz", "Closest approach d_{z};d_{z} [cm];# tracks", 200, -dzmax, dzmax);
1217  tkDetector_.DzErr = trkDir.make<TH1F>("h_dzErr", "Error of d_{z};#sigma(d_{z}) [cm];# tracks", 200, 0, 0.01);
1218  tkDetector_.DzSig =
1219  trkDir.make<TH1F>("h_dzSig", "Significance of d_{z};d_{z}/#sigma(d_{z});# tracks", 100, -10000, 10000);
1220  tkDetector_.Pt = trkDir.make<TH1F>("h_pt", "transverse momentum p_{t};p_{t} [GeV];# tracks", 100, 0, pMax);
1221  tkDetector_.PtErr = trkDir.make<TH1F>("h_ptErr", "Error of p_{t};#sigma(p_{t}) [GeV];# tracks", 100, 0, 1.6);
1222  tkDetector_.PtSig = trkDir.make<TH1F>("h_ptSig", "Significance of p_{t};p_{t}/#sigma(p_{t});# tracks", 100, 0, 200);
1223  tkDetector_.P = trkDir.make<TH1F>("h_p", "momentum magnitude |p|;|p| [GeV];# tracks", 100, 0, pMax);
1224  tkDetector_.MeanAngle = trkDir.make<TH1F>(
1225  "h_meanAngle", "mean angle on module <#phi_{module}>;<#phi_{module}> [ ^{o}];# tracks", 100, -5, 95);
1226  tkDetector_.HitsGood = trkDir.make<TH1F>("h_hitsGood", "# hits [good];# hits [good];# tracks", 51, -1, 50);
1227 
1228  tkDetector_.MeanAngleVsHits = trkDir.make<TH2F>(
1229  "h2_meanAngleVsHits", "<#phi_{module}> vs. # hits;# hits;<#phi_{module}> [ ^{o}]", 51, -1, 50, 50, -5, 95);
1231  trkDir.make<TH2F>("h2_hitsGoodVsHitsValid",
1232  "# hits [good] vs. # hits [valid];# hits [valid];# hits [good]",
1233  51,
1234  -1,
1235  50,
1236  51,
1237  -1,
1238  50);
1240  trkDir.make<TH2F>("h2_hitsPixelVsEta", "# hits [pixel] vs. #eta;#eta;# hits [pixel]", 60, -3, 3, 11, -1, 10);
1241  tkDetector_.HitsPixelVsTheta = trkDir.make<TH2F>(
1242  "h2_hitsPixelVsTheta", "# hits [pixel] vs. #theta;#theta;# hits [pixel]", 100, -10, 190, 11, -1, 10);
1244  trkDir.make<TH2F>("h2_hitsStripVsEta", "# hits [strip] vs. #eta;#eta;# hits [strip]", 60, -3, 3, 31, -1, 40);
1245  tkDetector_.HitsStripVsTheta = trkDir.make<TH2F>(
1246  "h2_hitsStripVsTheta", "# hits [strip] vs. #theta;#theta;# hits [strip]", 100, -10, 190, 31, -1, 40);
1247  tkDetector_.PtVsEta = trkDir.make<TH2F>("h2_ptVsEta", "p_{t} vs. #eta;#eta;p_{t} [GeV]", 60, -3, 3, 100, 0, pMax);
1249  trkDir.make<TH2F>("h2_ptVsTheta", "p_{t} vs. #theta;#theta;p_{t} [GeV]", 100, -10, 190, 100, 0, pMax);
1250 
1251  tkDetector_.PMeanAngleVsHits = trkDir.make<TProfile>(
1252  "p_meanAngleVsHits", "<#phi_{module}> vs. # hits;# hits;<#phi_{module}> [ ^{o}]", 51, -1, 50);
1253  tkDetector_.PHitsGoodVsHitsValid = trkDir.make<TProfile>(
1254  "p_hitsGoodVsHitsValid", "# hits [good] vs. # hits [valid];# hits [valid];# hits [good]", 51, -1, 50);
1256  trkDir.make<TProfile>("p_hitsPixelVsEta", "# hits [pixel] vs. #eta;#eta;# hits [pixel]", 60, -3, 3);
1258  trkDir.make<TProfile>("p_hitsPixelVsTheta", "# hits [pixel] vs. #theta;#theta;# hits [pixel]", 100, -10, 190);
1260  trkDir.make<TProfile>("p_hitsStripVsEta", "# hits [strip] vs. #eta;#eta;# hits [strip]", 60, -3, 3);
1262  trkDir.make<TProfile>("p_hitsStripVsTheta", "# hits [strip] vs. #theta;#theta;# hits [strip]", 100, -10, 190);
1263  tkDetector_.PPtVsEta = trkDir.make<TProfile>("p_ptVsEta", "p_{t} vs. #eta;#eta;p_{t} [GeV]", 60, -3, 3);
1264  tkDetector_.PPtVsTheta = trkDir.make<TProfile>("p_ptVsTheta", "p_{t} vs. #theta;#theta;p_{t} [GeV]", 100, -10, 190);
1265 }
1266 
1267 // -----------------------------------------------------------------------------------------------------------
1268 
1270  const Trajectory& traj,
1271  const reco::BeamSpot& beamSpot) {
1272  const math::XYZPoint beamPoint(beamSpot.x0(), beamSpot.y0(), beamSpot.z0());
1273  double d0BeamspotErr =
1274  std::sqrt(track.d0Error() * track.d0Error() + 0.5 * beamSpot.BeamWidthX() * beamSpot.BeamWidthX() +
1275  0.5 * beamSpot.BeamWidthY() * beamSpot.BeamWidthY());
1276 
1277  const static TrajectoryStateCombiner tsoscomb;
1278 
1279  const reco::HitPattern& hitPattern(track.hitPattern());
1280 
1282 
1283  trkParams.hitsSize = track.recHitsSize();
1284  trkParams.hitsValid = track.found(); // invalid is every hit from every single module that expects a hit
1285  trkParams.hitsInvalid = trkParams.hitsSize - trkParams.hitsValid;
1286  trkParams.layersMissed =
1287  track.lost(); // lost hit means, that a crossed layer doesn't contain a hit (can be more than one invalid hit)
1288  trkParams.hitsPixel = hitPattern.numberOfValidPixelHits();
1289  trkParams.hitsStrip = hitPattern.numberOfValidStripHits();
1290  trkParams.charge = track.charge();
1291  trkParams.chi2 = track.chi2();
1292  trkParams.ndof = track.ndof();
1293  trkParams.norChi2 = trkParams.chi2 / trkParams.ndof;
1294  trkParams.prob = TMath::Prob(trkParams.chi2, trkParams.ndof);
1295  trkParams.eta = track.eta();
1296  trkParams.etaErr = track.etaError();
1297  trkParams.theta = track.theta();
1298  trkParams.phi = track.phi();
1299  trkParams.phiErr = track.phiError();
1300  trkParams.d0 = track.d0();
1301  trkParams.d0Beamspot = -1. * track.dxy(beamPoint);
1302  trkParams.d0BeamspotErr = d0BeamspotErr;
1303  trkParams.dz = track.dz();
1304  trkParams.dzErr = track.dzError();
1305  trkParams.dzBeamspot = track.dz(beamPoint);
1306  trkParams.p = track.p();
1307  trkParams.pt = track.pt();
1308  trkParams.ptErr = track.ptError();
1309 
1310  const std::vector<TrajectoryMeasurement>& v_meas = traj.measurements();
1311 
1312  int count2D(0);
1313  float meanPhiSensToNorm(0.F);
1314  for (auto const& i_meas : v_meas) {
1315  const TrajectoryMeasurement& meas = i_meas;
1316  const TransientTrackingRecHit& hit = *meas.recHit();
1317  const TrackingRecHit& recHit = *hit.hit();
1318  if (this->isHit2D(recHit))
1319  ++count2D;
1320 
1322  const align::LocalVector mom(tsos.localDirection());
1323  meanPhiSensToNorm += atan(fabs(sqrt(mom.x() * mom.x() + mom.y() * mom.y()) / mom.z()));
1324  }
1325  meanPhiSensToNorm *= (1. / static_cast<float>(trkParams.hitsSize));
1326 
1327  trkParams.hits2D = count2D;
1328  trkParams.meanPhiSensToNorm = meanPhiSensToNorm;
1329 
1330  if (parameterSet_.getParameter<bool>("applyTrackCuts")) {
1331  trackCut_ = false;
1332  if (trkParams.hitsStrip < 11 || trkParams.hits2D < 2 || trkParams.hitsPixel < 2 || //trkParams.hitsInvalid>2 ||
1333  trkParams.hitsStrip > 35 || trkParams.hitsPixel > 7 || trkParams.norChi2 > 5. || trkParams.pt < 25. ||
1334  trkParams.pt > 150. || std::abs(trkParams.d0Beamspot) > 0.02 || std::abs(trkParams.dz) > 15.)
1335  trackCut_ = true;
1336  } else {
1337  trackCut_ = false;
1338  }
1339 
1340  return trkParams;
1341 }
1342 
1344  const edm::EventSetup& iSetup) {
1346 
1347  const static TrajectoryStateCombiner tsoscomb;
1348 
1349  const TrajectoryMeasurement& meas = i_meas;
1350  const TransientTrackingRecHit& hit = *meas.recHit();
1351  const TrackingRecHit& recHit = *hit.hit();
1352  const TrajectoryStateOnSurface& tsos = tsoscomb(meas.forwardPredictedState(), meas.backwardPredictedState());
1353 
1354  const DetId& detId(hit.geographicalId());
1355  const DetId::Detector& detector = detId.det();
1356  if (detector != DetId::Tracker) {
1357  hitParams.hitState = TrackStruct::notInTracker;
1358  return hitParams;
1359  }
1360  const uint32_t rawId(detId.rawId());
1361 
1362  for (auto& i_sector : m_tkSector_) {
1363  for (auto const& i_rawId : i_sector.second.v_rawId) {
1364  if (rawId == i_rawId) {
1365  hitParams.v_sector.push_back(i_sector.first);
1366  break;
1367  }
1368  }
1369  }
1370 
1371  const align::LocalVector& mom(tsos.localDirection());
1372  int xMomentum(0), yMomentum(0), zMomentum(0);
1373  xMomentum = mom.x() > 0. ? 1 : -1;
1374  yMomentum = mom.y() > 0. ? 1 : -1;
1375  zMomentum = mom.z() > 0. ? 1 : -1;
1376  float phiSensX =
1377  std::atan(std::fabs(mom.x() / mom.z())) *
1378  static_cast<float>(
1379  m_tkTreeVar_[rawId].vDirection); // check for orientation of E- and B- Field (thoughts for barrel)
1380  float phiSensY = std::atan(std::fabs(mom.y() / mom.z())) * static_cast<float>(m_tkTreeVar_[rawId].vDirection);
1381  hitParams.phiSens = std::atan(std::fabs(std::sqrt(mom.x() * mom.x() + mom.y() * mom.y()) / mom.z()));
1382  hitParams.phiSensX = (xMomentum == zMomentum ? phiSensX : -phiSensX);
1383  hitParams.phiSensY = (yMomentum == zMomentum ? phiSensY : -phiSensY);
1384 
1385  if (!hit.isValid()) {
1386  hitParams.hitState = TrackStruct::invalid;
1387  return hitParams;
1388  }
1389 
1390  // Get local positions and errors of hit and track
1391  const LocalPoint& lPHit = hit.localPosition();
1392  const LocalPoint& lPTrk = tsos.localPosition();
1393 
1394  // use APE also for the hit error, while APE is automatically included in tsos error
1395  //
1396  // no need to add APE to hitError anymore by Ajay 27 Oct 2014
1397  const LocalError& errHitApe = hit.localPositionError(); // now sum of CPE+APE as said by MARCO?
1398  LocalError errorWithoutAPE;
1399 
1400  bool Pixel(false);
1401  bool Strip(false);
1402 
1405  Pixel = true;
1406  } else if (m_tkTreeVar_[rawId].subdetId == StripSubdetector::TIB ||
1407  m_tkTreeVar_[rawId].subdetId == StripSubdetector::TOB ||
1408  m_tkTreeVar_[rawId].subdetId == StripSubdetector::TID ||
1409  m_tkTreeVar_[rawId].subdetId == StripSubdetector::TEC) {
1410  Strip = true;
1411  } else {
1412  edm::LogWarning("FillHitVariables") << "cant identify wether hit is from pixel or strip";
1413  hitParams.hitState = TrackStruct::invalid;
1414  return hitParams;
1415  }
1416 
1417  if (!hit.detUnit()) {
1418  hitParams.hitState = TrackStruct::invalid;
1419  return hitParams;
1420  } // is it a single physical module?
1421  const GeomDetUnit& detUnit = *hit.detUnit();
1422 
1423  if (Pixel) {
1424  if (!dynamic_cast<const PixelTopology*>(&detUnit.type().topology())) {
1425  hitParams.hitState = TrackStruct::invalid;
1426  return hitParams;
1427  }
1428  const PixelGeomDetUnit* pixelDet = (const PixelGeomDetUnit*)(&detUnit);
1429  const LocalError& lape = pixelDet->localAlignmentError();
1430  if (lape.valid()) {
1431  errorWithoutAPE = LocalError(errHitApe.xx() - lape.xx(), errHitApe.xy() - lape.xy(), errHitApe.yy() - lape.yy());
1432  }
1433  }
1434  if (Strip) {
1435  if (!dynamic_cast<const StripTopology*>(&detUnit.type().topology())) {
1436  hitParams.hitState = TrackStruct::invalid;
1437  return hitParams;
1438  }
1439  const StripGeomDetUnit* stripDet = (const StripGeomDetUnit*)(&detUnit);
1440  const LocalError& lape = stripDet->localAlignmentError();
1441  if (lape.valid()) {
1442  errorWithoutAPE = LocalError(errHitApe.xx() - lape.xx(), errHitApe.xy() - lape.xy(), errHitApe.yy() - lape.yy());
1443  }
1444  }
1445 
1446  const LocalError& errHitWoApe = errorWithoutAPE;
1447  const LocalError& errTrk = tsos.localError().positionError();
1448 
1449  const StatePositionAndError2 positionAndError2Hit = this->positionAndError2(lPHit, errHitApe, hit);
1450  const StatePositionAndError2 positionAndError2HitWoApe = this->positionAndError2(lPHit, errHitWoApe, hit);
1451  edm::LogInfo("CalculateAPE") << "errHitWoApe " << errHitWoApe << "errHitApe " << errHitApe;
1452 
1453  const StatePositionAndError2 positionAndError2Trk = this->positionAndError2(lPTrk, errTrk, hit);
1454 
1455  const TrackStruct::HitState& stateHit(positionAndError2Hit.first);
1456  const TrackStruct::HitState& stateHitWoApe(positionAndError2HitWoApe.first);
1457  const TrackStruct::HitState& stateTrk(positionAndError2Trk.first);
1458 
1459  if (stateHit == TrackStruct::invalid || stateHitWoApe == TrackStruct::invalid || stateTrk == TrackStruct::invalid) {
1460  hitParams.hitState = TrackStruct::invalid;
1461  return hitParams;
1462  } else if (stateHit == TrackStruct::negativeError || stateHitWoApe == TrackStruct::negativeError ||
1463  stateTrk == TrackStruct::negativeError) {
1464  ++counter1;
1465  // Do not print error message by default
1466  //std::stringstream ss_error;
1467  //ss_error<<"Upper values belong to: ";
1468  //if(stateHit==TrackStruct::negativeError)ss_error<<"Hit without APE, ";
1469  //if(stateHitWoApe==TrackStruct::negativeError)ss_error<<"Hit with APE, ";
1470  //if(stateTrk==TrackStruct::negativeError)ss_error<<"Track,";
1471  //edm::LogError("Negative error Value")<<"@SUB=ApeEstimator::fillHitVariables"<<ss_error.str();
1473  return hitParams;
1474  }
1475 
1476  // Calculate residuals
1477 
1478  const float xHit = positionAndError2Hit.second.posX;
1479  const float xTrk = positionAndError2Trk.second.posX;
1480  const float yHit = positionAndError2Hit.second.posY;
1481  const float yTrk = positionAndError2Trk.second.posY;
1482 
1483  const float errXHit2(positionAndError2Hit.second.errX2);
1484  const float errXHitWoApe2(positionAndError2HitWoApe.second.errX2);
1485  const float errXTrk2(positionAndError2Trk.second.errX2);
1486  const float errYHit2(positionAndError2Hit.second.errY2);
1487  const float errYHitWoApe2(positionAndError2HitWoApe.second.errY2);
1488  const float errYTrk2(positionAndError2Trk.second.errY2);
1489 
1490  const float errXHit = std::sqrt(positionAndError2Hit.second.errX2);
1491  const float errXHitWoApe = std::sqrt(positionAndError2HitWoApe.second.errX2);
1492  const float errXTrk = std::sqrt(positionAndError2Trk.second.errX2);
1493  const float errYHit = std::sqrt(positionAndError2Hit.second.errY2);
1494  const float errYHitWoApe = std::sqrt(positionAndError2HitWoApe.second.errY2);
1495  const float errYTrk = std::sqrt(positionAndError2Trk.second.errY2);
1496 
1497  const float resX = xTrk - xHit;
1498  const float resY = yTrk - yHit;
1499 
1500  const float errX = std::sqrt(errXHit2 + errXTrk2);
1501  const float errXWoApe2 = errXHitWoApe2 + errXTrk2;
1502  const float errXWoApe = std::sqrt(errXWoApe2);
1503  const float errY = std::sqrt(errYHit2 + errYTrk2);
1504  const float errYWoApe2 = errYHitWoApe2 + errYTrk2;
1505  const float errYWoApe = std::sqrt(errYWoApe2);
1506 
1507  const float norResX = resX / errX;
1508  const float norResY = resY / errY;
1509 
1510  // Take global orientation into account for residuals (sign is not important for errors)
1511 
1512  float resXprime(999.F), resYprime(999.F), norResXprime(999.F), norResYprime(999.F);
1513  if (m_tkTreeVar_[rawId].uDirection == 1) {
1514  resXprime = resX;
1515  norResXprime = norResX;
1516  } else if (m_tkTreeVar_[rawId].uDirection == -1) {
1517  resXprime = -resX;
1518  norResXprime = -norResX;
1519  } else {
1520  edm::LogError("FillHitVariables") << "Incorrect value of uDirection, which gives global module orientation";
1521  hitParams.hitState = TrackStruct::invalid;
1522  return hitParams;
1523  }
1524  if (m_tkTreeVar_[rawId].vDirection == 1) {
1525  resYprime = resY;
1526  norResYprime = norResY;
1527  } else if (m_tkTreeVar_[rawId].vDirection == -1) {
1528  resYprime = -resY;
1529  norResYprime = -norResY;
1530  } else {
1531  edm::LogError("FillHitVariables") << "Incorrect value of vDirection, which gives global module orientation";
1532  hitParams.hitState = TrackStruct::invalid;
1533  return hitParams;
1534  }
1535 
1536  hitParams.xHit = xHit;
1537  hitParams.xTrk = xTrk;
1538 
1539  hitParams.errXHit = errXHit;
1540  hitParams.errXHitWoApe = errXHitWoApe;
1541  hitParams.errXTrk = errXTrk;
1542 
1543  hitParams.errX2 = errX * errX;
1544  hitParams.errX = errX;
1545  hitParams.errXWoApe = errXWoApe;
1546 
1547  hitParams.resX = resXprime;
1548  hitParams.norResX = norResXprime;
1549 
1550  const float norResX2(norResXprime * norResXprime);
1551  hitParams.probX = TMath::Prob(norResX2, 1);
1552 
1553  hitParams.yHit = yHit;
1554  hitParams.yTrk = yTrk;
1555 
1556  hitParams.errYHit = errYHit;
1557  hitParams.errYHitWoApe = errYHitWoApe;
1558  hitParams.errYTrk = errYTrk;
1559 
1560  hitParams.errY2 = errY * errY;
1561  hitParams.errY = errY;
1562  hitParams.errYWoApe = errYWoApe;
1563 
1564  hitParams.resY = resYprime;
1565  hitParams.norResY = norResYprime;
1566 
1567  const float norResY2(norResYprime * norResYprime);
1568  hitParams.probY = TMath::Prob(norResY2, 1);
1569 
1570  // Cluster parameters
1571 
1574  const SiPixelRecHit& pixelHit = dynamic_cast<const SiPixelRecHit&>(recHit);
1575  const SiPixelCluster& pixelCluster = *pixelHit.cluster();
1576 
1577  hitParams.chargePixel = pixelCluster.charge();
1578  hitParams.widthX = pixelCluster.sizeX();
1579  hitParams.baryStripX = pixelCluster.x();
1580  hitParams.widthY = pixelCluster.sizeY();
1581  hitParams.baryStripY = pixelCluster.y();
1582 
1583  hitParams.clusterProbabilityXY = pixelHit.clusterProbability(0);
1584  hitParams.clusterProbabilityQ = pixelHit.clusterProbability(2);
1585  hitParams.clusterProbabilityXYQ = pixelHit.clusterProbability(1);
1586  hitParams.logClusterProbability = std::log10(hitParams.clusterProbabilityXY);
1587 
1588  hitParams.isOnEdge = pixelHit.isOnEdge();
1589  hitParams.hasBadPixels = pixelHit.hasBadPixels();
1590  hitParams.spansTwoRoc = pixelHit.spansTwoROCs();
1591  hitParams.qBin = pixelHit.qBin();
1592 
1593  hitParams.isPixelHit = true;
1594  } else if (m_tkTreeVar_[rawId].subdetId == StripSubdetector::TIB ||
1595  m_tkTreeVar_[rawId].subdetId == StripSubdetector::TOB ||
1596  m_tkTreeVar_[rawId].subdetId == StripSubdetector::TID ||
1597  m_tkTreeVar_[rawId].subdetId == StripSubdetector::TEC) {
1598  if (!(dynamic_cast<const SiStripRecHit2D*>(&recHit) || dynamic_cast<const SiStripRecHit1D*>(&recHit))) {
1599  edm::LogError("FillHitVariables")
1600  << "RecHit in Strip is 'Matched' or 'Projected', but here all should be monohits per module";
1601  hitParams.hitState = TrackStruct::invalid;
1602  return hitParams;
1603  }
1604  const SiStripCluster* clusterPtr(nullptr);
1605  if (m_tkTreeVar_[rawId].subdetId == StripSubdetector::TIB ||
1606  m_tkTreeVar_[rawId].subdetId == StripSubdetector::TOB) {
1607  if (dynamic_cast<const SiStripRecHit1D*>(&recHit)) {
1608  const SiStripRecHit1D& stripHit = dynamic_cast<const SiStripRecHit1D&>(recHit);
1609  clusterPtr = &(*stripHit.cluster());
1610  } else if (dynamic_cast<const SiStripRecHit2D*>(&recHit)) {
1611  edm::LogWarning("FillHitVariables") << "Data has TIB/TOB hits as SiStripRecHit2D and not 1D. Probably data is "
1612  "processed with CMSSW<34X. Nevertheless everything should work fine";
1613  const SiStripRecHit2D& stripHit = dynamic_cast<const SiStripRecHit2D&>(recHit);
1614  clusterPtr = &(*stripHit.cluster());
1615  }
1616  } else if (m_tkTreeVar_[rawId].subdetId == StripSubdetector::TID ||
1617  m_tkTreeVar_[rawId].subdetId == StripSubdetector::TEC) {
1618  const SiStripRecHit2D& stripHit = dynamic_cast<const SiStripRecHit2D&>(recHit);
1619  clusterPtr = &(*stripHit.cluster());
1620  }
1621  if (!clusterPtr) {
1622  edm::LogError("FillHitVariables") << "Pointer to cluster not valid!!! This should never happen...";
1623  hitParams.hitState = TrackStruct::invalid;
1624  return hitParams;
1625  }
1626  const SiStripCluster& stripCluster(*clusterPtr);
1627 
1629 
1630  auto stripChargeL = siStripClusterInfo_.stripCharges().begin();
1631  auto stripChargeR = siStripClusterInfo_.stripCharges().end() - 1;
1632  const std::pair<uint16_t, uint16_t> stripChargeLR = std::make_pair(*stripChargeL, *stripChargeR);
1633 
1634  hitParams.chargeStrip = siStripClusterInfo_.charge();
1635  hitParams.widthX = siStripClusterInfo_.width();
1636  hitParams.baryStripX = siStripClusterInfo_.baryStrip() + 1.;
1638  hitParams.maxStrip = siStripClusterInfo_.maxStrip() + 1;
1639  hitParams.maxStripInv = m_tkTreeVar_[rawId].nStrips - hitParams.maxStrip + 1;
1640  hitParams.maxCharge = siStripClusterInfo_.maxCharge();
1641  hitParams.maxIndex = siStripClusterInfo_.maxIndex();
1642  hitParams.chargeOnEdges =
1643  static_cast<float>(stripChargeLR.first + stripChargeLR.second) / static_cast<float>(hitParams.chargeStrip);
1644  hitParams.chargeAsymmetry = static_cast<float>(stripChargeLR.first - stripChargeLR.second) /
1645  static_cast<float>(stripChargeLR.first + stripChargeLR.second);
1646  hitParams.chargeLRplus =
1647  static_cast<float>(siStripClusterInfo_.chargeLR().first + siStripClusterInfo_.chargeLR().second) /
1648  static_cast<float>(hitParams.chargeStrip);
1649  hitParams.chargeLRminus =
1650  static_cast<float>(siStripClusterInfo_.chargeLR().first - siStripClusterInfo_.chargeLR().second) /
1651  static_cast<float>(hitParams.chargeStrip);
1653 
1654  // Calculate projection length corrected by drift
1655  if (!hit.detUnit()) {
1656  hitParams.hitState = TrackStruct::invalid;
1657  return hitParams;
1658  } // is it a single physical module?
1659  const GeomDetUnit& detUnit = *hit.detUnit();
1660  if (!dynamic_cast<const StripTopology*>(&detUnit.type().topology())) {
1661  hitParams.hitState = TrackStruct::invalid;
1662  return hitParams;
1663  }
1664 
1665  const MagneticField* magField = &iSetup.getData(magFieldToken_);
1666  const SiStripLorentzAngle* lorentzAngle = &iSetup.getData(lorentzAngleToken_);
1667 
1668  const StripGeomDetUnit* stripDet = (const StripGeomDetUnit*)(&detUnit);
1669  LocalVector bField = (stripDet->surface()).toLocal(magField->inTesla(stripDet->surface().position()));
1670  float tanLorentzAnglePerTesla = lorentzAngle->getLorentzAngle(stripDet->geographicalId().rawId());
1671 
1672  float dirX = -tanLorentzAnglePerTesla * bField.y();
1673  float dirY = tanLorentzAnglePerTesla * bField.x();
1674  float dirZ = 1.; // E field always in z direction
1675  LocalVector driftDirection(dirX, dirY, dirZ);
1676 
1677  const Bounds& bounds = stripDet->specificSurface().bounds();
1678  float maxLength = std::sqrt(std::pow(bounds.length(), 2) + std::pow(bounds.width(), 2));
1679  float thickness = bounds.thickness();
1680 
1681  const StripTopology& topol = dynamic_cast<const StripTopology&>(detUnit.type().topology());
1682  LocalVector momentumDir(tsos.localDirection());
1683  LocalPoint momentumPos(tsos.localPosition());
1684  LocalVector scaledMomentumDir(momentumDir);
1685  if (momentumDir.z() > 0.)
1686  scaledMomentumDir *= std::fabs(thickness / momentumDir.z());
1687  else if (momentumDir.z() < 0.)
1688  scaledMomentumDir *= -std::fabs(thickness / momentumDir.z());
1689  else
1690  scaledMomentumDir *= maxLength / momentumDir.mag();
1691 
1692  float projEdge1 = topol.measurementPosition(momentumPos - 0.5 * scaledMomentumDir).x();
1693  if (projEdge1 < 0.)
1694  projEdge1 = 0.;
1695  else if (projEdge1 > m_tkTreeVar_[rawId].nStrips)
1696  projEdge1 = m_tkTreeVar_[rawId].nStrips;
1697  float projEdge2 = topol.measurementPosition(momentumPos + 0.5 * scaledMomentumDir).x();
1698  if (projEdge2 < 0.)
1699  projEdge1 = 0.;
1700  else if (projEdge2 > m_tkTreeVar_[rawId].nStrips)
1701  projEdge1 = m_tkTreeVar_[rawId].nStrips;
1702 
1703  float coveredStrips = std::fabs(projEdge2 - projEdge1);
1704 
1705  hitParams.projWidth = coveredStrips;
1706 
1707  } else {
1708  edm::LogError("FillHitVariables") << "Incorrect subdetector ID, hit not associated to tracker";
1709  hitParams.hitState = TrackStruct::notInTracker;
1710  return hitParams;
1711  }
1712 
1713  if (!hitParams.isModuleUsable) {
1714  hitParams.hitState = TrackStruct::invalid;
1715  return hitParams;
1716  }
1717 
1718  if (hitParams.v_sector.empty()) {
1720  return hitParams;
1721  }
1722 
1723  return hitParams;
1724  //}
1725 }
1726 
1728  const LocalError& localError,
1729  const TransientTrackingRecHit& hit) {
1731 
1732  const DetId& detId(hit.geographicalId());
1733  const uint32_t& rawId(detId.rawId());
1734  const unsigned int& subdetId(m_tkTreeVar_[rawId].subdetId);
1735 
1736  if (localError.xx() < 0. || localError.yy() < 0.) {
1737  // Do not print error message by default
1738  //edm::LogError("Negative error Value")<<"@SUB=ApeEstimator::fillHitVariables"
1739  // <<"One of the squared error methods gives negative result\n"
1740  // <<"\tSubdetector\tlocalError.xx()\tlocalError.yy()\n"
1741  // <<"\t"<<subdetId<<"\t\t"<<localError.xx()<<"\t"<<localError.yy();
1742  vPE2.first = TrackStruct::negativeError;
1743  return vPE2;
1744  }
1745 
1746  if (subdetId == PixelSubdetector::PixelBarrel || subdetId == PixelSubdetector::PixelEndcap ||
1747  subdetId == StripSubdetector::TIB || subdetId == StripSubdetector::TOB) {
1748  // Cartesian coordinates
1749  vPE2 = std::make_pair(TrackStruct::ok, this->rectangularPositionAndError2(localPoint, localError));
1750  } else if (subdetId == StripSubdetector::TID || subdetId == StripSubdetector::TEC) {
1751  // Local x in radial coordinates
1752  if (!hit.detUnit())
1753  return vPE2; // is it a single physical module?
1754  const GeomDetUnit& detUnit = *hit.detUnit();
1755 
1756  if (!dynamic_cast<const RadialStripTopology*>(&detUnit.type().topology()))
1757  return vPE2;
1758  const RadialStripTopology& topol = dynamic_cast<const RadialStripTopology&>(detUnit.type().topology());
1759 
1760  MeasurementError measError = topol.measurementError(localPoint, localError);
1761  if (measError.uu() < 0. || measError.vv() < 0.) {
1762  // Do not print error message by default
1763  //edm::LogError("Negative error Value")<<"@SUB=ApeEstimator::fillHitVariables"
1764  // <<"One of the squared error methods gives negative result\n"
1765  // <<"\tmeasError.uu()\tmeasError.vv()\n"
1766  // <<"\t"<<measError.uu()<<"\t"<<measError.vv()
1767  // <<"\n\nOriginalValues:\n"
1768  // <<localPoint.x()<<" "<<localPoint.y()<<"\n"
1769  // <<localError.xx()<<" "<<localError.yy()<<"\n"
1770  // <<"Subdet: "<<subdetId;
1771  vPE2.first = TrackStruct::negativeError;
1772  return vPE2;
1773  }
1774  vPE2 = std::make_pair(TrackStruct::ok, this->radialPositionAndError2(localPoint, localError, topol));
1775  } else {
1776  edm::LogError("FillHitVariables") << "Incorrect subdetector ID, hit not associated to tracker";
1777  }
1778 
1779  return vPE2;
1780 }
1781 
1783  const float x(lP.x());
1784  const float y(lP.y());
1785  const float errX2(lE.xx());
1786  const float errY2(lE.yy());
1787 
1788  return PositionAndError2(x, y, errX2, errY2);
1789 }
1790 
1792  const LocalError& lE,
1793  const RadialStripTopology& topol) {
1794  MeasurementPoint measPos = topol.measurementPosition(lP);
1795  MeasurementError measErr = topol.measurementError(lP, lE);
1796 
1797  const float r_0 = topol.originToIntersection();
1798  const float stripLength = topol.localStripLength(lP);
1799  const float phi = topol.stripAngle(measPos.x());
1800 
1801  float x(-999.F);
1802  float y(-999.F);
1803  float errX2(-999.F);
1804  float errY2(-999.F);
1805 
1806  x = phi * r_0;
1807  // Radial y (not symmetric around 0; radial distance with minimum at middle strip at lower edge [0, yMax])
1808  const float l_0 = r_0 - topol.detHeight() / 2;
1809  const float cosPhi(std::cos(phi));
1810  y = measPos.y() * stripLength - 0.5 * stripLength + l_0 * (1. / cosPhi - 1.);
1811 
1812  const float angularWidth2(topol.angularWidth() * topol.angularWidth());
1813  const float errPhi2(measErr.uu() * angularWidth2);
1814 
1815  errX2 = errPhi2 * r_0 * r_0;
1816  // Radial y (not symmetric around 0, real radial distance from intersection point)
1817  const float cosPhi4(std::pow(cosPhi, 4)), sinPhi2(std::sin(phi) * std::sin(phi));
1818  const float helpSummand = l_0 * l_0 * (sinPhi2 / cosPhi4 * errPhi2);
1819  errY2 = measErr.vv() * stripLength * stripLength + helpSummand;
1820 
1821  return PositionAndError2(x, y, errX2, errY2);
1822 }
1823 
1824 // -----------------------------------------------------------------------------------------------------------
1825 
1827  this->setHitSelectionMapUInt("width");
1828  this->setHitSelectionMap("widthProj");
1829  this->setHitSelectionMap("widthDiff");
1830  this->setHitSelectionMap("charge");
1831  this->setHitSelectionMapUInt("edgeStrips");
1832  this->setHitSelectionMap("maxCharge");
1833  this->setHitSelectionMapUInt("maxIndex");
1834  this->setHitSelectionMap("chargeOnEdges");
1835  this->setHitSelectionMap("chargeAsymmetry");
1836  this->setHitSelectionMap("chargeLRplus");
1837  this->setHitSelectionMap("chargeLRminus");
1838  this->setHitSelectionMap("sOverN");
1839 
1840  this->setHitSelectionMap("chargePixel");
1841  this->setHitSelectionMapUInt("widthX");
1842  this->setHitSelectionMapUInt("widthY");
1843 
1844  this->setHitSelectionMap("baryStripX");
1845  this->setHitSelectionMap("baryStripY");
1846  this->setHitSelectionMap("clusterProbabilityXY");
1847  this->setHitSelectionMap("clusterProbabilityQ");
1848  this->setHitSelectionMap("clusterProbabilityXYQ");
1849  this->setHitSelectionMap("logClusterProbability");
1850  this->setHitSelectionMapUInt("isOnEdge");
1851  this->setHitSelectionMapUInt("hasBadPixels");
1852  this->setHitSelectionMapUInt("spansTwoRoc");
1853  this->setHitSelectionMapUInt("qBin");
1854 
1855  this->setHitSelectionMap("phiSens");
1856  this->setHitSelectionMap("phiSensX");
1857  this->setHitSelectionMap("phiSensY");
1858  this->setHitSelectionMap("resX");
1859  this->setHitSelectionMap("norResX");
1860  this->setHitSelectionMap("probX");
1861  this->setHitSelectionMap("errXHit");
1862  this->setHitSelectionMap("errXTrk");
1863  this->setHitSelectionMap("errX");
1864  this->setHitSelectionMap("errX2");
1865 
1866  this->setHitSelectionMap("resY");
1867  this->setHitSelectionMap("norResY");
1868  this->setHitSelectionMap("probY");
1869  this->setHitSelectionMap("errYHit");
1870  this->setHitSelectionMap("errYTrk");
1871  this->setHitSelectionMap("errY");
1872  this->setHitSelectionMap("errY2");
1873 
1874  edm::LogInfo("HitSelector") << "applying hit cuts ...";
1875  bool emptyMap(true);
1876  for (auto& i_hitSelection : m_hitSelection_) {
1877  if (!i_hitSelection.second.empty()) {
1878  int entry(1);
1879  double intervalBegin(999.);
1880  for (std::vector<double>::iterator i_hitInterval = i_hitSelection.second.begin();
1881  i_hitInterval != i_hitSelection.second.end();
1882  ++entry) {
1883  if (entry % 2 == 1) {
1884  intervalBegin = *i_hitInterval;
1885  ++i_hitInterval;
1886  } else {
1887  if (intervalBegin > *i_hitInterval) {
1888  edm::LogError("HitSelector") << "INVALID Interval selected for " << i_hitSelection.first << ":\t"
1889  << intervalBegin << " > " << (*i_hitInterval) << "\n ... delete Selection for "
1890  << i_hitSelection.first;
1891  i_hitSelection.second.clear();
1892  i_hitInterval = i_hitSelection.second.begin(); //emptyMap = true; i_hitSelection = m_hitSelection_.begin();
1893  } else {
1894  edm::LogInfo("HitSelector") << "Interval selected for " << i_hitSelection.first << ":\t" << intervalBegin
1895  << ", " << (*i_hitInterval);
1896  ++i_hitInterval;
1897  }
1898  }
1899  }
1900  if (!i_hitSelection.second.empty())
1901  emptyMap = false;
1902  }
1903  }
1904 
1905  bool emptyMapUInt(true);
1906  for (auto& i_hitSelection : m_hitSelectionUInt_) {
1907  if (!i_hitSelection.second.empty()) {
1908  int entry(1);
1909  unsigned int intervalBegin(999);
1910  for (std::vector<unsigned int>::iterator i_hitInterval = i_hitSelection.second.begin();
1911  i_hitInterval != i_hitSelection.second.end();
1912  ++entry) {
1913  if (entry % 2 == 1) {
1914  intervalBegin = *i_hitInterval;
1915  ++i_hitInterval;
1916  } else {
1917  if (intervalBegin > *i_hitInterval) {
1918  edm::LogError("HitSelector") << "INVALID Interval selected for " << i_hitSelection.first << ":\t"
1919  << intervalBegin << " > " << (*i_hitInterval) << "\n ... delete Selection for "
1920  << i_hitSelection.first;
1921  i_hitSelection.second.clear();
1922  i_hitInterval = i_hitSelection.second.begin(); //emptyMap = true; i_hitSelection = m_hitSelection_.begin();
1923  } else {
1924  edm::LogInfo("HitSelector") << "Interval selected for " << i_hitSelection.first << ":\t" << intervalBegin
1925  << ", " << (*i_hitInterval);
1926  ++i_hitInterval;
1927  }
1928  }
1929  }
1930  if (!i_hitSelection.second.empty())
1931  emptyMapUInt = false;
1932  }
1933  }
1934 
1935  if (emptyMap && emptyMapUInt) {
1936  m_hitSelection_.clear();
1937  m_hitSelectionUInt_.clear();
1938  edm::LogInfo("HitSelector") << "NO hit cuts applied";
1939  }
1940  return;
1941 }
1942 
1945  std::vector<double> v_cutVariable(parSet.getParameter<std::vector<double> >(cutVariable));
1946  if (v_cutVariable.size() % 2 == 1) {
1947  edm::LogError("HitSelector") << "Invalid Hit Selection for " << cutVariable
1948  << ": need even number of arguments (intervals)"
1949  << "\n ... delete Selection for " << cutVariable;
1950  v_cutVariable.clear();
1951  m_hitSelection_[cutVariable] = v_cutVariable;
1952  return;
1953  }
1954  m_hitSelection_[cutVariable] = v_cutVariable;
1955  return;
1956 }
1957 
1960  std::vector<unsigned int> v_cutVariable(parSet.getParameter<std::vector<unsigned int> >(cutVariable));
1961  if (v_cutVariable.size() % 2 == 1) {
1962  edm::LogError("HitSelector") << "Invalid Hit Selection for " << cutVariable
1963  << ": need even number of arguments (intervals)"
1964  << "\n ... delete Selection for " << cutVariable;
1965  v_cutVariable.clear();
1966  m_hitSelectionUInt_[cutVariable] = v_cutVariable;
1967  return;
1968  }
1969  m_hitSelectionUInt_[cutVariable] = v_cutVariable;
1970  return;
1971 }
1972 
1973 // -----------------------------------------------------------------------------------------------------------
1974 
1976  if (hitParams.hitState == TrackStruct::notInTracker)
1977  return false;
1978  if (hitParams.hitState == TrackStruct::invalid || hitParams.hitState == TrackStruct::negativeError)
1979  return false;
1980 
1981  bool isGoodHit(true);
1982  bool isGoodHitX(true);
1983  bool isGoodHitY(true);
1984 
1985  for (auto& i_hitSelection : m_hitSelection_) {
1986  const std::string& hitSelection(i_hitSelection.first);
1987  const std::vector<double>& v_hitSelection(i_hitSelection.second);
1988  if (v_hitSelection.empty())
1989  continue;
1990 
1991  // For pixel and strip sectors in common
1992  if (hitSelection == "phiSens") {
1993  if (!this->inDoubleInterval(v_hitSelection, hitParams.phiSens))
1994  isGoodHit = false;
1995  } else if (hitSelection == "phiSensX") {
1996  if (!this->inDoubleInterval(v_hitSelection, hitParams.phiSensX))
1997  isGoodHit = false;
1998  } else if (hitSelection == "phiSensY") {
1999  if (!this->inDoubleInterval(v_hitSelection, hitParams.phiSensY))
2000  isGoodHit = false;
2001  }
2002 
2003  else if (hitSelection == "resX") {
2004  if (!this->inDoubleInterval(v_hitSelection, hitParams.resX))
2005  isGoodHitX = false;
2006  } else if (hitSelection == "norResX") {
2007  if (!this->inDoubleInterval(v_hitSelection, hitParams.norResX))
2008  isGoodHitX = false;
2009  } else if (hitSelection == "probX") {
2010  if (!this->inDoubleInterval(v_hitSelection, hitParams.probX))
2011  isGoodHitX = false;
2012  } else if (hitSelection == "errXHit") {
2013  if (!this->inDoubleInterval(v_hitSelection, hitParams.errXHit))
2014  isGoodHitX = false;
2015  } else if (hitSelection == "errXTrk") {
2016  if (!this->inDoubleInterval(v_hitSelection, hitParams.errXTrk))
2017  isGoodHitX = false;
2018  } else if (hitSelection == "errX") {
2019  if (!this->inDoubleInterval(v_hitSelection, hitParams.errX))
2020  isGoodHitX = false;
2021  } else if (hitSelection == "errX2") {
2022  if (!this->inDoubleInterval(v_hitSelection, hitParams.errX2))
2023  isGoodHitX = false;
2024  }
2025 
2026  // For pixel only
2027  if (hitParams.isPixelHit) {
2028  if (hitSelection == "chargePixel") {
2029  if (!this->inDoubleInterval(v_hitSelection, hitParams.chargePixel))
2030  isGoodHit = false;
2031  } else if (hitSelection == "clusterProbabilityXY") {
2032  if (!this->inDoubleInterval(v_hitSelection, hitParams.clusterProbabilityXY))
2033  isGoodHit = false;
2034  } else if (hitSelection == "clusterProbabilityQ") {
2035  if (!this->inDoubleInterval(v_hitSelection, hitParams.clusterProbabilityQ))
2036  isGoodHit = false;
2037  } else if (hitSelection == "clusterProbabilityXYQ") {
2038  if (!this->inDoubleInterval(v_hitSelection, hitParams.clusterProbabilityXYQ))
2039  isGoodHit = false;
2040  } else if (hitSelection == "logClusterProbability") {
2041  if (!this->inDoubleInterval(v_hitSelection, hitParams.logClusterProbability))
2042  isGoodHit = false;
2043  }
2044 
2045  else if (hitSelection == "baryStripX") {
2046  if (!this->inDoubleInterval(v_hitSelection, hitParams.baryStripX))
2047  isGoodHitX = false;
2048  } else if (hitSelection == "baryStripY") {
2049  if (!this->inDoubleInterval(v_hitSelection, hitParams.baryStripY))
2050  isGoodHitY = false;
2051  }
2052 
2053  else if (hitSelection == "resY") {
2054  if (!this->inDoubleInterval(v_hitSelection, hitParams.resY))
2055  isGoodHitY = false;
2056  } else if (hitSelection == "norResY") {
2057  if (!this->inDoubleInterval(v_hitSelection, hitParams.norResY))
2058  isGoodHitY = false;
2059  } else if (hitSelection == "probY") {
2060  if (!this->inDoubleInterval(v_hitSelection, hitParams.probY))
2061  isGoodHitY = false;
2062  } else if (hitSelection == "errYHit") {
2063  if (!this->inDoubleInterval(v_hitSelection, hitParams.errYHit))
2064  isGoodHitY = false;
2065  } else if (hitSelection == "errYTrk") {
2066  if (!this->inDoubleInterval(v_hitSelection, hitParams.errYTrk))
2067  isGoodHitY = false;
2068  } else if (hitSelection == "errY") {
2069  if (!this->inDoubleInterval(v_hitSelection, hitParams.errY))
2070  isGoodHitY = false;
2071  } else if (hitSelection == "errY2") {
2072  if (!this->inDoubleInterval(v_hitSelection, hitParams.errY2))
2073  isGoodHitY = false;
2074  }
2075  } else { // For strip only
2076  if (hitSelection == "widthProj") {
2077  if (!this->inDoubleInterval(v_hitSelection, hitParams.projWidth))
2078  isGoodHit = false;
2079  } else if (hitSelection == "widthDiff") {
2080  if (!this->inDoubleInterval(v_hitSelection, hitParams.projWidth - static_cast<float>(hitParams.widthX)))
2081  isGoodHit = false;
2082  } else if (hitSelection == "charge") {
2083  if (!this->inDoubleInterval(v_hitSelection, hitParams.chargeStrip))
2084  isGoodHit = false;
2085  } else if (hitSelection == "maxCharge") {
2086  if (!this->inDoubleInterval(v_hitSelection, hitParams.maxCharge))
2087  isGoodHit = false;
2088  } else if (hitSelection == "chargeOnEdges") {
2089  if (!this->inDoubleInterval(v_hitSelection, hitParams.chargeOnEdges))
2090  isGoodHit = false;
2091  } else if (hitSelection == "chargeAsymmetry") {
2092  if (!this->inDoubleInterval(v_hitSelection, hitParams.chargeAsymmetry))
2093  isGoodHit = false;
2094  } else if (hitSelection == "chargeLRplus") {
2095  if (!this->inDoubleInterval(v_hitSelection, hitParams.chargeLRplus))
2096  isGoodHit = false;
2097  } else if (hitSelection == "chargeLRminus") {
2098  if (!this->inDoubleInterval(v_hitSelection, hitParams.chargeLRminus))
2099  isGoodHit = false;
2100  } else if (hitSelection == "sOverN") {
2101  if (!this->inDoubleInterval(v_hitSelection, hitParams.sOverN))
2102  isGoodHit = false;
2103  }
2104  }
2105  }
2106 
2107  for (auto& i_hitSelection : m_hitSelectionUInt_) {
2108  const std::string& hitSelection(i_hitSelection.first);
2109  const std::vector<unsigned int>& v_hitSelection(i_hitSelection.second);
2110  if (v_hitSelection.empty())
2111  continue;
2112 
2113  // For pixel and strip sectors in common
2114 
2115  // For pixel only
2116  if (hitParams.isPixelHit) {
2117  if (hitSelection == "isOnEdge") {
2118  if (!this->inUintInterval(v_hitSelection, hitParams.isOnEdge))
2119  isGoodHit = false;
2120  } else if (hitSelection == "hasBadPixels") {
2121  if (!this->inUintInterval(v_hitSelection, hitParams.hasBadPixels))
2122  isGoodHit = false;
2123  } else if (hitSelection == "spansTwoRoc") {
2124  if (!this->inUintInterval(v_hitSelection, hitParams.spansTwoRoc))
2125  isGoodHit = false;
2126  } else if (hitSelection == "qBin") {
2127  if (!this->inUintInterval(v_hitSelection, hitParams.qBin))
2128  isGoodHit = false;
2129  }
2130 
2131  else if (hitSelection == "widthX") {
2132  if (!this->inUintInterval(v_hitSelection, hitParams.widthX))
2133  isGoodHitX = false;
2134  } else if (hitSelection == "widthY") {
2135  if (!this->inUintInterval(v_hitSelection, hitParams.widthY))
2136  isGoodHitY = false;
2137  }
2138  } else { // For strip only
2139  if (hitSelection == "width") {
2140  if (!this->inUintInterval(v_hitSelection, hitParams.widthX))
2141  isGoodHit = false;
2142  } else if (hitSelection == "edgeStrips") {
2143  if (!this->inUintInterval(v_hitSelection, hitParams.maxStrip, hitParams.maxStripInv))
2144  isGoodHit = false;
2145  } else if (hitSelection == "maxIndex") {
2146  if (!this->inUintInterval(v_hitSelection, hitParams.maxIndex))
2147  isGoodHit = false;
2148  }
2149  }
2150  }
2151 
2152  if (hitParams.isPixelHit) {
2153  hitParams.goodXMeasurement = isGoodHit && isGoodHitX;
2154  hitParams.goodYMeasurement = isGoodHit && isGoodHitY;
2155  } else {
2156  hitParams.goodXMeasurement = isGoodHit && isGoodHitX;
2157  hitParams.goodYMeasurement = false;
2158  }
2159 
2160  if (!hitParams.goodXMeasurement && !hitParams.goodYMeasurement)
2161  return false;
2162  else
2163  return true;
2164 }
2165 
2166 bool ApeEstimator::inDoubleInterval(const std::vector<double>& v_hitSelection, const float variable) const {
2167  int entry(0);
2168  double intervalBegin(999.);
2169  bool isSelected(false);
2170  for (auto const& i_hitInterval : v_hitSelection) {
2171  ++entry;
2172  if (entry % 2 == 1)
2173  intervalBegin = i_hitInterval;
2174  else if (variable >= intervalBegin && variable < i_hitInterval)
2175  isSelected = true;
2176  }
2177  return isSelected;
2178 }
2179 
2180 bool ApeEstimator::inUintInterval(const std::vector<unsigned int>& v_hitSelection,
2181  const unsigned int variable,
2182  const unsigned int variable2) const {
2183  int entry(0);
2184  unsigned int intervalBegin(999);
2185  bool isSelected(false);
2186  for (auto i_hitInterval : v_hitSelection) {
2187  ++entry;
2188  if (entry % 2 == 1)
2189  intervalBegin = i_hitInterval;
2190  else if (variable >= intervalBegin && variable <= i_hitInterval) {
2191  if (variable2 == 999 || (variable2 >= intervalBegin && variable2 <= i_hitInterval))
2192  isSelected = true;
2193  }
2194  }
2195  return isSelected;
2196 }
2197 
2198 // -----------------------------------------------------------------------------------------------------------
2199 
2201  unsigned int goodHitsPerTrack(trackStruct.v_hitParams.size());
2202  tkDetector_.HitsGood->Fill(goodHitsPerTrack);
2203  tkDetector_.HitsGoodVsHitsValid->Fill(trackStruct.trkParams.hitsValid, goodHitsPerTrack);
2204  tkDetector_.PHitsGoodVsHitsValid->Fill(trackStruct.trkParams.hitsValid, goodHitsPerTrack);
2205 
2206  if (parameterSet_.getParameter<bool>("applyTrackCuts")) {
2207  // which tracks to take? need min. nr. of selected hits?
2208  if (goodHitsPerTrack < minGoodHitsPerTrack_)
2209  return;
2210  }
2211 
2212  tkDetector_.HitsSize->Fill(trackStruct.trkParams.hitsSize);
2213  tkDetector_.HitsValid->Fill(trackStruct.trkParams.hitsValid);
2214  tkDetector_.HitsInvalid->Fill(trackStruct.trkParams.hitsInvalid);
2215  tkDetector_.Hits2D->Fill(trackStruct.trkParams.hits2D);
2216  tkDetector_.LayersMissed->Fill(trackStruct.trkParams.layersMissed);
2217  tkDetector_.HitsPixel->Fill(trackStruct.trkParams.hitsPixel);
2218  tkDetector_.HitsStrip->Fill(trackStruct.trkParams.hitsStrip);
2219  tkDetector_.Charge->Fill(trackStruct.trkParams.charge);
2220  tkDetector_.Chi2->Fill(trackStruct.trkParams.chi2);
2221  tkDetector_.Ndof->Fill(trackStruct.trkParams.ndof);
2222  tkDetector_.NorChi2->Fill(trackStruct.trkParams.norChi2);
2223  tkDetector_.Prob->Fill(trackStruct.trkParams.prob);
2224  tkDetector_.Eta->Fill(trackStruct.trkParams.eta);
2225  tkDetector_.EtaErr->Fill(trackStruct.trkParams.etaErr);
2226  tkDetector_.EtaSig->Fill(trackStruct.trkParams.eta / trackStruct.trkParams.etaErr);
2227  tkDetector_.Theta->Fill(trackStruct.trkParams.theta * 180. / M_PI);
2228  tkDetector_.Phi->Fill(trackStruct.trkParams.phi * 180. / M_PI);
2229  tkDetector_.PhiErr->Fill(trackStruct.trkParams.phiErr * 180. / M_PI);
2230  tkDetector_.PhiSig->Fill(trackStruct.trkParams.phi / trackStruct.trkParams.phiErr);
2231  tkDetector_.D0Beamspot->Fill(trackStruct.trkParams.d0Beamspot);
2232  tkDetector_.D0BeamspotErr->Fill(trackStruct.trkParams.d0BeamspotErr);
2233  tkDetector_.D0BeamspotSig->Fill(trackStruct.trkParams.d0Beamspot / trackStruct.trkParams.d0BeamspotErr);
2234  tkDetector_.Dz->Fill(trackStruct.trkParams.dz);
2235  tkDetector_.DzErr->Fill(trackStruct.trkParams.dzErr);
2236  tkDetector_.DzSig->Fill(trackStruct.trkParams.dz / trackStruct.trkParams.dzErr);
2237  tkDetector_.P->Fill(trackStruct.trkParams.p);
2238  tkDetector_.Pt->Fill(trackStruct.trkParams.pt);
2239  tkDetector_.PtErr->Fill(trackStruct.trkParams.ptErr);
2240  tkDetector_.PtSig->Fill(trackStruct.trkParams.pt / trackStruct.trkParams.ptErr);
2241  tkDetector_.MeanAngle->Fill(trackStruct.trkParams.meanPhiSensToNorm * 180. / M_PI);
2242 
2243  tkDetector_.MeanAngleVsHits->Fill(trackStruct.trkParams.hitsSize,
2244  trackStruct.trkParams.meanPhiSensToNorm * 180. / M_PI);
2245  tkDetector_.HitsPixelVsEta->Fill(trackStruct.trkParams.eta, trackStruct.trkParams.hitsPixel);
2246  tkDetector_.HitsPixelVsTheta->Fill(trackStruct.trkParams.theta * 180. / M_PI, trackStruct.trkParams.hitsPixel);
2247  tkDetector_.HitsStripVsEta->Fill(trackStruct.trkParams.eta, trackStruct.trkParams.hitsStrip);
2248  tkDetector_.HitsStripVsTheta->Fill(trackStruct.trkParams.theta * 180. / M_PI, trackStruct.trkParams.hitsStrip);
2249  tkDetector_.PtVsEta->Fill(trackStruct.trkParams.eta, trackStruct.trkParams.pt);
2250  tkDetector_.PtVsTheta->Fill(trackStruct.trkParams.theta * 180. / M_PI, trackStruct.trkParams.pt);
2251 
2252  tkDetector_.PMeanAngleVsHits->Fill(trackStruct.trkParams.hitsSize,
2253  trackStruct.trkParams.meanPhiSensToNorm * 180. / M_PI);
2254  tkDetector_.PHitsPixelVsEta->Fill(trackStruct.trkParams.eta, trackStruct.trkParams.hitsPixel);
2255  tkDetector_.PHitsPixelVsTheta->Fill(trackStruct.trkParams.theta * 180. / M_PI, trackStruct.trkParams.hitsPixel);
2256  tkDetector_.PHitsStripVsEta->Fill(trackStruct.trkParams.eta, trackStruct.trkParams.hitsStrip);
2257  tkDetector_.PHitsStripVsTheta->Fill(trackStruct.trkParams.theta * 180. / M_PI, trackStruct.trkParams.hitsStrip);
2258  tkDetector_.PPtVsEta->Fill(trackStruct.trkParams.eta, trackStruct.trkParams.pt);
2259  tkDetector_.PPtVsTheta->Fill(trackStruct.trkParams.theta * 180. / M_PI, trackStruct.trkParams.pt);
2260 
2261  for (auto& i_hit : trackStruct.v_hitParams) {
2262  const TrackStruct::HitParameterStruct& hit(i_hit);
2263  //Put here from earlier method
2264  if (hit.hitState == TrackStruct::notAssignedToSectors)
2265  continue;
2266 
2267  for (auto& i_sector : m_tkSector_) {
2268  bool moduleInSector(false);
2269  for (auto const& i_hitSector : hit.v_sector) {
2270  if (i_sector.first == i_hitSector) {
2271  moduleInSector = true;
2272  break;
2273  }
2274  }
2275  if (!moduleInSector)
2276  continue;
2277  TrackerSectorStruct& sector(i_sector.second);
2278 
2279  if (hit.goodXMeasurement) {
2280  std::map<std::string, TrackerSectorStruct::CorrelationHists>& m_corrHists(sector.m_correlationHistsX);
2281 
2282  // Cluster and Hit Parameters
2284 
2285  // Track Parameters
2286  m_corrHists["HitsValid"].fillCorrHistsX(hit, trackStruct.trkParams.hitsValid);
2287  m_corrHists["HitsGood"].fillCorrHistsX(hit, goodHitsPerTrack);
2288  m_corrHists["HitsInvalid"].fillCorrHistsX(hit, trackStruct.trkParams.hitsInvalid);
2289  m_corrHists["Hits2D"].fillCorrHistsX(hit, trackStruct.trkParams.hits2D);
2290  m_corrHists["LayersMissed"].fillCorrHistsX(hit, trackStruct.trkParams.layersMissed);
2291  m_corrHists["HitsPixel"].fillCorrHistsX(hit, trackStruct.trkParams.hitsPixel);
2292  m_corrHists["HitsStrip"].fillCorrHistsX(hit, trackStruct.trkParams.hitsStrip);
2293  m_corrHists["NorChi2"].fillCorrHistsX(hit, trackStruct.trkParams.norChi2);
2294  m_corrHists["Theta"].fillCorrHistsX(hit, trackStruct.trkParams.theta * 180. / M_PI);
2295  m_corrHists["Phi"].fillCorrHistsX(hit, trackStruct.trkParams.phi * 180. / M_PI);
2296  m_corrHists["D0Beamspot"].fillCorrHistsX(hit, trackStruct.trkParams.d0Beamspot);
2297  m_corrHists["Dz"].fillCorrHistsX(hit, trackStruct.trkParams.dz);
2298  m_corrHists["Pt"].fillCorrHistsX(hit, trackStruct.trkParams.pt);
2299  m_corrHists["P"].fillCorrHistsX(hit, trackStruct.trkParams.p);
2300  m_corrHists["InvP"].fillCorrHistsX(hit, 1. / trackStruct.trkParams.p);
2301  m_corrHists["MeanAngle"].fillCorrHistsX(hit, trackStruct.trkParams.meanPhiSensToNorm * 180. / M_PI);
2302  }
2303 
2304  if (hit.goodYMeasurement) {
2305  std::map<std::string, TrackerSectorStruct::CorrelationHists>& m_corrHists(sector.m_correlationHistsY);
2306 
2307  // Cluster and Hit Parameters
2309 
2310  // Track Parameters
2311  m_corrHists["HitsValid"].fillCorrHistsY(hit, trackStruct.trkParams.hitsValid);
2312  m_corrHists["HitsGood"].fillCorrHistsY(hit, goodHitsPerTrack);
2313  m_corrHists["HitsInvalid"].fillCorrHistsY(hit, trackStruct.trkParams.hitsInvalid);
2314  m_corrHists["Hits2D"].fillCorrHistsY(hit, trackStruct.trkParams.hits2D);
2315  m_corrHists["LayersMissed"].fillCorrHistsY(hit, trackStruct.trkParams.layersMissed);
2316  m_corrHists["HitsPixel"].fillCorrHistsY(hit, trackStruct.trkParams.hitsPixel);
2317  m_corrHists["HitsStrip"].fillCorrHistsY(hit, trackStruct.trkParams.hitsStrip);
2318  m_corrHists["NorChi2"].fillCorrHistsY(hit, trackStruct.trkParams.norChi2);
2319  m_corrHists["Theta"].fillCorrHistsY(hit, trackStruct.trkParams.theta * 180. / M_PI);
2320  m_corrHists["Phi"].fillCorrHistsY(hit, trackStruct.trkParams.phi * 180. / M_PI);
2321  m_corrHists["D0Beamspot"].fillCorrHistsY(hit, trackStruct.trkParams.d0Beamspot);
2322  m_corrHists["Dz"].fillCorrHistsY(hit, trackStruct.trkParams.dz);
2323  m_corrHists["Pt"].fillCorrHistsY(hit, trackStruct.trkParams.pt);
2324  m_corrHists["P"].fillCorrHistsY(hit, trackStruct.trkParams.p);
2325  m_corrHists["InvP"].fillCorrHistsY(hit, 1. / trackStruct.trkParams.p);
2326  m_corrHists["MeanAngle"].fillCorrHistsY(hit, trackStruct.trkParams.meanPhiSensToNorm * 180. / M_PI);
2327  }
2328 
2329  // Special Histograms
2330  for (auto& i_sigmaX : sector.m_sigmaX) {
2331  for (auto& iHist : i_sigmaX.second) {
2332  if (i_sigmaX.first == "sigmaXHit")
2333  iHist->Fill(hit.errXHit * 10000.);
2334  else if (i_sigmaX.first == "sigmaXTrk")
2335  iHist->Fill(hit.errXTrk * 10000.);
2336  else if (i_sigmaX.first == "sigmaX")
2337  iHist->Fill(hit.errX * 10000.);
2338  }
2339  }
2340  for (auto& i_sigmaY : sector.m_sigmaY) {
2341  for (auto& iHist : i_sigmaY.second) {
2342  if (i_sigmaY.first == "sigmaYHit")
2343  iHist->Fill(hit.errYHit * 10000.);
2344  else if (i_sigmaY.first == "sigmaYTrk")
2345  iHist->Fill(hit.errYTrk * 10000.);
2346  else if (i_sigmaY.first == "sigmaY")
2347  iHist->Fill(hit.errY * 10000.);
2348  }
2349  }
2350  }
2351  }
2352 }
2353 
2356  std::map<std::string, TrackerSectorStruct::CorrelationHists>& m_corrHists(sector.m_correlationHistsX);
2357 
2358  // Cluster Parameters
2359  m_corrHists["WidthX"].fillCorrHistsX(hit, hit.widthX);
2360  m_corrHists["BaryStripX"].fillCorrHistsX(hit, hit.baryStripX);
2361 
2362  if (hit.isPixelHit) {
2363  m_corrHists["ChargePixel"].fillCorrHistsX(hit, hit.chargePixel);
2364  m_corrHists["ClusterProbXY"].fillCorrHistsX(hit, hit.clusterProbabilityXY);
2365  m_corrHists["ClusterProbQ"].fillCorrHistsX(hit, hit.clusterProbabilityQ);
2366  m_corrHists["ClusterProbXYQ"].fillCorrHistsX(hit, hit.clusterProbabilityXYQ);
2367  m_corrHists["LogClusterProb"].fillCorrHistsX(hit, hit.logClusterProbability);
2368  m_corrHists["IsOnEdge"].fillCorrHistsX(hit, hit.isOnEdge);
2369  m_corrHists["HasBadPixels"].fillCorrHistsX(hit, hit.hasBadPixels);
2370  m_corrHists["SpansTwoRoc"].fillCorrHistsX(hit, hit.spansTwoRoc);
2371  m_corrHists["QBin"].fillCorrHistsX(hit, hit.qBin);
2372 
2373  } else {
2374  m_corrHists["ChargeStrip"].fillCorrHistsX(hit, hit.chargeStrip);
2375  m_corrHists["MaxStrip"].fillCorrHistsX(hit, hit.maxStrip);
2376  m_corrHists["MaxCharge"].fillCorrHistsX(hit, hit.maxCharge);
2377  m_corrHists["MaxIndex"].fillCorrHistsX(hit, hit.maxIndex);
2378  m_corrHists["ChargeOnEdges"].fillCorrHistsX(hit, hit.chargeOnEdges);
2379  m_corrHists["ChargeAsymmetry"].fillCorrHistsX(hit, hit.chargeAsymmetry);
2380  m_corrHists["ChargeLRplus"].fillCorrHistsX(hit, hit.chargeLRplus);
2381  m_corrHists["ChargeLRminus"].fillCorrHistsX(hit, hit.chargeLRminus);
2382  m_corrHists["SOverN"].fillCorrHistsX(hit, hit.sOverN);
2383  m_corrHists["WidthProj"].fillCorrHistsX(hit, hit.projWidth);
2384  m_corrHists["WidthDiff"].fillCorrHistsX(hit, hit.projWidth - static_cast<float>(hit.widthX));
2385 
2386  sector.WidthVsWidthProjected->Fill(hit.projWidth, hit.widthX);
2387  sector.PWidthVsWidthProjected->Fill(hit.projWidth, hit.widthX);
2388 
2389  sector.WidthDiffVsMaxStrip->Fill(hit.maxStrip, hit.projWidth - static_cast<float>(hit.widthX));
2390  sector.PWidthDiffVsMaxStrip->Fill(hit.maxStrip, hit.projWidth - static_cast<float>(hit.widthX));
2391 
2392  sector.WidthDiffVsSigmaXHit->Fill(hit.errXHit, hit.projWidth - static_cast<float>(hit.widthX));
2393  sector.PWidthDiffVsSigmaXHit->Fill(hit.errXHit, hit.projWidth - static_cast<float>(hit.widthX));
2394 
2395  sector.WidthVsPhiSensX->Fill(hit.phiSensX * 180. / M_PI, hit.widthX);
2396  sector.PWidthVsPhiSensX->Fill(hit.phiSensX * 180. / M_PI, hit.widthX);
2397  }
2398 
2399  // Hit Parameters
2400  m_corrHists["SigmaXHit"].fillCorrHistsX(hit, hit.errXHit * 10000.);
2401  m_corrHists["SigmaXTrk"].fillCorrHistsX(hit, hit.errXTrk * 10000.);
2402  m_corrHists["SigmaX"].fillCorrHistsX(hit, hit.errX * 10000.);
2403 
2404  m_corrHists["PhiSens"].fillCorrHistsX(hit, hit.phiSens * 180. / M_PI);
2405  m_corrHists["PhiSensX"].fillCorrHistsX(hit, hit.phiSensX * 180. / M_PI);
2406  m_corrHists["PhiSensY"].fillCorrHistsX(hit, hit.phiSensY * 180. / M_PI);
2407 
2408  sector.XHit->Fill(hit.xHit);
2409  sector.XTrk->Fill(hit.xTrk);
2410  sector.SigmaX2->Fill(hit.errX2 * 10000. * 10000.);
2411 
2412  sector.ResX->Fill(hit.resX * 10000.);
2413  sector.NorResX->Fill(hit.norResX);
2414 
2415  sector.ProbX->Fill(hit.probX);
2416 
2417  sector.PhiSensXVsBarycentreX->Fill(hit.baryStripX, hit.phiSensX * 180. / M_PI);
2418  sector.PPhiSensXVsBarycentreX->Fill(hit.baryStripX, hit.phiSensX * 180. / M_PI);
2419 }
2420 
2423  std::map<std::string, TrackerSectorStruct::CorrelationHists>& m_corrHists(sector.m_correlationHistsY);
2424  // Do not fill anything for strip
2425  if (!hit.isPixelHit)
2426  return;
2427 
2428  // Cluster Parameters
2429  m_corrHists["WidthY"].fillCorrHistsY(hit, hit.widthY);
2430  m_corrHists["BaryStripY"].fillCorrHistsY(hit, hit.baryStripY);
2431 
2432  m_corrHists["ChargePixel"].fillCorrHistsY(hit, hit.chargePixel);
2433  m_corrHists["ClusterProbXY"].fillCorrHistsY(hit, hit.clusterProbabilityXY);
2434  m_corrHists["ClusterProbQ"].fillCorrHistsY(hit, hit.clusterProbabilityQ);
2435  m_corrHists["ClusterProbXYQ"].fillCorrHistsY(hit, hit.clusterProbabilityXYQ);
2436  m_corrHists["LogClusterProb"].fillCorrHistsY(hit, hit.logClusterProbability);
2437  m_corrHists["IsOnEdge"].fillCorrHistsY(hit, hit.isOnEdge);
2438  m_corrHists["HasBadPixels"].fillCorrHistsY(hit, hit.hasBadPixels);
2439  m_corrHists["SpansTwoRoc"].fillCorrHistsY(hit, hit.spansTwoRoc);
2440  m_corrHists["QBin"].fillCorrHistsY(hit, hit.qBin);
2441 
2442  // Hit Parameters
2443  m_corrHists["SigmaYHit"].fillCorrHistsY(hit, hit.errYHit * 10000.);
2444  m_corrHists["SigmaYTrk"].fillCorrHistsY(hit, hit.errYTrk * 10000.);
2445  m_corrHists["SigmaY"].fillCorrHistsY(hit, hit.errY * 10000.);
2446 
2447  m_corrHists["PhiSens"].fillCorrHistsY(hit, hit.phiSens * 180. / M_PI);
2448  m_corrHists["PhiSensX"].fillCorrHistsY(hit, hit.phiSensX * 180. / M_PI);
2449  m_corrHists["PhiSensY"].fillCorrHistsY(hit, hit.phiSensY * 180. / M_PI);
2450 
2451  sector.YHit->Fill(hit.yHit);
2452  sector.YTrk->Fill(hit.yTrk);
2453  sector.SigmaY2->Fill(hit.errY2 * 10000. * 10000.);
2454 
2455  sector.ResY->Fill(hit.resY * 10000.);
2456  sector.NorResY->Fill(hit.norResY);
2457 
2458  sector.ProbY->Fill(hit.probY);
2459 
2460  sector.PhiSensYVsBarycentreY->Fill(hit.baryStripY, hit.phiSensY * 180. / M_PI);
2461  sector.PPhiSensYVsBarycentreY->Fill(hit.baryStripY, hit.phiSensY * 180. / M_PI);
2462 }
2463 
2465  unsigned int goodHitsPerTrack(trackStruct.v_hitParams.size());
2466 
2467  if (parameterSet_.getParameter<bool>("applyTrackCuts")) {
2468  // which tracks to take? need min. nr. of selected hits?
2469  if (goodHitsPerTrack < minGoodHitsPerTrack_)
2470  return;
2471  }
2472 
2473  for (auto const& i_hit : trackStruct.v_hitParams) {
2474  // Put here from earlier method
2475  if (i_hit.hitState == TrackStruct::notAssignedToSectors)
2476  continue;
2477 
2478  for (auto& i_sector : m_tkSector_) {
2479  bool moduleInSector(false);
2480  for (auto const& i_hitSector : i_hit.v_sector) {
2481  if (i_sector.first == i_hitSector) {
2482  moduleInSector = true;
2483  break;
2484  }
2485  }
2486  if (!moduleInSector)
2487  continue;
2488 
2489  if (!calculateApe_)
2490  continue;
2491 
2492  if (i_hit.goodXMeasurement) {
2493  for (auto const& i_errBins : m_resErrBins_) {
2494  // Separate the bins for residual resolution w/o APE, to be consistent within iterations where APE will change (have same hit always in same bin)
2495  // So also fill this value in the histogram sigmaX
2496  // But of course use the normalized residual regarding the APE to have its influence in its width
2497  if (i_hit.errXWoApe < i_errBins.second.first || i_hit.errXWoApe >= i_errBins.second.second) {
2498  continue;
2499  }
2500  i_sector.second.m_binnedHists[i_errBins.first]["sigmaX"]->Fill(i_hit.errXWoApe);
2501  i_sector.second.m_binnedHists[i_errBins.first]["norResX"]->Fill(i_hit.norResX);
2502  break;
2503  }
2504  i_sector.second.ResX->Fill(i_hit.resX * 10000.);
2505  i_sector.second.NorResX->Fill(i_hit.norResX);
2506  }
2507 
2508  if (i_hit.goodYMeasurement) {
2509  for (auto const& i_errBins : m_resErrBins_) {
2510  // Separate the bins for residual resolution w/o APE, to be consistent within iterations where APE will change (have same hit always in same bin)
2511  // So also fill this value in the histogram sigmaY
2512  // But of course use the normalized residual regarding the APE to have its influence in its width
2513  if (i_hit.errYWoApe < i_errBins.second.first || i_hit.errYWoApe >= i_errBins.second.second) {
2514  continue;
2515  }
2516  i_sector.second.m_binnedHists[i_errBins.first]["sigmaY"]->Fill(i_hit.errYWoApe);
2517  i_sector.second.m_binnedHists[i_errBins.first]["norResY"]->Fill(i_hit.norResY);
2518  break;
2519  }
2520  i_sector.second.ResY->Fill(i_hit.resY * 10000.);
2521  i_sector.second.NorResY->Fill(i_hit.norResY);
2522  }
2523  }
2524  }
2525 }
2526 
2527 // -----------------------------------------------------------------------------------------------------------
2528 
2530  // Loop over sectors for calculating APE
2531  for (auto& i_sector : m_tkSector_) {
2532  // Loop over residual error bins to calculate APE for every bin
2533  for (auto const& i_errBins : i_sector.second.m_binnedHists) {
2534  std::map<std::string, TH1*> m_Hists = i_errBins.second;
2535 
2536  // Fitting Parameters
2537  double integralX = m_Hists["norResX"]->Integral();
2538  i_sector.second.EntriesX->SetBinContent(i_errBins.first, integralX);
2539 
2540  if (i_sector.second.isPixel) {
2541  double integralY = m_Hists["norResY"]->Integral();
2542  i_sector.second.EntriesY->SetBinContent(i_errBins.first, integralY);
2543  }
2544  }
2545  }
2546 }
2547 
2548 // -----------------------------------------------------------------------------------------------------------
2549 
2551  // we count SiStrip stereo modules as 2D if selected via countStereoHitAs2D_
2552  // (since they provide theta information)
2553  // --- NO, here it is always set to true ---
2554  if (!hit.isValid() || (hit.dimension() < 2 && !dynamic_cast<const SiStripRecHit1D*>(&hit))) {
2555  return false; // real RecHit1D - but SiStripRecHit1D depends on countStereoHitAs2D_
2556  } else {
2557  const DetId detId(hit.geographicalId());
2558  if (detId.det() == DetId::Tracker) {
2559  if (detId.subdetId() == PixelSubdetector::PixelBarrel || detId.subdetId() == PixelSubdetector::PixelEndcap) {
2560  return true; // pixel is always 2D
2561  } else { // should be SiStrip now
2562  const SiStripDetId stripId(detId);
2563  if (stripId.stereo())
2564  return true; // stereo modules
2565  else if (dynamic_cast<const SiStripRecHit1D*>(&hit) || dynamic_cast<const SiStripRecHit2D*>(&hit))
2566  return false; // rphi modules hit
2567  //the following two are not used any more since ages...
2568  else if (dynamic_cast<const SiStripMatchedRecHit2D*>(&hit))
2569  return true; // matched is 2D
2570  else if (dynamic_cast<const ProjectedSiStripRecHit2D*>(&hit)) {
2571  const ProjectedSiStripRecHit2D* pH = static_cast<const ProjectedSiStripRecHit2D*>(&hit);
2572  return (this->isHit2D(pH->originalHit())); // depends on original...
2573  } else {
2574  edm::LogError("UnknownType") << "@SUB=ApeEstimator::isHit2D"
2575  << "Tracker hit not in pixel, neither SiStripRecHit[12]D nor "
2576  << "SiStripMatchedRecHit2D nor ProjectedSiStripRecHit2D.";
2577  return false;
2578  }
2579  }
2580  } else { // not tracker??
2581  edm::LogWarning("DetectorMismatch") << "@SUB=ApeEstimator::isHit2D"
2582  << "Hit not in tracker with 'official' dimension >=2.";
2583  return true; // dimension() >= 2 so accept that...
2584  }
2585  }
2586  // never reached...
2587 }
2588 
2589 // -----------------------------------------------------------------------------------------------------------
2590 
2591 // ------------ method called to for each event ------------
2594  edm::Handle<reco::BeamSpot> beamSpotHandle;
2595  iEvent.getByToken(offlinebeamSpot_, beamSpotHandle);
2596 
2597  if (beamSpotHandle.isValid()) {
2598  beamSpot = *beamSpotHandle;
2599  } else {
2600  edm::LogError("ApeEstimator") << "No beam spot available from EventSetup"
2601  << "\n...skip event";
2602  return;
2603  }
2604 
2606  iEvent.getByToken(tjTagToken_, m_TrajTracksMap);
2607 
2609 
2610  if (analyzerMode_)
2611  tkDetector_.TrkSize->Fill(m_TrajTracksMap->size());
2612 
2613  if (maxTracksPerEvent_ != 0 && m_TrajTracksMap->size() > maxTracksPerEvent_)
2614  return;
2615 
2616  //Creation of (traj,track)
2617  typedef std::pair<const Trajectory*, const reco::Track*> ConstTrajTrackPair;
2618  typedef std::vector<ConstTrajTrackPair> ConstTrajTrackPairCollection;
2619  ConstTrajTrackPairCollection trajTracks;
2620 
2622  for (i_trajTrack = m_TrajTracksMap->begin(); i_trajTrack != m_TrajTracksMap->end(); ++i_trajTrack) {
2623  trajTracks.push_back(ConstTrajTrackPair(&(*(*i_trajTrack).key), &(*(*i_trajTrack).val)));
2624  }
2625 
2626  //Loop over Tracks & Hits
2627  unsigned int trackSizeGood(0);
2628  ConstTrajTrackPairCollection::const_iterator iTrack;
2629  for (iTrack = trajTracks.begin(); iTrack != trajTracks.end(); ++iTrack) {
2630  const Trajectory* traj = (*iTrack).first;
2631  const reco::Track* track = (*iTrack).second;
2632 
2633  TrackStruct trackStruct;
2634  trackStruct.trkParams = this->fillTrackVariables(*track, *traj, beamSpot);
2635 
2636  if (trackCut_)
2637  continue;
2638 
2639  const std::vector<TrajectoryMeasurement> v_meas = (*traj).measurements();
2640 
2641  //Loop over Hits
2642  for (std::vector<TrajectoryMeasurement>::const_iterator i_meas = v_meas.begin(); i_meas != v_meas.end(); ++i_meas) {
2643  TrackStruct::HitParameterStruct hitParams = this->fillHitVariables(*i_meas, iSetup);
2644  if (this->hitSelected(hitParams))
2645  trackStruct.v_hitParams.push_back(hitParams);
2646  }
2647 
2648  if (analyzerMode_)
2649  this->fillHistsForAnalyzerMode(trackStruct);
2650  if (calculateApe_)
2651  this->fillHistsForApeCalculation(trackStruct);
2652 
2653  if (!trackStruct.v_hitParams.empty())
2654  ++trackSizeGood;
2655  }
2656  if (analyzerMode_ && trackSizeGood > 0)
2657  tkDetector_.TrkSizeGood->Fill(trackSizeGood);
2658 }
2659 
2660 // ------------ method called once each job just before starting event loop ------------
2662  this->hitSelection();
2663 
2664  this->sectorBuilder();
2665 
2666  this->residualErrorBinning();
2667 
2668  if (analyzerMode_)
2670 
2671  if (calculateApe_)
2673 
2674  if (analyzerMode_)
2675  this->bookTrackHists();
2676 }
2677 
2678 // ------------ method called once each job just after ending the event loop ------------
2680  if (calculateApe_)
2681  this->calculateAPE();
2682 
2683  edm::LogInfo("HitSelector") << "\nThere are " << counter1 << " negative Errors calculated\n";
2684 }
2685 
2686 //define this as a plug-in
ClusterRef cluster() const
Definition: SiPixelRecHit.h:47
bool inDoubleInterval(const std::vector< double > &, const float) const
static constexpr auto TEC
std::vector< unsigned int > v_sector
float uu() const
const edm::ParameterSet parameterSet_
ESGetTokenH3DDVariant esConsumes(std::string const &Record, edm::ConsumesCollector &)
Definition: DeDxTools.cc:283
T getParameter(std::string const &) const
Definition: ParameterSet.h:307
void hitSelection()
bool isOnEdge() const
Definition: SiPixelRecHit.h:97
void setCluster(const SiStripCluster &cluster, int detId)
T const & getData(const ESGetToken< T, R > &iToken) const noexcept(false)
Definition: EventSetup.h:119
void bookSectorHistsForAnalyzerMode()
const LocalTrajectoryError & localError() const
bool valid() const
Definition: LocalError.h:20
virtual GlobalVector inTesla(const GlobalPoint &gp) const =0
Field value ad specified global point, in Tesla.
ApeEstimator(const edm::ParameterSet &)
TrajectoryStateOnSurface const & forwardPredictedState() const
Access to forward predicted state (from fitter or builder)
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
const bool calculateApe_
void sectorBuilder()
unsigned int counter1
SiStripClusterInfo siStripClusterInfo_
const edm::ESGetToken< MagneticField, IdealMagneticFieldRecord > magFieldToken_
bool hasBadPixels() const
Definition: SiPixelRecHit.h:99
~ApeEstimator() override
PositionAndError2 radialPositionAndError2(const LocalPoint &, const LocalError &, const RadialStripTopology &)
unsigned int counter3
void fillHitHistsYForAnalyzerMode(const TrackStruct::HitParameterStruct &, TrackerSectorStruct &)
T x() const
Definition: PV2DBase.h:43
Log< level::Error, false > LogError
LocalError positionError() const
unsigned int counter4
void calculateAPE()
virtual const GeomDetType & type() const
Definition: GeomDet.cc:69
virtual float detHeight() const =0
PositionAndError2 rectangularPositionAndError2(const LocalPoint &, const LocalError &)
TrackerDetectorStruct tkDetector_
const unsigned int maxTracksPerEvent_
ClusterRef cluster() const
TrackStruct::HitParameterStruct fillHitVariables(const TrajectoryMeasurement &, const edm::EventSetup &)
bool checkIntervalsForSectors(const unsigned int sectorCounter, const std::vector< double > &) const
auto stripCharges() const -> decltype(cluster() ->amplitudes())
nStrips
1.2 is to make the matching window safely the two nearest strips 0.35 is the size of an ME0 chamber i...
constexpr float dzMax
void residualErrorBinning()
DataContainer const & measurements() const
Definition: Trajectory.h:178
const_iterator end() const
last iterator over the map (read only)
const edm::ESGetToken< SiStripLorentzAngle, SiStripLorentzAngleDepRcd > lorentzAngleToken_
float signalOverNoise() const
MeasurementPoint measurementPosition(const LocalPoint &) const override=0
T y() const
Definition: PV2DBase.h:44
const bool analyzerMode_
size_type size() const
map size
T * make(const Args &...args) const
make new ROOT object
float yy() const
Definition: LocalError.h:24
T x() const
Definition: PV3DBase.h:59
T y() const
Definition: PV3DBase.h:60
int iEvent
Definition: GenABIO.cc:224
std::vector< HitParameterStruct > v_hitParams
T sqrt(T t)
Definition: SSEVec.h:23
TrackStruct::TrackParameterStruct fillTrackVariables(const reco::Track &, const Trajectory &, const reco::BeamSpot &)
TrackParameterStruct trkParams
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
LocalVector localDirection() const
edm::EDGetTokenT< reco::BeamSpot > offlinebeamSpot_
uint32_t stereo() const
Definition: SiStripDetId.h:168
bool checkModulePositions(const float, const std::vector< double > &) const
uint8_t maxCharge() const
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
TrajectoryStateOnSurface const & backwardPredictedState() const
Access to backward predicted state (from smoother)
#define DEFINE_FWK_MODULE(type)
Definition: MakerMacros.h:16
virtual float angularWidth() const =0
virtual MeasurementPoint measurementPosition(const LocalPoint &) const =0
void analyze(const edm::Event &, const edm::EventSetup &) override
float stripAngle(float strip) const override=0
unsigned int counter6
static constexpr auto TOB
float clusterProbability(unsigned int flags=0) const
Definition: SiPixelRecHit.cc:9
std::map< unsigned int, TrackerSectorStruct > m_tkSector_
uint16_t maxStrip() const
DetId geographicalId() const
The label of this GeomDet.
Definition: GeomDet.h:64
std::map< unsigned int, std::pair< double, double > > m_resErrBins_
float localStripLength(const LocalPoint &) const override=0
LocalVector toLocal(const reco::Track::Vector &v, const Surface &s)
bool inUintInterval(const std::vector< unsigned int > &, const unsigned int, const unsigned int=999) const
#define M_PI
bool checkModuleBools(const bool, const std::vector< unsigned int > &) const
void bookTrackHists()
Log< level::Info, false > LogInfo
Detector identifier class for the strip tracker.
Definition: SiStripDetId.h:18
float xy() const
Definition: LocalError.h:23
uint16_t maxIndex() const
Definition: DetId.h:17
float getLorentzAngle(const uint32_t &) const
static constexpr auto TIB
const Plane & surface() const
The nominal surface of the GeomDet.
Definition: GeomDet.h:37
TFileDirectory mkdir(const std::string &dir, const std::string &descr="")
create a new subdirectory
Definition: TFileService.h:69
const PositionType & position() const
std::pair< uint16_t, uint16_t > chargeLR() const
TFileDirectory mkdir(const std::string &dir, const std::string &descr="")
create a new subdirectory
constexpr uint32_t rawId() const
get the raw id
Definition: DetId.h:57
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:12
Detector
Definition: DetId.h:24
virtual float originToIntersection() const =0
bool isSelected(const std::vector< L1HPSPFTauQualityCut > &qualityCuts, const l1t::PFCandidate &pfCand, float_t primaryVertexZ)
uint16_t width() const
virtual const Topology & topology() const =0
bool isValid() const
Definition: HandleBase.h:70
std::map< unsigned int, ReducedTrackerTreeVariables > m_tkTreeVar_
LocalError const & localAlignmentError() const
Return local alligment error.
bool isHit2D(const TrackingRecHit &) const
bool spansTwoROCs() const
const_iterator begin() const
first iterator over the map (read only)
Pixel cluster – collection of neighboring pixels above threshold.
void beginJob() override
fixed size matrix
unsigned int counter5
bool checkModuleIds(const unsigned int, const std::vector< unsigned int > &) const
HLT enums.
bool hitSelected(TrackStruct::HitParameterStruct &) const
void fillHistsForApeCalculation(const TrackStruct &)
SiStripRecHit2D originalHit() const
int qBin() const
Definition: SiPixelRecHit.h:92
bool checkModuleDirections(const int, const std::vector< int > &) const
unsigned int counter2
bool isPixel(HitType hitType)
const unsigned int minGoodHitsPerTrack_
MeasurementError measurementError(const LocalPoint &, const LocalError &) const override=0
void statistics(const TrackerSectorStruct &, const int) const
void setHitSelectionMap(const std::string &)
edm::EDGetTokenT< TrajTrackAssociationCollection > tjTagToken_
void fillHitHistsXForAnalyzerMode(const TrackStruct::HitParameterStruct &, TrackerSectorStruct &)
std::pair< const Trajectory *, const reco::Track * > ConstTrajTrackPair
Definition: Bounds.h:18
uint16_t charge() const
void fillHistsForAnalyzerMode(const TrackStruct &)
void bookSectorHistsForApeCalculation()
Log< level::Warning, false > LogWarning
std::map< std::string, std::vector< double > > m_hitSelection_
void initEvent(const edm::EventSetup &iSetup)
static uInt32 F(BLOWFISH_CTX *ctx, uInt32 x)
Definition: blowfish.cc:163
const Plane & specificSurface() const
Same as surface(), kept for backward compatibility.
Definition: GeomDet.h:40
void endJob() override
std::map< std::string, std::vector< unsigned int > > m_hitSelectionUInt_
float baryStrip() const
std::pair< TrackStruct::HitState, PositionAndError2 > StatePositionAndError2
void setHitSelectionMapUInt(const std::string &)
ClusterRef cluster() const
static constexpr auto TID
float vv() const
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29
float xx() const
Definition: LocalError.h:22
std::vector< unsigned int > v_rawId
ConstRecHitPointer const & recHit() const
Our base class.
Definition: SiPixelRecHit.h:23
StatePositionAndError2 positionAndError2(const LocalPoint &, const LocalError &, const TransientTrackingRecHit &)
const Bounds & bounds() const
Definition: Surface.h:87