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CSCHaloAlgo Class Reference

#include <CSCHaloAlgo.h>

Public Member Functions

reco::CSCHaloData Calculate (const CSCGeometry &TheCSCGeometry, edm::Handle< reco::MuonCollection > &TheCosmicMuons, const edm::Handle< reco::MuonTimeExtraMap > TheCSCTimeMap, edm::Handle< reco::MuonCollection > &TheMuons, edm::Handle< CSCSegmentCollection > &TheCSCSegments, edm::Handle< CSCRecHit2DCollection > &TheCSCRecHits, edm::Handle< L1MuGMTReadoutCollection > &TheL1GMTReadout, edm::Handle< edm::TriggerResults > &TheHLTResults, const edm::TriggerNames *triggerNames, const edm::Handle< CSCALCTDigiCollection > &TheALCTs, MuonSegmentMatcher *TheMatcher, const edm::Event &TheEvent)
 
 CSCHaloAlgo ()
 
void SetDetaThreshold (float x)
 
void SetDphiThreshold (float x)
 
void SetExpectedBX (int x)
 
void SetMatchingDEtaThreshold (float x)
 
void SetMatchingDPhiThreshold (float x)
 
void SetMatchingDWireThreshold (int x)
 
void SetMaxDtMuonSegment (float x)
 
void SetMaxFreeInverseBeta (float x)
 
void SetMaxSegmentPhiDiff (float x)
 
void SetMaxSegmentRDiff (float x)
 
void SetMaxSegmentTheta (float x)
 
void SetMinMaxInnerRadius (float min, float max)
 
void SetMinMaxOuterMomentumTheta (float min, float max)
 
void SetMinMaxOuterRadius (float min, float max)
 
void SetNormChi2Threshold (float x)
 
void SetRecHitTime0 (float x)
 
void SetRecHitTimeWindow (float x)
 
 ~CSCHaloAlgo ()
 

Public Attributes

std::vector< edm::InputTagvIT_HLTBit
 

Private Attributes

float deta_threshold
 
float dphi_threshold
 
int expected_BX
 
float matching_deta_threshold
 
float matching_dphi_threshold
 
int matching_dwire_threshold
 
float max_dt_muon_segment
 
float max_free_inverse_beta
 
float max_inner_radius
 
float max_outer_radius
 
float max_outer_theta
 
float max_segment_phi_diff
 
float max_segment_r_diff
 
float max_segment_theta
 
float min_inner_radius
 
float min_outer_radius
 
float min_outer_theta
 
float norm_chi2_threshold
 
float recHit_t0
 
float recHit_twindow
 

Detailed Description

Definition at line 84 of file CSCHaloAlgo.h.

Constructor & Destructor Documentation

CSCHaloAlgo::CSCHaloAlgo ( )

Definition at line 14 of file CSCHaloAlgo.cc.

References Pi.

15 {
16  deta_threshold = 0.;
17  min_inner_radius = 0.;
18  max_inner_radius = 9999.;
19  min_outer_radius = 0.;
20  max_outer_radius = 9999.;
21  dphi_threshold = 999.;
22  norm_chi2_threshold = 999.;
23  recHit_t0=0.;
24  recHit_twindow=25.;
25  expected_BX=3;
26  max_dt_muon_segment=-10.0;
28 
29  min_outer_theta = 0.;
31 
32  matching_dphi_threshold = 0.18; //radians
35 }
float recHit_t0
Definition: CSCHaloAlgo.h:130
const double Pi
float min_outer_radius
Definition: CSCHaloAlgo.h:126
float recHit_twindow
Definition: CSCHaloAlgo.h:131
float max_outer_radius
Definition: CSCHaloAlgo.h:127
float dphi_threshold
Definition: CSCHaloAlgo.h:128
float deta_threshold
Definition: CSCHaloAlgo.h:121
float max_inner_radius
Definition: CSCHaloAlgo.h:125
float min_outer_theta
Definition: CSCHaloAlgo.h:123
float matching_dphi_threshold
Definition: CSCHaloAlgo.h:133
float matching_deta_threshold
Definition: CSCHaloAlgo.h:134
float max_outer_theta
Definition: CSCHaloAlgo.h:122
float max_dt_muon_segment
Definition: CSCHaloAlgo.h:136
float min_inner_radius
Definition: CSCHaloAlgo.h:124
float max_free_inverse_beta
Definition: CSCHaloAlgo.h:137
int matching_dwire_threshold
Definition: CSCHaloAlgo.h:135
float norm_chi2_threshold
Definition: CSCHaloAlgo.h:129
CSCHaloAlgo::~CSCHaloAlgo ( )
inline

Definition at line 88 of file CSCHaloAlgo.h.

88 {}

Member Function Documentation

reco::CSCHaloData CSCHaloAlgo::Calculate ( const CSCGeometry TheCSCGeometry,
edm::Handle< reco::MuonCollection > &  TheCosmicMuons,
const edm::Handle< reco::MuonTimeExtraMap TheCSCTimeMap,
edm::Handle< reco::MuonCollection > &  TheMuons,
edm::Handle< CSCSegmentCollection > &  TheCSCSegments,
edm::Handle< CSCRecHit2DCollection > &  TheCSCRecHits,
edm::Handle< L1MuGMTReadoutCollection > &  TheL1GMTReadout,
edm::Handle< edm::TriggerResults > &  TheHLTResults,
const edm::TriggerNames triggerNames,
const edm::Handle< CSCALCTDigiCollection > &  TheALCTs,
MuonSegmentMatcher TheMatcher,
const edm::Event TheEvent 
)

Definition at line 37 of file CSCHaloAlgo.cc.

References Abs(), CSCGeometry::chamber(), chambers, MuonSubdetId::CSC, CSCDetId, CSCDetId::endcap(), PV3DBase< T, PVType, FrameType >::eta(), reco::MuonTimeExtra::freeInverseBeta(), reco::CSCHaloData::GetCSCTrackImpactPositions(), L1MuGMTReadoutCollection::getRecords(), reco::CSCHaloData::GetTracks(), CSCGeometry::idToDetUnit(), cmsHarvester::index, edm::HandleBase::isValid(), j, diffTwoXMLs::label, MuonSegmentMatcher::matchCSC(), RPCpg::mu, DetId::Muon, PV3DBase< T, PVType, FrameType >::phi(), Pi, edm::Handle< T >::product(), edm::RefVector< C, T, F >::push_back(), reco::CSCHaloData::SetHLTBit(), reco::CSCHaloData::SetNFlatHaloSegments(), reco::CSCHaloData::SetNIncomingTracks(), reco::CSCHaloData::SetNOutOfTimeHits(), reco::CSCHaloData::SetNOutOfTimeTriggers(), reco::CSCHaloData::SetNumberOfHaloTriggers(), reco::CSCHaloData::SetSegmentsBothEndcaps(), findQualityFiles::size, GeomDet::surface(), PV3DBase< T, PVType, FrameType >::theta(), theta(), GeomDet::toGlobal(), edm::TriggerNames::triggerIndex(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), detailsBasic3DVector::z, and PV3DBase< T, PVType, FrameType >::z().

49 {
50  reco::CSCHaloData TheCSCHaloData;
51  int imucount=0;
52  if( TheCosmicMuons.isValid() )
53  {
54  short int n_tracks_small_beta=0;
55  short int n_tracks_small_dT=0;
56  short int n_tracks_small_dT_and_beta=0;
57  for( reco::MuonCollection::const_iterator iMuon = TheCosmicMuons->begin() ; iMuon != TheCosmicMuons->end() ; iMuon++, imucount++ )
58  {
59  reco::TrackRef Track = iMuon->outerTrack();
60  if(!Track) continue;
61 
62  bool StoreTrack = false;
63  // Calculate global phi coordinate for central most rechit in the track
64  float innermost_global_z = 1500.;
65  float outermost_global_z = 0.;
66  GlobalPoint InnerMostGlobalPosition(0.,0.,0.); // smallest abs(z)
67  GlobalPoint OuterMostGlobalPosition(0.,0.,0.); // largest abs(z)
68  int nCSCHits = 0;
69  for(unsigned int j = 0 ; j < Track->extra()->recHitsSize(); j++ )
70  {
71  auto hit = Track->extra()->recHitRef(j);
72  if( !hit->isValid() ) continue;
73  DetId TheDetUnitId(hit->geographicalId());
74  if( TheDetUnitId.det() != DetId::Muon ) continue;
75  if( TheDetUnitId.subdetId() != MuonSubdetId::CSC ) continue;
76 
77  const GeomDetUnit *TheUnit = TheCSCGeometry.idToDetUnit(TheDetUnitId);
78  LocalPoint TheLocalPosition = hit->localPosition();
79  const BoundPlane& TheSurface = TheUnit->surface();
80  const GlobalPoint TheGlobalPosition = TheSurface.toGlobal(TheLocalPosition);
81 
82  float z = TheGlobalPosition.z();
83  if( TMath::Abs(z) < innermost_global_z )
84  {
85  innermost_global_z = TMath::Abs(z);
86  InnerMostGlobalPosition = GlobalPoint( TheGlobalPosition);
87  }
88  if( TMath::Abs(z) > outermost_global_z )
89  {
90  outermost_global_z = TMath::Abs(z);
91  OuterMostGlobalPosition = GlobalPoint( TheGlobalPosition );
92  }
93  nCSCHits ++;
94  }
95 
96  std::vector<const CSCSegment*> MatchedSegments = TheMatcher->matchCSC(*Track,TheEvent);
97  // Find the inner and outer segments separately in case they don't agree completely with recHits
98  // Plan for the possibility segments in both endcaps
99  float InnerSegmentTime[2] = {0,0};
100  float OuterSegmentTime[2] = {0,0};
101  float innermost_seg_z[2] = {1500,1500};
102  float outermost_seg_z[2] = {0,0};
103  for (std::vector<const CSCSegment*>::const_iterator segment =MatchedSegments.begin();
104  segment != MatchedSegments.end(); ++segment)
105  {
106  CSCDetId TheCSCDetId((*segment)->cscDetId());
107  const CSCChamber* TheCSCChamber = TheCSCGeometry.chamber(TheCSCDetId);
108  LocalPoint TheLocalPosition = (*segment)->localPosition();
109  const GlobalPoint TheGlobalPosition = TheCSCChamber->toGlobal(TheLocalPosition);
110  float z = TheGlobalPosition.z();
111  int TheEndcap = TheCSCDetId.endcap();
112  if( TMath::Abs(z) < innermost_seg_z[TheEndcap-1] )
113  {
114  innermost_seg_z[TheEndcap-1] = TMath::Abs(z);
115  InnerSegmentTime[TheEndcap-1] = (*segment)->time();
116  }
117  if( TMath::Abs(z) > outermost_seg_z[TheEndcap-1] )
118  {
119  outermost_seg_z[TheEndcap-1] = TMath::Abs(z);
120  OuterSegmentTime[TheEndcap-1] = (*segment)->time();
121  }
122  }
123 
124  if( nCSCHits < 3 ) continue; // This needs to be optimized, but is the minimum
125 
126  float dT_Segment = 0; // default safe value, looks like collision muon
127 
128  if( innermost_seg_z[0] < outermost_seg_z[0]) // two segments in ME+
129  dT_Segment = OuterSegmentTime[0]-InnerSegmentTime[0];
130  if( innermost_seg_z[1] < outermost_seg_z[1]) // two segments in ME-
131  {
132  // replace the measurement if there weren't segments in ME+ or
133  // if the track in ME- has timing more consistent with an incoming particle
134  if (dT_Segment == 0.0 || OuterSegmentTime[1]-InnerSegmentTime[1] < dT_Segment)
135  dT_Segment = OuterSegmentTime[1]-InnerSegmentTime[1] ;
136  }
137 
138  if( OuterMostGlobalPosition.x() == 0. || OuterMostGlobalPosition.y() == 0. || OuterMostGlobalPosition.z() == 0. )
139  continue;
140  if( InnerMostGlobalPosition.x() == 0. || InnerMostGlobalPosition.y() == 0. || InnerMostGlobalPosition.z() == 0. )
141  continue;
142 
143  //Its a CSC Track,store it if it passes halo selection
144  StoreTrack = true;
145 
146  float deta = TMath::Abs( OuterMostGlobalPosition.eta() - InnerMostGlobalPosition.eta() );
147  float dphi = TMath::ACos( TMath::Cos( OuterMostGlobalPosition.phi() - InnerMostGlobalPosition.phi() ) ) ;
148  float theta = Track->outerMomentum().theta();
149  float innermost_x = InnerMostGlobalPosition.x() ;
150  float innermost_y = InnerMostGlobalPosition.y();
151  float outermost_x = OuterMostGlobalPosition.x();
152  float outermost_y = OuterMostGlobalPosition.y();
153  float innermost_r = TMath::Sqrt(innermost_x *innermost_x + innermost_y * innermost_y );
154  float outermost_r = TMath::Sqrt(outermost_x *outermost_x + outermost_y * outermost_y );
155 
156  if( deta < deta_threshold )
157  StoreTrack = false;
158  if( theta > min_outer_theta && theta < max_outer_theta )
159  StoreTrack = false;
160  if( dphi > dphi_threshold )
161  StoreTrack = false;
162  if( innermost_r < min_inner_radius )
163  StoreTrack = false;
164  if( innermost_r > max_inner_radius )
165  StoreTrack = false;
166  if( outermost_r < min_outer_radius )
167  StoreTrack = false;
168  if( outermost_r > max_outer_radius )
169  StoreTrack = false;
170  if( Track->normalizedChi2() > norm_chi2_threshold )
171  StoreTrack = false;
172 
173  if( StoreTrack )
174  {
175  TheCSCHaloData.GetCSCTrackImpactPositions().push_back( InnerMostGlobalPosition );
176  TheCSCHaloData.GetTracks().push_back( Track );
177  }
178 
179  // Analyze the MuonTimeExtra information
180  if( TheCSCTimeMap.isValid() )
181  {
182  reco::MuonRef muonR(TheCosmicMuons,imucount);
183  const reco::MuonTimeExtraMap & timeMapCSC = *TheCSCTimeMap;
184  reco::MuonTimeExtra timecsc = timeMapCSC[muonR];
185  float freeInverseBeta = timecsc.freeInverseBeta();
186 
187  if (dT_Segment < max_dt_muon_segment )
188  n_tracks_small_dT++;
189  if (freeInverseBeta < max_free_inverse_beta)
190  n_tracks_small_beta++;
191  if ((dT_Segment < max_dt_muon_segment) && (freeInverseBeta < max_free_inverse_beta))
192  n_tracks_small_dT_and_beta++;
193  }
194  else
195  {
196  static std::atomic<bool> MuonTimeFail{false};
197  bool expected = false;
198  if( MuonTimeFail.compare_exchange_strong(expected,true,std::memory_order_acq_rel) )
199  {
200  edm::LogWarning ("InvalidInputTag") << "The MuonTimeExtraMap does not appear to be in the event. Some beam halo "
201  << " identification variables will be empty" ;
202  }
203  }
204  }
205  TheCSCHaloData.SetNIncomingTracks(n_tracks_small_dT,n_tracks_small_beta,n_tracks_small_dT_and_beta);
206  }
207  else // collection is invalid
208  {
209  static std::atomic<bool> CosmicFail{false};
210  bool expected = false;
211  if( CosmicFail.compare_exchange_strong(expected,true,std::memory_order_acq_rel) )
212  {
213  edm::LogWarning ("InvalidInputTag") << " The Cosmic Muon collection does not appear to be in the event. These beam halo "
214  << " identification variables will be empty" ;
215  }
216  }
217 
218  if( TheHLTResults.isValid() )
219  {
220  bool EventPasses = false;
221  for( unsigned int index = 0 ; index < vIT_HLTBit.size(); index++)
222  {
223  if( vIT_HLTBit[index].label().size() )
224  {
225  //Get the HLT bit and check to make sure it is valid
226  unsigned int bit = triggerNames->triggerIndex( vIT_HLTBit[index].label().c_str());
227  if( bit < TheHLTResults->size() )
228  {
229  //If any of the HLT names given by the user accept, then the event passes
230  if( TheHLTResults->accept( bit ) && !TheHLTResults->error( bit ) )
231  {
232  EventPasses = true;
233  }
234  }
235  }
236  }
237  if( EventPasses )
238  TheCSCHaloData.SetHLTBit(true);
239  else
240  TheCSCHaloData.SetHLTBit(false);
241  }
242  else // HLT results are not valid
243  {
244  static std::atomic<bool> HLTFail{false};
245  bool expected = false;
246  if( HLTFail.compare_exchange_strong(expected,true,std::memory_order_acq_rel) )
247  {
248  edm::LogWarning ("InvalidInputTag") << "The HLT results do not appear to be in the event. The beam halo HLT trigger "
249  << "decision will not be used in the halo identification";
250  }
251  }
252 
253  if( TheL1GMTReadout.isValid() )
254  {
255  L1MuGMTReadoutCollection const *gmtrc = TheL1GMTReadout.product ();
256  std::vector < L1MuGMTReadoutRecord > gmt_records = gmtrc->getRecords ();
257  std::vector < L1MuGMTReadoutRecord >::const_iterator igmtrr;
258 
259  int icsc = 0;
260  int PlusZ = 0 ;
261  int MinusZ = 0 ;
262  // Check to see if CSC BeamHalo trigger is tripped
263  for (igmtrr = gmt_records.begin (); igmtrr != gmt_records.end (); igmtrr++)
264  {
265  std::vector < L1MuRegionalCand >::const_iterator iter1;
266  std::vector < L1MuRegionalCand > rmc;
267  rmc = igmtrr->getCSCCands ();
268  for (iter1 = rmc.begin (); iter1 != rmc.end (); iter1++)
269  {
270  if (!(*iter1).empty ())
271  {
272  if ((*iter1).isFineHalo ())
273  {
274  float halophi = iter1->phiValue();
275  halophi = halophi > TMath::Pi() ? halophi - 2.*TMath::Pi() : halophi;
276  float haloeta = iter1->etaValue();
277  bool HaloIsGood = true;
278  // Check if halo trigger is faked by any collision muons
279  if( TheMuons.isValid() )
280  {
281  float dphi = 9999.;
282  float deta = 9999.;
283  for( reco::MuonCollection::const_iterator mu = TheMuons->begin(); mu != TheMuons->end() && HaloIsGood ; mu++ )
284  {
285  // Don't match with SA-only muons
286  if( mu->isStandAloneMuon() && !mu->isTrackerMuon() && !mu->isGlobalMuon() ) continue;
287 
288  /*
289  if(!mu->isTrackerMuon())
290  {
291  if( mu->isStandAloneMuon() )
292  {
293  //make sure that this SA muon is not actually a halo-like muon
294  float theta = mu->outerTrack()->outerMomentum().theta();
295  float deta = TMath::Abs(mu->outerTrack()->outerPosition().eta() - mu->outerTrack()->innerPosition().eta());
296  if( theta < min_outer_theta || theta > max_outer_theta ) //halo-like
297  continue;
298  else if ( deta > deta_threshold ) //halo-like
299  continue;
300  }
301  }
302  */
303 
304  const std::vector<MuonChamberMatch> chambers = mu->matches();
305  for(std::vector<MuonChamberMatch>::const_iterator iChamber = chambers.begin();
306  iChamber != chambers.end() ; iChamber ++ )
307  {
308  if( iChamber->detector() != MuonSubdetId::CSC ) continue;
309  for( std::vector<reco::MuonSegmentMatch>::const_iterator iSegment = iChamber->segmentMatches.begin() ;
310  iSegment != iChamber->segmentMatches.end(); ++iSegment )
311  {
312  edm::Ref<CSCSegmentCollection> cscSegment = iSegment->cscSegmentRef;
313  std::vector<CSCRecHit2D> hits = cscSegment -> specificRecHits();
314  for( std::vector<CSCRecHit2D>::iterator iHit = hits.begin();
315  iHit != hits.end() ; iHit++ )
316  {
317  DetId TheDetUnitId(iHit->cscDetId());
318  const GeomDetUnit *TheUnit = TheCSCGeometry.idToDetUnit(TheDetUnitId);
319  LocalPoint TheLocalPosition = iHit->localPosition();
320  const BoundPlane& TheSurface = TheUnit->surface();
321  GlobalPoint TheGlobalPosition = TheSurface.toGlobal(TheLocalPosition);
322 
323  float phi_ = TheGlobalPosition.phi();
324  float eta_ = TheGlobalPosition.eta();
325 
326  deta = deta < TMath::Abs( eta_ - haloeta ) ? deta : TMath::Abs( eta_ - haloeta );
327  dphi = dphi < TMath::ACos(TMath::Cos(phi_ - halophi)) ? dphi : TMath::ACos(TMath::Cos(phi_ - halophi));
328  }
329  }
330  }
331  if ( dphi < matching_dphi_threshold && deta < matching_deta_threshold)
332  HaloIsGood = false; // i.e., collision muon likely faked halo trigger
333  }
334  }
335  if( !HaloIsGood )
336  continue;
337  if( (*iter1).etaValue() > 0 )
338  PlusZ++;
339  else
340  MinusZ++;
341  }
342  else
343  icsc++;
344  }
345  }
346  }
347  TheCSCHaloData.SetNumberOfHaloTriggers(PlusZ, MinusZ);
348  }
349  else
350  {
351  static std::atomic<bool> L1Fail{false};
352  bool expected = false;
353  if( L1Fail.compare_exchange_strong(expected,true,std::memory_order_acq_rel) )
354  {
355  edm::LogWarning ("InvalidInputTag") << "The L1MuGMTReadoutCollection does not appear to be in the event. The L1 beam halo trigger "
356  << "decision will not be used in the halo identification";
357  }
358  }
359 
360  // Loop over CSCALCTDigi collection to look for out-of-time chamber triggers
361  // A collision muon in real data should only have ALCTDigi::getBX() = 3 ( in MC, it will be 6 )
362  // Note that there could be two ALCTs per chamber
363  short int n_alctsP=0;
364  short int n_alctsM=0;
365  if(TheALCTs.isValid())
366  {
367  for (CSCALCTDigiCollection::DigiRangeIterator j=TheALCTs->begin(); j!=TheALCTs->end(); j++)
368  {
369  const CSCALCTDigiCollection::Range& range =(*j).second;
370  CSCDetId detId((*j).first.rawId());
371  for (CSCALCTDigiCollection::const_iterator digiIt = range.first; digiIt!=range.second; ++digiIt)
372  {
373  if( (*digiIt).isValid() && ( (*digiIt).getBX() < expected_BX ) )
374  {
375  int digi_endcap = detId.endcap();
376  int digi_station = detId.station();
377  int digi_ring = detId.ring();
378  int digi_chamber = detId.chamber();
379  int digi_wire = digiIt->getKeyWG();
380  if( digi_station == 1 && digi_ring == 4 ) //hack
381  digi_ring = 1;
382 
383  bool DigiIsGood = true;
384  int dwire = 999.;
385  if( TheMuons.isValid() )
386  {
387  //Check if there are any collision muons with hits in the vicinity of the digi
388  for(reco::MuonCollection::const_iterator mu = TheMuons->begin(); mu!= TheMuons->end() && DigiIsGood ; mu++ )
389  {
390  if( !mu->isTrackerMuon() && !mu->isGlobalMuon() && mu->isStandAloneMuon() ) continue;
391 
392  const std::vector<MuonChamberMatch> chambers = mu->matches();
393  for(std::vector<MuonChamberMatch>::const_iterator iChamber = chambers.begin();
394  iChamber != chambers.end(); iChamber ++ )
395  {
396  if( iChamber->detector() != MuonSubdetId::CSC ) continue;
397  for( std::vector<reco::MuonSegmentMatch>::const_iterator iSegment = iChamber->segmentMatches.begin();
398  iSegment != iChamber->segmentMatches.end(); iSegment++ )
399  {
400  edm::Ref<CSCSegmentCollection> cscSegRef = iSegment->cscSegmentRef;
401  std::vector<CSCRecHit2D> hits = cscSegRef->specificRecHits();
402  for( std::vector<CSCRecHit2D>::iterator iHit = hits.begin();
403  iHit != hits.end(); iHit++ )
404  {
405  if( iHit->cscDetId().endcap() != digi_endcap ) continue;
406  if( iHit->cscDetId().station() != digi_station ) continue;
407  if( iHit->cscDetId().ring() != digi_ring ) continue;
408  if( iHit->cscDetId().chamber() != digi_chamber ) continue;
409  int hit_wire = iHit->hitWire();
410  dwire = dwire < TMath::Abs(hit_wire - digi_wire)? dwire : TMath::Abs(hit_wire - digi_wire );
411  }
412  }
413  }
414  if( dwire <= matching_dwire_threshold )
415  DigiIsGood = false; // collision-like muon is close to this digi
416  }
417  }
418  // only count out of time digis if they are not matched to collision muons
419  if( DigiIsGood )
420  {
421  if( detId.endcap() == 1 )
422  n_alctsP++;
423  else if ( detId.endcap() == 2)
424  n_alctsM++;
425  }
426  }
427  }
428  }
429  }
430  else
431  {
432  static std::atomic<bool> DigiFail{false};
433  bool expected = false;
434  if (DigiFail.compare_exchange_strong(expected,true,std::memory_order_acq_rel)){
435  edm::LogWarning ("InvalidInputTag") << "The CSCALCTDigiCollection does not appear to be in the event. The ALCT Digis will "
436  << " not be used in the halo identification";
437  }
438  }
439  TheCSCHaloData.SetNOutOfTimeTriggers(n_alctsP,n_alctsM);
440 
441  // Loop over the CSCRecHit2D collection to look for out-of-time recHits
442  // Out-of-time is defined as tpeak outside [t_0 + TOF - t_window, t_0 + TOF + t_window]
443  // where t_0 and t_window are configurable parameters
444  short int n_recHitsP = 0;
445  short int n_recHitsM = 0;
446  if( TheCSCRecHits.isValid() )
447  {
449  for (dRHIter = TheCSCRecHits->begin(); dRHIter != TheCSCRecHits->end(); dRHIter++)
450  {
451  if ( !((*dRHIter).isValid()) ) continue; // only interested in valid hits
452  CSCDetId idrec = (CSCDetId)(*dRHIter).cscDetId();
453  float RHTime = (*dRHIter).tpeak();
454  LocalPoint rhitlocal = (*dRHIter).localPosition();
455  const CSCChamber* chamber = TheCSCGeometry.chamber(idrec);
456  GlobalPoint globalPosition = chamber->toGlobal(rhitlocal);
457  float globZ = globalPosition.z();
458  if ( RHTime < (recHit_t0 - recHit_twindow) )
459  {
460  if( globZ > 0 )
461  n_recHitsP++;
462  else
463  n_recHitsM++;
464  }
465 
466  /*
467 
468  float globX = globalPosition.x();
469  float globY = globalPosition.y();
470  float globZ = globalPosition.z();
471  float TOF = (sqrt(globX*globX+ globY*globY + globZ*globZ))/29.9792458 ; //cm -> ns
472  if ( (RHTime < (recHit_t0 + TOF - recHit_twindow)) || (RHTime > (recHit_t0 + TOF + recHit_twindow)) )
473  {
474  if( globZ > 0 )
475  n_recHitsP++;
476  else
477  n_recHitsM++;
478  }
479  */
480  }
481  }
482  else
483  {
484  static std::atomic<bool> RecHitFail{false};
485  bool expected = false;
486  if( RecHitFail.compare_exchange_strong(expected,true,std::memory_order_acq_rel) )
487  {
488  edm::LogWarning ("InvalidInputTag") << "The requested CSCRecHit2DCollection does not appear to be in the event. The CSC RecHit "
489  << " variables used for halo identification will not be calculated or stored";
490  }
491  }
492  TheCSCHaloData.SetNOutOfTimeHits(n_recHitsP+n_recHitsM);
493  // MLR
494  // Loop through CSCSegments and count the number of "flat" segments with the same (r,phi),
495  // saving the value in TheCSCHaloData.
496  short int maxNSegments = 0;
497  bool plus_endcap = false;
498  bool minus_endcap = false;
499  bool both_endcaps = false;
500  //float r = 0., phi = 0.;
501  if (TheCSCSegments.isValid()) {
502  for(CSCSegmentCollection::const_iterator iSegment = TheCSCSegments->begin();
503  iSegment != TheCSCSegments->end();
504  iSegment++) {
505 
506  CSCDetId iCscDetID = iSegment->cscDetId();
507  bool SegmentIsGood=true;
508  //avoid segments from collision muons
509  if( TheMuons.isValid() )
510  {
511  for(reco::MuonCollection::const_iterator mu = TheMuons->begin(); mu!= TheMuons->end() && SegmentIsGood ; mu++ )
512  {
513  if( !mu->isTrackerMuon() && !mu->isGlobalMuon() && mu->isStandAloneMuon() ) continue;
514  const std::vector<MuonChamberMatch> chambers = mu->matches();
515  for(std::vector<MuonChamberMatch>::const_iterator kChamber = chambers.begin();
516  kChamber != chambers.end(); kChamber ++ )
517  {
518  if( kChamber->detector() != MuonSubdetId::CSC ) continue;
519  for( std::vector<reco::MuonSegmentMatch>::const_iterator kSegment = kChamber->segmentMatches.begin();
520  kSegment != kChamber->segmentMatches.end(); kSegment++ )
521  {
522  edm::Ref<CSCSegmentCollection> cscSegRef = kSegment->cscSegmentRef;
523  CSCDetId kCscDetID = cscSegRef->cscDetId();
524 
525  if( kCscDetID == iCscDetID )
526  {
527  SegmentIsGood = false;
528  }
529  }
530  }
531  }
532  }
533  if(!SegmentIsGood) continue;
534 
535  // Get local direction vector; if direction runs parallel to beamline,
536  // count this segment as beam halo candidate.
537  LocalPoint iLocalPosition = iSegment->localPosition();
538  LocalVector iLocalDirection = iSegment->localDirection();
539 
540  GlobalPoint iGlobalPosition = TheCSCGeometry.chamber(iCscDetID)->toGlobal(iLocalPosition);
541  GlobalVector iGlobalDirection = TheCSCGeometry.chamber(iCscDetID)->toGlobal(iLocalDirection);
542 
543  float iTheta = iGlobalDirection.theta();
544  if (iTheta > max_segment_theta && iTheta < TMath::Pi() - max_segment_theta) continue;
545 
546  float iPhi = iGlobalPosition.phi();
547  float iR = TMath::Sqrt(iGlobalPosition.x()*iGlobalPosition.x() + iGlobalPosition.y()*iGlobalPosition.y());
548  short int nSegs = 0;
549 
550  // Changed to loop over all Segments (so N^2) to catch as many segments as possible.
551  for (CSCSegmentCollection::const_iterator jSegment = TheCSCSegments->begin();
552  jSegment != TheCSCSegments->end();
553  jSegment++) {
554  if (jSegment == iSegment) continue;
555  SegmentIsGood=true;
556  LocalPoint jLocalPosition = jSegment->localPosition();
557  LocalVector jLocalDirection = jSegment->localDirection();
558  CSCDetId jCscDetID = jSegment->cscDetId();
559  GlobalPoint jGlobalPosition = TheCSCGeometry.chamber(jCscDetID)->toGlobal(jLocalPosition);
560  GlobalVector jGlobalDirection = TheCSCGeometry.chamber(jCscDetID)->toGlobal(jLocalDirection);
561  float jTheta = jGlobalDirection.theta();
562  float jPhi = jGlobalPosition.phi();
563  float jR = TMath::Sqrt(jGlobalPosition.x()*jGlobalPosition.x() + jGlobalPosition.y()*jGlobalPosition.y());
564 
565  if (TMath::ACos(TMath::Cos(jPhi - iPhi)) <= max_segment_phi_diff
566  && TMath::Abs(jR - iR) <= max_segment_r_diff
567  && (jTheta < max_segment_theta || jTheta > TMath::Pi() - max_segment_theta)) {
569  if( TheMuons.isValid() ) {
570  for(reco::MuonCollection::const_iterator mu = TheMuons->begin(); mu!= TheMuons->end() && SegmentIsGood ; mu++ ) {
571  if( !mu->isTrackerMuon() && !mu->isGlobalMuon() && mu->isStandAloneMuon() ) continue;
572  const std::vector<MuonChamberMatch> chambers = mu->matches();
573  for(std::vector<MuonChamberMatch>::const_iterator kChamber = chambers.begin();
574  kChamber != chambers.end(); kChamber ++ ) {
575  if( kChamber->detector() != MuonSubdetId::CSC ) continue;
576  for( std::vector<reco::MuonSegmentMatch>::const_iterator kSegment = kChamber->segmentMatches.begin();
577  kSegment != kChamber->segmentMatches.end(); kSegment++ ) {
578  edm::Ref<CSCSegmentCollection> cscSegRef = kSegment->cscSegmentRef;
579  CSCDetId kCscDetID = cscSegRef->cscDetId();
580 
581  if( kCscDetID == jCscDetID ) {
582  SegmentIsGood = false;
583  }
584  }
585  }
586  }
587  }
588  if(SegmentIsGood) {
589  nSegs++;
590  minus_endcap = iGlobalPosition.z() < 0 || jGlobalPosition.z() < 0;
591  plus_endcap = iGlobalPosition.z() > 0 || jGlobalPosition.z() > 0;
592  }
593  }
594  }
595  // Correct the fact that the way nSegs counts will always be short by 1
596  if (nSegs > 0) nSegs++;
597  if (nSegs > maxNSegments) {
598  // Use value of r, phi to collect halo CSCSegments for examining timing (not coded yet...)
599  //r = iR;
600  //phi = iPhi;
601  maxNSegments = nSegs;
602  both_endcaps = both_endcaps ? both_endcaps : minus_endcap && plus_endcap;
603  }
604  }
605  }
606  TheCSCHaloData.SetNFlatHaloSegments(maxNSegments);
607  TheCSCHaloData.SetSegmentsBothEndcaps(both_endcaps);
608  // End MLR
609 
610  return TheCSCHaloData;
611 }
float recHit_t0
Definition: CSCHaloAlgo.h:130
const double Pi
float max_segment_r_diff
Definition: CSCHaloAlgo.h:139
float min_outer_radius
Definition: CSCHaloAlgo.h:126
float recHit_twindow
Definition: CSCHaloAlgo.h:131
float max_outer_radius
Definition: CSCHaloAlgo.h:127
float dphi_threshold
Definition: CSCHaloAlgo.h:128
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:52
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
Geom::Theta< T > theta() const
T y() const
Definition: PV3DBase.h:63
std::vector< const CSCSegment * > matchCSC(const reco::Track &muon, const edm::Event &event)
float deta_threshold
Definition: CSCHaloAlgo.h:121
float max_inner_radius
Definition: CSCHaloAlgo.h:125
float min_outer_theta
Definition: CSCHaloAlgo.h:123
const Plane & surface() const
The nominal surface of the GeomDet.
Definition: GeomDet.h:40
float float float z
float max_segment_phi_diff
Definition: CSCHaloAlgo.h:140
float matching_dphi_threshold
Definition: CSCHaloAlgo.h:133
Geom::Theta< T > theta() const
Definition: PV3DBase.h:75
float matching_deta_threshold
Definition: CSCHaloAlgo.h:134
int endcap() const
Definition: CSCDetId.h:106
std::vector< edm::InputTag > vIT_HLTBit
Definition: CSCHaloAlgo.h:97
static const int CSC
Definition: MuonSubdetId.h:13
unsigned int triggerIndex(std::string const &name) const
Definition: TriggerNames.cc:32
float max_outer_theta
Definition: CSCHaloAlgo.h:122
float max_dt_muon_segment
Definition: CSCHaloAlgo.h:136
T z() const
Definition: PV3DBase.h:64
T Abs(T a)
Definition: MathUtil.h:49
const std::vector< GlobalPoint > & GetCSCTrackImpactPositions() const
Definition: CSCHaloData.h:78
void SetSegmentsBothEndcaps(bool b)
Definition: CSCHaloData.h:86
int j
Definition: DBlmapReader.cc:9
const int mu
Definition: Constants.h:22
float min_inner_radius
Definition: CSCHaloAlgo.h:124
bool isValid() const
Definition: HandleBase.h:75
void SetHLTBit(bool status)
Definition: CSCHaloData.h:74
Definition: DetId.h:18
void SetNFlatHaloSegments(short int nSegments)
Definition: CSCHaloData.h:85
T const * product() const
Definition: Handle.h:81
void SetNIncomingTracks(short int n_small_dT, short int n_small_beta, short int n_small_both)
Definition: CSCHaloData.h:70
const CSCChamber * chamber(CSCDetId id) const
Return the chamber corresponding to given DetId.
Definition: CSCGeometry.cc:118
void SetNumberOfHaloTriggers(int PlusZ, int MinusZ)
Definition: CSCHaloData.h:63
float max_segment_theta
Definition: CSCHaloAlgo.h:141
std::vector< CSCALCTDigi >::const_iterator const_iterator
float max_free_inverse_beta
Definition: CSCHaloAlgo.h:137
T eta() const
Definition: PV3DBase.h:76
int matching_dwire_threshold
Definition: CSCHaloAlgo.h:135
float norm_chi2_threshold
Definition: CSCHaloAlgo.h:129
float freeInverseBeta() const
Definition: MuonTimeExtra.h:36
std::vector< L1MuGMTReadoutRecord > const & getRecords() const
void push_back(value_type const &ref)
Add a Ref&lt;C, T&gt; to the RefVector.
Definition: RefVector.h:64
void SetNOutOfTimeHits(short int num)
Definition: CSCHaloData.h:68
std::pair< const_iterator, const_iterator > Range
virtual const GeomDetUnit * idToDetUnit(DetId) const override
Return the pointer to the GeomDetUnit corresponding to a given DetId.
Definition: CSCGeometry.cc:93
void SetNOutOfTimeTriggers(short int PlusZ, short int MinusZ)
Definition: CSCHaloData.h:66
static char chambers[264][20]
Definition: ReadPGInfo.cc:243
T x() const
Definition: PV3DBase.h:62
tuple size
Write out results.
edm::RefVector< reco::TrackCollection > & GetTracks()
Definition: CSCHaloData.h:59
void CSCHaloAlgo::SetDetaThreshold ( float  x)
inline

Definition at line 99 of file CSCHaloAlgo.h.

References deta_threshold, and x.

99 { deta_threshold = x;}
float deta_threshold
Definition: CSCHaloAlgo.h:121
Definition: DDAxes.h:10
void CSCHaloAlgo::SetDphiThreshold ( float  x)
inline

Definition at line 102 of file CSCHaloAlgo.h.

References dphi_threshold, and x.

102 { dphi_threshold = x;}
float dphi_threshold
Definition: CSCHaloAlgo.h:128
Definition: DDAxes.h:10
void CSCHaloAlgo::SetExpectedBX ( int  x)
inline

Definition at line 106 of file CSCHaloAlgo.h.

References expected_BX, and x.

106 { expected_BX = x ;}
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMatchingDEtaThreshold ( float  x)
inline

Definition at line 109 of file CSCHaloAlgo.h.

References matching_deta_threshold, and x.

float matching_deta_threshold
Definition: CSCHaloAlgo.h:134
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMatchingDPhiThreshold ( float  x)
inline

Definition at line 108 of file CSCHaloAlgo.h.

References matching_dphi_threshold, and x.

float matching_dphi_threshold
Definition: CSCHaloAlgo.h:133
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMatchingDWireThreshold ( int  x)
inline

Definition at line 110 of file CSCHaloAlgo.h.

References matching_dwire_threshold, and x.

int matching_dwire_threshold
Definition: CSCHaloAlgo.h:135
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMaxDtMuonSegment ( float  x)
inline

Definition at line 111 of file CSCHaloAlgo.h.

References max_dt_muon_segment, and x.

float max_dt_muon_segment
Definition: CSCHaloAlgo.h:136
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMaxFreeInverseBeta ( float  x)
inline

Definition at line 112 of file CSCHaloAlgo.h.

References max_free_inverse_beta, and x.

float max_free_inverse_beta
Definition: CSCHaloAlgo.h:137
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMaxSegmentPhiDiff ( float  x)
inline

Definition at line 116 of file CSCHaloAlgo.h.

References max_segment_phi_diff, and x.

116 { max_segment_phi_diff = x; }
float max_segment_phi_diff
Definition: CSCHaloAlgo.h:140
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMaxSegmentRDiff ( float  x)
inline

Definition at line 115 of file CSCHaloAlgo.h.

References max_segment_r_diff, and x.

115 { max_segment_r_diff = x; }
float max_segment_r_diff
Definition: CSCHaloAlgo.h:139
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMaxSegmentTheta ( float  x)
inline

Definition at line 117 of file CSCHaloAlgo.h.

References max_segment_theta, and x.

117 { max_segment_theta = x; }
float max_segment_theta
Definition: CSCHaloAlgo.h:141
Definition: DDAxes.h:10
void CSCHaloAlgo::SetMinMaxInnerRadius ( float  min,
float  max 
)
inline

Definition at line 100 of file CSCHaloAlgo.h.

References bookConverter::max, max_inner_radius, min(), and min_inner_radius.

float max_inner_radius
Definition: CSCHaloAlgo.h:125
T min(T a, T b)
Definition: MathUtil.h:58
float min_inner_radius
Definition: CSCHaloAlgo.h:124
void CSCHaloAlgo::SetMinMaxOuterMomentumTheta ( float  min,
float  max 
)
inline

Definition at line 107 of file CSCHaloAlgo.h.

References bookConverter::max, max_outer_theta, min(), and min_outer_theta.

float min_outer_theta
Definition: CSCHaloAlgo.h:123
float max_outer_theta
Definition: CSCHaloAlgo.h:122
T min(T a, T b)
Definition: MathUtil.h:58
void CSCHaloAlgo::SetMinMaxOuterRadius ( float  min,
float  max 
)
inline

Definition at line 101 of file CSCHaloAlgo.h.

References bookConverter::max, max_outer_radius, min(), and min_outer_radius.

float min_outer_radius
Definition: CSCHaloAlgo.h:126
float max_outer_radius
Definition: CSCHaloAlgo.h:127
T min(T a, T b)
Definition: MathUtil.h:58
void CSCHaloAlgo::SetNormChi2Threshold ( float  x)
inline

Definition at line 103 of file CSCHaloAlgo.h.

References norm_chi2_threshold, and x.

float norm_chi2_threshold
Definition: CSCHaloAlgo.h:129
Definition: DDAxes.h:10
void CSCHaloAlgo::SetRecHitTime0 ( float  x)
inline

Definition at line 104 of file CSCHaloAlgo.h.

References recHit_t0, and x.

104 { recHit_t0 = x;}
float recHit_t0
Definition: CSCHaloAlgo.h:130
Definition: DDAxes.h:10
void CSCHaloAlgo::SetRecHitTimeWindow ( float  x)
inline

Definition at line 105 of file CSCHaloAlgo.h.

References recHit_twindow, and x.

105 { recHit_twindow = x; }
float recHit_twindow
Definition: CSCHaloAlgo.h:131
Definition: DDAxes.h:10

Member Data Documentation

float CSCHaloAlgo::deta_threshold
private

Definition at line 121 of file CSCHaloAlgo.h.

Referenced by SetDetaThreshold().

float CSCHaloAlgo::dphi_threshold
private

Definition at line 128 of file CSCHaloAlgo.h.

Referenced by SetDphiThreshold().

int CSCHaloAlgo::expected_BX
private

Definition at line 132 of file CSCHaloAlgo.h.

Referenced by SetExpectedBX().

float CSCHaloAlgo::matching_deta_threshold
private

Definition at line 134 of file CSCHaloAlgo.h.

Referenced by SetMatchingDEtaThreshold().

float CSCHaloAlgo::matching_dphi_threshold
private

Definition at line 133 of file CSCHaloAlgo.h.

Referenced by SetMatchingDPhiThreshold().

int CSCHaloAlgo::matching_dwire_threshold
private

Definition at line 135 of file CSCHaloAlgo.h.

Referenced by SetMatchingDWireThreshold().

float CSCHaloAlgo::max_dt_muon_segment
private

Definition at line 136 of file CSCHaloAlgo.h.

Referenced by SetMaxDtMuonSegment().

float CSCHaloAlgo::max_free_inverse_beta
private

Definition at line 137 of file CSCHaloAlgo.h.

Referenced by SetMaxFreeInverseBeta().

float CSCHaloAlgo::max_inner_radius
private

Definition at line 125 of file CSCHaloAlgo.h.

Referenced by SetMinMaxInnerRadius().

float CSCHaloAlgo::max_outer_radius
private

Definition at line 127 of file CSCHaloAlgo.h.

Referenced by SetMinMaxOuterRadius().

float CSCHaloAlgo::max_outer_theta
private

Definition at line 122 of file CSCHaloAlgo.h.

Referenced by SetMinMaxOuterMomentumTheta().

float CSCHaloAlgo::max_segment_phi_diff
private

Definition at line 140 of file CSCHaloAlgo.h.

Referenced by SetMaxSegmentPhiDiff().

float CSCHaloAlgo::max_segment_r_diff
private

Definition at line 139 of file CSCHaloAlgo.h.

Referenced by SetMaxSegmentRDiff().

float CSCHaloAlgo::max_segment_theta
private

Definition at line 141 of file CSCHaloAlgo.h.

Referenced by SetMaxSegmentTheta().

float CSCHaloAlgo::min_inner_radius
private

Definition at line 124 of file CSCHaloAlgo.h.

Referenced by SetMinMaxInnerRadius().

float CSCHaloAlgo::min_outer_radius
private

Definition at line 126 of file CSCHaloAlgo.h.

Referenced by SetMinMaxOuterRadius().

float CSCHaloAlgo::min_outer_theta
private

Definition at line 123 of file CSCHaloAlgo.h.

Referenced by SetMinMaxOuterMomentumTheta().

float CSCHaloAlgo::norm_chi2_threshold
private

Definition at line 129 of file CSCHaloAlgo.h.

Referenced by SetNormChi2Threshold().

float CSCHaloAlgo::recHit_t0
private

Definition at line 130 of file CSCHaloAlgo.h.

Referenced by SetRecHitTime0().

float CSCHaloAlgo::recHit_twindow
private

Definition at line 131 of file CSCHaloAlgo.h.

Referenced by SetRecHitTimeWindow().

std::vector<edm::InputTag> CSCHaloAlgo::vIT_HLTBit

Definition at line 97 of file CSCHaloAlgo.h.