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NuclearInteractionFinder.cc
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4 
6 
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12 
14 
16 
18 
19 
21 maxHits(iConfig.getParameter<int>("maxHits")),
22 rescaleErrorFactor(iConfig.getParameter<double>("rescaleErrorFactor")),
23 checkCompletedTrack(iConfig.getParameter<bool>("checkCompletedTrack")),
24 navigationSchoolName(iConfig.getParameter<std::string>("NavigationSchool"))
25 {
26 
27  std::string measurementTrackerName = iConfig.getParameter<std::string>("MeasurementTrackerName");
28 
32  edm::ESHandle<MeasurementTracker> measurementTrackerHandle;
33  edm::ESHandle<GeometricSearchTracker> theGeomSearchTrackerHandle;
34  edm::ESHandle<TrackerGeometry> theTrackerGeom;
35 
36  es.get<TrackerDigiGeometryRecord> ().get (theTrackerGeom);
37  es.get<TrackingComponentsRecord>().get("PropagatorWithMaterial",prop);
38  es.get<TrackingComponentsRecord>().get("Chi2",est);
39  es.get<CkfComponentsRecord>().get(measurementTrackerName, measurementTrackerHandle);
40  es.get<TrackerRecoGeometryRecord>().get(theGeomSearchTrackerHandle );
42 
46 
47  thePropagator = prop.product();
48  theEstimator = est.product();
49  theMeasurementTracker = measurementTrackerHandle.product();
50  theGeomSearchTracker = theGeomSearchTrackerHandle.product();
51 
52  LogDebug("NuclearSeedGenerator") << "New NuclearInteractionFinder instance with parameters : \n"
53  << "maxHits : " << maxHits << "\n"
54  << "rescaleErrorFactor : " << rescaleErrorFactor << "\n"
55  << "checkCompletedTrack : " << checkCompletedTrack << "\n";
56 
57  nuclTester = new NuclearTester(maxHits, theEstimator, theTrackerGeom.product() );
58 
59  currentSeed = new SeedFromNuclearInteraction(thePropagator, theTrackerGeom.product(), iConfig) ;
60 
62 }
63 //----------------------------------------------------------------------
65  delete nuclTester;
66  delete currentSeed;
67  delete thePrimaryHelix;
68 }
69 
70 //----------------------------------------------------------------------
72 
73  if(traj.empty() || !traj.isValid()) return false;
74 
75  LogDebug("NuclearSeedGenerator") << "Analyzis of a new trajectory with a number of valid hits = " << traj.foundHits();
76 
77  std::vector<TrajectoryMeasurement> measurements = traj.measurements();
78 
79  // initialization
80  nuclTester->reset( measurements.size() );
81  allSeeds.clear();
82 
83  LayerMeasurements layerMeasurements(*theMeasurementTracker, event);
84 
85  if(traj.direction()==alongMomentum) {
86  std::reverse(measurements.begin(), measurements.end());
87  }
88 
89  std::vector<TrajectoryMeasurement>::const_iterator it_meas = measurements.begin();
90 
91  std::vector<double> ncompatibleHits;
92  bool NIfound = false;
93 
94  // Loop on all the RecHits.
95  while(!NIfound)
96  {
97  if(it_meas == measurements.end()) break;
98 
99  // check only the maxHits outermost hits of the primary track
100  if(nuclTester->nHitsChecked() > maxHits) break;
101 
102  nuclTester->push_back(*it_meas, findCompatibleMeasurements(*it_meas, rescaleErrorFactor, layerMeasurements));
103 
104  LogDebug("NuclearSeedGenerator") << "Number of compatible meas:" << (nuclTester->back()).size() << "\n"
105  << "Mean distance between hits :" << nuclTester->meanHitDistance() << "\n"
106  << "Forward estimate :" << nuclTester->fwdEstimate() << "\n";
107 
108  // don't check tracks which reach the end of the tracker if checkCompletedTrack==false
109  if( checkCompletedTrack==false && (nuclTester->compatibleHits()).front()==0 ) break;
110 
111  if(nuclTester->isNuclearInteraction()) NIfound=true;
112 
113  ++it_meas;
114  }
115 
116  if(NIfound) {
117  LogDebug("NuclearSeedGenerator") << "NUCLEAR INTERACTION FOUND at index : " << nuclTester->nuclearIndex() << "\n";
118 
119  // Get correct parametrization of the helix of the primary track at the interaction point (to be used by improveCurrentSeed)
120  definePrimaryHelix(measurements.begin()+nuclTester->nuclearIndex()-1);
121 
122  this->fillSeeds( nuclTester->goodTMPair());
123 
124  return true;
125  }
126 
127  return false;
128 }
129 //----------------------------------------------------------------------
130 void NuclearInteractionFinder::definePrimaryHelix(std::vector<TrajectoryMeasurement>::const_iterator it_meas) {
131  // This method uses the 3 last TM after the interaction point to calculate the helix parameters
132 
133  GlobalPoint pt[3];
134  for(int i=0; i<3; i++) {
135  pt[i] = (it_meas->updatedState()).globalParameters().position();
136  it_meas++;
137  }
138  delete thePrimaryHelix;
139  thePrimaryHelix = new TangentHelix( pt[0], pt[1], pt[2] );
140 }
141 //----------------------------------------------------------------------
142 std::vector<TrajectoryMeasurement>
143 NuclearInteractionFinder::findCompatibleMeasurements(const TM& lastMeas, double rescale, const LayerMeasurements & layerMeasurements) const
144 {
145  const TSOS& currentState = lastMeas.updatedState();
146  LogDebug("NuclearSeedGenerator") << "currentState :" << currentState << "\n";
147 
148  TSOS newState = rescaleError(rescale, currentState);
149  return findMeasurementsFromTSOS(newState, lastMeas.recHit()->geographicalId(), layerMeasurements);
150 }
151 //----------------------------------------------------------------------
152 std::vector<TrajectoryMeasurement>
153 NuclearInteractionFinder::findMeasurementsFromTSOS(const TSOS& currentState, DetId detid, const LayerMeasurements & layerMeasurements) const {
154 
155  using namespace std;
156  int invalidHits = 0;
157  vector<TM> result;
158  const DetLayer* lastLayer = theGeomSearchTracker->detLayer( detid );
159  vector<const DetLayer*> nl;
160 
161  if(lastLayer) {
162  nl = theNavigationSchool->nextLayers(*lastLayer,*currentState.freeState(), alongMomentum);
163  }
164  else {
165  edm::LogError("NuclearInteractionFinder") << "In findCompatibleMeasurements : lastLayer not accessible";
166  return result;
167  }
168 
169  if (nl.empty()) {
170  LogDebug("NuclearSeedGenerator") << "In findCompatibleMeasurements : no compatible layer found";
171  return result;
172  }
173 
174  for (vector<const DetLayer*>::iterator il = nl.begin();
175  il != nl.end(); il++) {
176  vector<TM> tmp =
177  layerMeasurements.measurements((**il),currentState, *thePropagator, *theEstimator);
178  if ( !tmp.empty()) {
179  if ( result.empty()) result = tmp;
180  else {
181  // keep one dummy TM at the end, skip the others
182  result.insert( result.end()-invalidHits, tmp.begin(), tmp.end());
183  }
184  invalidHits++;
185  }
186  }
187 
188  // sort the final result, keep dummy measurements at the end
189  if ( result.size() > 1) {
190  sort( result.begin(), result.end()-invalidHits, TrajMeasLessEstim());
191  }
192  return result;
193 }
194 
195 //----------------------------------------------------------------------
196 void NuclearInteractionFinder::fillSeeds( const std::pair<TrajectoryMeasurement, std::vector<TrajectoryMeasurement> >& tmPairs ) {
197  // This method returns the seeds calculated by the class SeedsFromNuclearInteraction
198 
199  const TM& innerTM = tmPairs.first;
200  const std::vector<TM>& outerTMs = tmPairs.second;
201 
202  // Loop on all outer TM
203  for(std::vector<TM>::const_iterator outtm = outerTMs.begin(); outtm!=outerTMs.end(); outtm++) {
204  if((innerTM.recHit())->isValid() && (outtm->recHit())->isValid()) {
205  currentSeed->setMeasurements(innerTM.updatedState(), innerTM.recHit(), outtm->recHit());
206  allSeeds.push_back(*currentSeed);
207  }
208  else LogDebug("NuclearSeedGenerator") << "The initial hits for seeding are invalid" << "\n";
209  }
210  return;
211 }
212 //----------------------------------------------------------------------
213 std::unique_ptr<TrajectorySeedCollection> NuclearInteractionFinder::getPersistentSeeds() {
214  auto output = std::make_unique<TrajectorySeedCollection>();
215  for(std::vector<SeedFromNuclearInteraction>::const_iterator it_seed = allSeeds.begin(); it_seed != allSeeds.end(); it_seed++) {
216  if(it_seed->isValid()) {
217  output->push_back( it_seed->TrajSeed() );
218  }
219  else LogDebug("NuclearSeedGenerator") << "The seed is invalid" << "\n";
220  }
221  return output;
222 }
223 //----------------------------------------------------------------------
225  std::vector<SeedFromNuclearInteraction> newSeedCollection;
226 
227  LayerMeasurements layerMeasurements(*theMeasurementTracker, event);
228 
229  // loop on all actual seeds
230  for(std::vector<SeedFromNuclearInteraction>::const_iterator it_seed = allSeeds.begin(); it_seed != allSeeds.end(); it_seed++) {
231 
232  if( !it_seed->isValid() ) continue;
233 
234  // find compatible TM in an outer layer
235  std::vector<TM> thirdTMs = findMeasurementsFromTSOS( it_seed->updatedTSOS() , it_seed->outerHitDetId(), layerMeasurements );
236 
237  // loop on those new TMs
238  for(std::vector<TM>::const_iterator tm = thirdTMs.begin(); tm!= thirdTMs.end(); tm++) {
239 
240  if( ! tm->recHit()->isValid() ) continue;
241 
242  // create new seeds collection using the circle equation
243  currentSeed->setMeasurements(*thePrimaryHelix, it_seed->initialTSOS(), it_seed->outerHit(), tm->recHit() );
244  newSeedCollection.push_back( *currentSeed );
245  }
246  }
247  allSeeds.clear();
248  allSeeds = newSeedCollection;
249 }
250 //----------------------------------------------------------------------
252 
256 
257  // we assume that the error on q/p is equal to 20% of q/p * rescale
258  mr(0,0) = (ltp.signedInverseMomentum()*0.2*rescale)*(ltp.signedInverseMomentum()*0.2*rescale);
259 
260  // the error on dx/z and dy/dz is fixed to 10% (* rescale)
261  mr(1,1) = 1E-2*rescale*rescale;
262  mr(2,2) = 1E-2*rescale*rescale;
263 
264  // the error on the local x and y positions are not modified.
265  mr(3,3) = m(3,3);
266  mr(4,4) = m(4,4);
267 
268  return TSOS(ltp, mr, state.surface(), &(state.globalParameters().magneticField()), state.surfaceSide());
269 }
#define LogDebug(id)
size
Write out results.
bool empty() const
True if trajectory has no measurements.
Definition: Trajectory.h:254
T getParameter(std::string const &) const
int foundHits() const
Definition: Trajectory.h:225
std::vector< TrajectoryMeasurement > measurements(const DetLayer &layer, const TrajectoryStateOnSurface &startingState, const Propagator &prop, const MeasurementEstimator &est) const
ConstRecHitPointer const & recHit() const
std::unique_ptr< TrajectorySeedCollection > getPersistentSeeds()
Fill &#39;output&#39; with persistent nuclear seeds.
std::vector< int > compatibleHits() const
Definition: NuclearTester.h:61
const LocalTrajectoryParameters & localParameters() const
const TMContainer & back() const
Definition: NuclearTester.h:43
bool run(const Trajectory &traj, const MeasurementTrackerEvent &event)
Run the Finder.
std::vector< TrajectoryMeasurement > findMeasurementsFromTSOS(const TSOS &currentState, DetId detid, const LayerMeasurements &layerMeasurements) const
void improveSeeds(const MeasurementTrackerEvent &event)
Improve the seeds with a third RecHit.
const NavigationSchool * nav() const
ROOT::Math::SMatrix< double, 5, 5, ROOT::Math::MatRepSym< double, 5 > > AlgebraicSymMatrix55
void setMeasurements(const TSOS &tsosAtInteractionPoint, ConstRecHitPointer ihit, ConstRecHitPointer ohit)
Fill all data members from 2 TM&#39;s where the first one is supposed to be at the interaction point...
double fwdEstimate(const std::vector< TrajectoryMeasurement > &vecTM) const
int nuclearIndex() const
Definition: NuclearTester.h:55
PropagationDirection const & direction() const
Definition: Trajectory.cc:140
bool isNuclearInteraction()
Definition: NuclearTester.cc:9
float signedInverseMomentum() const
Signed inverse momentum q/p (zero for neutrals).
DataContainer const & measurements() const
Definition: Trajectory.h:196
void push_back(const TM &init_tm, const TMContainer &vecTM)
Definition: NuclearTester.h:38
const SurfaceType & surface() const
std::vector< TrajectoryMeasurement > findCompatibleMeasurements(const TM &lastMeas, double rescaleFactor, const LayerMeasurements &layerMeasurements) const
Find compatible TM of a TM with error rescaled by rescaleFactor.
SurfaceSide surfaceSide() const
Position relative to material, defined relative to momentum vector.
double meanHitDistance(const std::vector< TrajectoryMeasurement > &vecTM) const
FreeTrajectoryState const * freeState(bool withErrors=true) const
std::vector< SeedFromNuclearInteraction > allSeeds
void reset(unsigned int nMeasurements)
Definition: NuclearTester.h:49
const MeasurementTracker * theMeasurementTracker
const DetLayer * detLayer(const DetId &id) const
obsolete method. Use idToLayer() instead.
const NavigationSchool * theNavigationSchool
const AlgebraicSymMatrix55 & matrix() const
const MeasurementEstimator * theEstimator
const LocalTrajectoryError & localError() const
Definition: DetId.h:18
bool isValid() const
Definition: Trajectory.h:279
const GlobalTrajectoryParameters & globalParameters() const
std::vector< const DetLayer * > nextLayers(const DetLayer &detLayer, Args &&...args) const
NavigationDirection.
edm::ESHandle< MagneticField > theMagField
const GeometricSearchTracker * theGeomSearchTracker
measurementTrackerName
possibility to inhibit extended forward coverage
TrajectoryStateOnSurface TSOS
std::vector< std::vector< double > > tmp
Definition: MVATrainer.cc:100
T get() const
Definition: EventSetup.h:68
void fillSeeds(const std::pair< TrajectoryMeasurement, std::vector< TrajectoryMeasurement > > &tmPairs)
get the seeds at the interaction point
Class used to test if a track has interacted nuclearly.
Definition: NuclearTester.h:16
const MagneticField & magneticField() const
TrajectoryStateOnSurface const & updatedState() const
unsigned int nHitsChecked() const
Definition: NuclearTester.h:59
void definePrimaryHelix(std::vector< TrajectoryMeasurement >::const_iterator it_meas)
Calculate the parameters of the circle representing the primary track at the interaction point...
TrajectoryStateOnSurface rescaleError(float rescale, const TSOS &state) const
T const * product() const
Definition: ESHandle.h:84
const TMPair & goodTMPair() const
Definition: NuclearTester.h:57
Definition: event.py:1
SeedFromNuclearInteraction * currentSeed