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/data/refman/pasoursint/CMSSW_5_3_3/src/RecoEgamma/EgammaPhotonAlgos/src/ConversionHitChecker.cc

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00001 #include <iostream>
00002 #include <vector>
00003 #include <memory>
00004 #include "RecoEgamma/EgammaPhotonAlgos/interface/ConversionHitChecker.h"
00005 // Framework
00006 //
00007 #include "TrackingTools/PatternTools/interface/Trajectory.h"
00008 
00009 //
00010 
00011 
00012 std::pair<uint8_t,Measurement1DFloat> ConversionHitChecker::nHitsBeforeVtx(const Trajectory &traj, const reco::Vertex &vtx, double sigmaTolerance) const {
00013 
00014   const std::vector<TrajectoryMeasurement> &measurements = traj.measurements();
00015 
00016   //protect for empty trajectory
00017   if (measurements.size()==0) {
00018     return std::pair<unsigned int,Measurement1DFloat>(0,Measurement1DFloat());
00019   }
00020 
00021   //check ordering of measurements in trajectory
00022   bool inout = (traj.direction() == alongMomentum);
00023 
00024   GlobalPoint vtxPos(vtx.x(),vtx.y(),vtx.z());
00025   
00026   uint8_t nhits = 0;
00027 
00028   std::vector<TrajectoryMeasurement>::const_iterator closest = measurements.begin();
00029   double distance = 1e6;
00030   //iterate inside out, when distance to vertex starts increasing, we are at the closest hit
00031   for (std::vector<TrajectoryMeasurement>::const_iterator fwdit = measurements.begin(), revit = measurements.end()-1;
00032           fwdit != measurements.end(); ++fwdit,--revit) {
00033     
00034     std::vector<TrajectoryMeasurement>::const_iterator it;
00035     if (inout) {
00036       it = fwdit;
00037     }
00038     else {
00039       it = revit;
00040     }
00041 
00042     //increment hit counter, compute distance and set iterator if this hit is valid
00043     if (it->recHit() && it->recHit()->isValid()) {
00044       ++nhits;
00045       distance = (vtxPos - it->updatedState().globalPosition()).mag();
00046       closest = it;
00047     }
00048 
00049     if ( (measurements.end()-fwdit)==1) {
00050       break; 
00051     }
00052 
00053     //check if next valid hit is farther away from vertex than existing closest
00054     std::vector<TrajectoryMeasurement>::const_iterator nextit;
00055     if (inout) {
00056       nextit = it+1;
00057     }
00058     else {
00059       nextit = it-1;
00060     }
00061     
00062     
00063     if ( nextit->recHit() && nextit->recHit()->isValid() ) {
00064       double nextDistance = (vtxPos - nextit->updatedState().globalPosition()).mag();
00065       if (nextDistance > distance) {
00066         break;
00067       }
00068     }
00069     
00070   }
00071 
00072   //compute signed decaylength significance for closest hit and check if it is before the vertex
00073   //if not then we need to subtract it from the count of hits before the vertex, since it has been implicitly included
00074 
00075   GlobalVector momDir = closest->updatedState().globalMomentum().unit();
00076   double decayLengthHitToVtx = (vtxPos - closest->updatedState().globalPosition()).dot(momDir);
00077 
00078   AlgebraicVector3 j;
00079   j[0] = momDir.x();
00080   j[1] = momDir.y();
00081   j[2] = momDir.z();
00082   AlgebraicVector6 jj;
00083   jj[0] = momDir.x();
00084   jj[1] = momDir.y();
00085   jj[2] = momDir.z();
00086   jj[3] =0.;
00087   jj[4] =0.;
00088   jj[5] =0.;
00089   
00090   //TODO: In principle the hit measurement position is correlated with the vertex fit
00091   //at worst though we inflate the uncertainty by a factor of two
00092   double trackError2 = ROOT::Math::Similarity(jj,closest->updatedState().cartesianError().matrix());
00093   double vertexError2 = ROOT::Math::Similarity(j,vtx.covariance());
00094   double decayLenError = sqrt(trackError2+vertexError2);
00095 
00096   Measurement1DFloat decayLength(decayLengthHitToVtx,decayLenError);
00097 
00098   if (decayLength.significance() < sigmaTolerance) {  //decay length is not (significantly) positive, so hit is consistent with the vertex position or late
00099                                            //subtract it from wrong hits count
00100     --nhits;
00101   }
00102  
00103   return std::pair<unsigned int,Measurement1DFloat>(nhits,decayLength);
00104 
00105 }
00106 
00107 uint8_t ConversionHitChecker::nSharedHits(const reco::Track &trk1, const reco::Track &trk2) const {
00108  
00109   uint8_t nShared = 0;
00110 
00111   for (trackingRecHit_iterator iHit1 = trk1.recHitsBegin();  iHit1 != trk1.recHitsEnd(); ++iHit1) { 
00112     const TrackingRecHit *hit1 = iHit1->get();
00113     if (hit1->isValid()) {
00114       for (trackingRecHit_iterator iHit2 = trk2.recHitsBegin();  iHit2 != trk2.recHitsEnd(); ++iHit2) { 
00115         const TrackingRecHit *hit2 = iHit2->get();
00116         if (hit2->isValid() && hit1->sharesInput(hit2,TrackingRecHit::some)) {
00117           ++nShared;
00118         }
00119       }    
00120     }
00121   }
00122   
00123   return nShared;
00124 
00125 }
00126 
00127