CMS 3D CMS Logo

/data/refman/pasoursint/CMSSW_5_3_6/src/RecoMuon/MuonSeedGenerator/src/MuonSeedCleaner.cc

Go to the documentation of this file.
00001 
00007 #include <RecoMuon/MuonSeedGenerator/src/MuonSeedCleaner.h>
00008 
00009 // Data Formats 
00010 #include <DataFormats/TrajectorySeed/interface/TrajectorySeedCollection.h>
00011 #include <DataFormats/TrajectorySeed/interface/TrajectorySeed.h>
00012 #include <DataFormats/CSCRecHit/interface/CSCRecHit2DCollection.h>
00013 #include <DataFormats/CSCRecHit/interface/CSCRecHit2D.h>
00014 #include <DataFormats/CSCRecHit/interface/CSCSegmentCollection.h>
00015 #include <DataFormats/CSCRecHit/interface/CSCSegment.h>
00016 #include <DataFormats/DTRecHit/interface/DTRecSegment4DCollection.h>
00017 #include <DataFormats/DTRecHit/interface/DTRecSegment4D.h>
00018 
00019 // Geometry
00020 #include <Geometry/CommonDetUnit/interface/GeomDet.h>
00021 #include <TrackingTools/DetLayers/interface/DetLayer.h>
00022 #include <RecoMuon/MeasurementDet/interface/MuonDetLayerMeasurements.h>
00023 #include <RecoMuon/DetLayers/interface/MuonDetLayerGeometry.h>
00024 #include <RecoMuon/Records/interface/MuonRecoGeometryRecord.h>
00025 
00026 // muon service
00027 #include <TrackingTools/TrajectoryState/interface/TrajectoryStateTransform.h>
00028 #include <DataFormats/TrajectoryState/interface/PTrajectoryStateOnDet.h>
00029 
00030 // Framework
00031 #include <FWCore/ParameterSet/interface/ParameterSet.h>
00032 #include "FWCore/Framework/interface/Event.h"
00033 #include <FWCore/Framework/interface/ESHandle.h>
00034 #include <FWCore/MessageLogger/interface/MessageLogger.h> 
00035 #include <DataFormats/Common/interface/Handle.h>
00036 
00037 // C++
00038 #include <vector>
00039 #include <deque>
00040 #include <utility>
00041 
00042 //typedef std::pair<double, TrajectorySeed> seedpr ;
00043 //static bool ptDecreasing(const seedpr s1, const seedpr s2) { return ( s1.first > s2.first ); }
00044 static bool lengthSorting(const TrajectorySeed s1, const TrajectorySeed s2) { return ( s1.nHits() > s2.nHits() ); }
00045 
00046 /*
00047  * Constructor
00048  */
00049 MuonSeedCleaner::MuonSeedCleaner(const edm::ParameterSet& pset){
00050 
00051   // Local Debug flag
00052   debug                = pset.getParameter<bool>("DebugMuonSeed");
00053 
00054   // muon service
00055   edm::ParameterSet serviceParameters = pset.getParameter<edm::ParameterSet>("ServiceParameters");
00056   theService        = new MuonServiceProxy(serviceParameters);
00057 
00058 }
00059 
00060 /*
00061  * Destructor
00062  */
00063 MuonSeedCleaner::~MuonSeedCleaner(){
00064 
00065   if (theService) delete theService;
00066 }
00067 
00068 /*********************************** 
00069  *
00070  *  Seed Cleaner
00071  *
00072  ***********************************/
00073 
00074 std::vector<TrajectorySeed> MuonSeedCleaner::seedCleaner(const edm::EventSetup& eventSetup, std::vector<TrajectorySeed>& seeds ) {
00075 
00076   theService->update(eventSetup);
00077   
00078   std::vector<TrajectorySeed> FinalSeeds;
00079   
00080   // group the seeds
00081   std::vector<SeedContainer> theCollection = GroupSeeds(seeds);
00082 
00083   // ckeck each group and pick the good one
00084   for (size_t i=0; i< theCollection.size(); i++ ) {
00085 
00086       // separate seeds w/ more than 1 segments and w/ 1st layer segment information
00087       SeedContainer goodSeeds   = SeedCandidates( theCollection[i], true );
00088       SeedContainer otherSeeds  = SeedCandidates( theCollection[i], false );
00089       if ( MomentumFilter( goodSeeds ) )  {
00090          //std::cout<<" == type1 "<<std::endl;
00091          TrajectorySeed bestSeed = Chi2LengthSelection( goodSeeds );
00092          FinalSeeds.push_back( bestSeed );
00093            
00094          GlobalPoint seedgp = SeedPosition( bestSeed );
00095          double eta = fabs( seedgp.eta() );
00096          if ( goodSeeds.size() > 2 && eta > 1.5 ) {
00097             TrajectorySeed anotherSeed  = MoreRecHits( goodSeeds );
00098             FinalSeeds.push_back( anotherSeed );
00099          }
00100       } 
00101       else if( MomentumFilter( otherSeeds ) ) {
00102          //std::cout<<" == type2 "<<std::endl;
00103          TrajectorySeed bestSeed = MoreRecHits( otherSeeds );
00104          FinalSeeds.push_back( bestSeed );
00105 
00106          GlobalPoint seedgp = SeedPosition( bestSeed );
00107          double eta = fabs( seedgp.eta() );
00108          if ( otherSeeds.size() > 2 && eta > 1.5 ) {
00109             TrajectorySeed anotherSeed  = LeanHighMomentum( otherSeeds );
00110             FinalSeeds.push_back( anotherSeed );
00111          }
00112       } 
00113       else {
00114          //std::cout<<" == type3 "<<std::endl;
00115          TrajectorySeed bestSeed = LeanHighMomentum( theCollection[i] );
00116          FinalSeeds.push_back( bestSeed );
00117 
00118          GlobalPoint seedgp = SeedPosition( bestSeed );
00119          double eta = fabs( seedgp.eta() );
00120          if ( theCollection.size() > 2 && eta > 1.5 ) {
00121             TrajectorySeed anotherSeed  = BiggerCone( theCollection[i] );
00122             FinalSeeds.push_back( anotherSeed );
00123          }
00124       }
00125   }  
00126   return FinalSeeds ; 
00127 
00128 }
00129 
00130 
00131 TrajectorySeed MuonSeedCleaner::Chi2LengthSelection(std::vector<TrajectorySeed>& seeds ) {
00132 
00133   if ( seeds.size() == 1 ) return seeds[0];
00134 
00135   int    winner   = 0 ;
00136   int    moreHits = 0 ;  
00137   double bestChi2 = 99999.;  
00138   for ( size_t i = 0; i < seeds.size(); i++ ) {
00139 
00140       // 1. fill out the Nchi2 of segments of the seed 
00141       //GlobalVector mom = SeedMomentum( seeds[i] ); // temporary use for debugging
00142       //double pt = sqrt( (mom.x()*mom.x()) + (mom.y()*mom.y()) );
00143       //std::cout<<" > SEED"<<i<<"  pt:"<<pt<< std::endl;
00144 
00145       double theChi2 = SeedChi2( seeds[i] );  
00146       double dChi2 = fabs( 1. - (theChi2 / bestChi2)) ;
00147       int    theHits = seeds[i].nHits() ;  
00148       int    dHits = theHits - moreHits ;
00149       //std::cout<<" -----  "<<std::endl;
00150 
00151       // 2. better chi2 
00152       if ( theChi2 < bestChi2 && dChi2 > 0.05 ) {
00153            winner = static_cast<int>(i) ;
00154            bestChi2 = theChi2 ;
00155            moreHits = theHits ;
00156       }
00157       // 3. if chi2 is not much better, pick more rechits one 
00158       if ( theChi2 >= bestChi2 && dChi2 < 0.05 && dHits > 0 ) {
00159            winner = static_cast<int>(i) ;
00160            bestChi2 = theChi2 ;
00161            moreHits = theHits ;
00162       }
00163 
00164   }
00165   //std::cout<<" Winner is "<< winner <<std::endl;
00166   TrajectorySeed theSeed =  seeds[winner];
00167   seeds.erase( seeds.begin()+winner ); 
00168   return theSeed;
00169 }
00170 
00171 TrajectorySeed MuonSeedCleaner::BiggerCone(std::vector<TrajectorySeed>& seeds ) {
00172 
00173   if ( seeds.size() == 1 ) return seeds[0];
00174 
00175   float biggerProjErr  = 9999.; 
00176   int winner = 0 ;
00177   AlgebraicSymMatrix mat(5,0) ; 
00178   for ( size_t i = 0; i < seeds.size(); i++ ) {
00179 
00180       edm::OwnVector<TrackingRecHit>::const_iterator r1 = seeds[i].recHits().first ;
00181       mat = r1->parametersError().similarityT( r1->projectionMatrix() );
00182 
00183       int    NRecHits = NRecHitsFromSegment( *r1 );
00184 
00185       float ddx = mat[1][1]; 
00186       float ddy = mat[2][2]; 
00187       float dxx = mat[3][3]; 
00188       float dyy = mat[4][4];
00189       float projectErr = sqrt( (ddx*10000.) + (ddy*10000.) + dxx + dyy ) ;
00190 
00191       if ( NRecHits < 5 ) continue ;
00192       if ( projectErr < biggerProjErr ) continue;
00193 
00194       winner = static_cast<int>(i) ;
00195       biggerProjErr = projectErr ;
00196   }
00197   TrajectorySeed theSeed = seeds[winner];
00198   seeds.erase( seeds.begin()+winner ); 
00199   return theSeed;
00200 
00201 }
00202 
00203 TrajectorySeed MuonSeedCleaner::LeanHighMomentum( std::vector<TrajectorySeed>& seeds ) {
00204 
00205   if ( seeds.size() == 1 ) return seeds[0];
00206 
00207   double highestPt = 0. ;  
00208   int    winner    = 0  ;
00209   for ( size_t i = 0; i < seeds.size(); i++ ) {
00210        GlobalVector mom = SeedMomentum( seeds[i] );
00211        double pt = sqrt( (mom.x()*mom.x()) + (mom.y()*mom.y()) );
00212        if ( pt > highestPt ) { 
00213           winner = static_cast<int>(i) ;
00214           highestPt = pt ;
00215        }
00216   }
00217   TrajectorySeed theSeed = seeds[winner];
00218   seeds.erase( seeds.begin()+winner ); 
00219   return theSeed;
00220 
00221 }
00222 
00223 
00224 TrajectorySeed MuonSeedCleaner::MoreRecHits(std::vector<TrajectorySeed>& seeds ) {
00225 
00226   if ( seeds.size() == 1 ) return seeds[0];
00227 
00228   int    winner   = 0 ;
00229   int    moreHits = 0 ;  
00230   double betterChi2 = 99999.;
00231   for ( size_t i = 0; i < seeds.size(); i++ ) {
00232 
00233       int    theHits = 0;  
00234       for (edm::OwnVector<TrackingRecHit>::const_iterator r1 = seeds[i].recHits().first; r1 != seeds[i].recHits().second; r1++){
00235           theHits += NRecHitsFromSegment( *r1 );
00236       }
00237 
00238       double theChi2 = SeedChi2( seeds[i] );  
00239    
00240       if ( theHits == moreHits && theChi2 < betterChi2  ) {
00241          betterChi2 = theChi2; 
00242          winner = static_cast<int>(i) ;
00243       } 
00244       if ( theHits > moreHits ) {
00245            moreHits = theHits ;
00246            betterChi2 = theChi2;
00247            winner = static_cast<int>(i) ;
00248       }
00249   }
00250   TrajectorySeed theSeed = seeds[winner];
00251   seeds.erase( seeds.begin()+winner ); 
00252   return theSeed;
00253 }
00254 
00255 
00256 SeedContainer MuonSeedCleaner::LengthFilter(std::vector<TrajectorySeed>& seeds ) {
00257  
00258   SeedContainer longSeeds; 
00259   int NSegs = 0;
00260   for (size_t i = 0; i< seeds.size(); i++) {
00261     
00262       int theLength = static_cast<int>( seeds[i].nHits());
00263       if ( theLength > NSegs ) {
00264          NSegs = theLength ;
00265          longSeeds.clear();
00266          longSeeds.push_back( seeds[i] );
00267       } 
00268       else if ( theLength == NSegs ) {
00269          longSeeds.push_back( seeds[i] );
00270       } else {
00271          continue;
00272       } 
00273   }
00274   //std::cout<<" final Length :"<<NSegs<<std::endl;
00275 
00276   return longSeeds ; 
00277   
00278 }
00279 
00280 
00281 bool MuonSeedCleaner::MomentumFilter(std::vector<TrajectorySeed>& seeds ) {
00282 
00283   bool findgoodMomentum = false;
00284   SeedContainer goodMomentumSeeds = seeds;
00285   seeds.clear();
00286   for ( size_t i = 0; i < goodMomentumSeeds.size(); i++ ) {
00287        GlobalVector mom = SeedMomentum( goodMomentumSeeds[i] );
00288        double pt = sqrt( (mom.x()*mom.x()) + (mom.y()*mom.y()) );
00289        if ( pt < 6. || pt > 2000. ) continue;
00290        //if ( pt < 6. ) continue;
00291        //std::cout<<" passed momentum :"<< pt <<std::endl;
00292        seeds.push_back( goodMomentumSeeds[i] );
00293        findgoodMomentum = true;  
00294   }
00295   if ( seeds.size() == 0 ) seeds = goodMomentumSeeds;
00296 
00297   return findgoodMomentum;
00298 }
00299 
00300 
00301 
00302 SeedContainer MuonSeedCleaner::SeedCandidates( std::vector<TrajectorySeed>& seeds, bool good ) {
00303 
00304   SeedContainer theCandidate;
00305   theCandidate.clear();
00306 
00307   bool longSeed = false;  
00308   bool withFirstLayer = false ;
00309 
00310   //std::cout<<"***** Seed Classification *****"<< seeds.size() <<std::endl;
00311   for ( size_t i = 0; i < seeds.size(); i++ ) {
00312 
00313       if (seeds[i].nHits() > 1 ) longSeed = true ;
00314       //std::cout<<"  Seed: "<<i<<" w/"<<seeds[i].nHits()<<" segs "<<std::endl;
00315       // looking for 1st layer segment
00316       int idx = 0;
00317       for (edm::OwnVector<TrackingRecHit>::const_iterator r1 = seeds[i].recHits().first; r1 != seeds[i].recHits().second; r1++){
00318 
00319          idx++;
00320          const GeomDet* gdet = theService->trackingGeometry()->idToDet( (*r1).geographicalId() );
00321          DetId geoId = gdet->geographicalId();
00322 
00323          if ( geoId.subdetId() == MuonSubdetId::DT ) {
00324             DTChamberId DT_Id( (*r1).geographicalId() );
00325             //std::cout<<" ID:"<<DT_Id <<" pos:"<< r1->localPosition()  <<std::endl;
00326             if (DT_Id.station() != 1)  continue;
00327             withFirstLayer = true;
00328          }
00329          if ( geoId.subdetId() == MuonSubdetId::CSC ) {
00330             idx++;
00331             CSCDetId CSC_Id = CSCDetId( (*r1).geographicalId() );
00332             //std::cout<<" ID:"<<CSC_Id <<" pos:"<< r1->localPosition()  <<std::endl;
00333             if (CSC_Id.station() != 1)  continue;
00334             withFirstLayer = true;
00335          }
00336       }
00337       bool goodseed = (longSeed && withFirstLayer) ? true : false ;
00338   
00339       if ( goodseed == good )  theCandidate.push_back( seeds[i] );
00340   }
00341   return theCandidate;
00342 
00343 }
00344 
00345 std::vector<SeedContainer> MuonSeedCleaner::GroupSeeds( std::vector<TrajectorySeed>& seeds) {
00346 
00347   std::vector<SeedContainer> seedCollection;
00348   seedCollection.clear();
00349   std::vector<TrajectorySeed> theGroup ;
00350   std::vector<bool> usedSeed(seeds.size(),false);
00351 
00352   // categorize seeds by comparing overlapping segments or a certian eta-phi cone 
00353   for (size_t i= 0; i<seeds.size(); i++){
00354     
00355     if (usedSeed[i]) continue;
00356     theGroup.push_back( seeds[i] );
00357     usedSeed[i] = true ;
00358 
00359     GlobalPoint pos1 = SeedPosition( seeds[i] );
00360 
00361     for (size_t j= i+1; j<seeds.size(); j++){
00362  
00363        // 1.1 seeds with overlaaping segments will be grouped together
00364        unsigned int overlapping = OverlapSegments(seeds[i], seeds[j]) ;
00365        if ( !usedSeed[j] && overlapping > 0 ) {
00366           // reject the identical seeds
00367           if ( seeds[i].nHits() == overlapping && seeds[j].nHits() == overlapping ) {
00368              usedSeed[j] = true ;
00369              continue;
00370           }
00371           theGroup.push_back( seeds[j] ); 
00372           usedSeed[j] = true ;
00373        }
00374        if (usedSeed[j]) continue;
00375 
00376        // 1.2 seeds in a certain cone are grouped together  
00377        GlobalPoint pos2 = SeedPosition( seeds[j]);
00378        double dh = pos1.eta() - pos2.eta() ;
00379        double df = pos1.phi() - pos2.phi() ;
00380        double dR = sqrt( (dh*dh) + (df*df) );
00381 
00382        if ( dR > 0.3 && seeds[j].nHits() == 1) continue;
00383        if ( dR > 0.2 && seeds[j].nHits() >  1) continue;
00384        theGroup.push_back( seeds[j] ); 
00385        usedSeed[j] = true ;
00386     }
00387     sort(theGroup.begin(), theGroup.end(), lengthSorting ) ;
00388     seedCollection.push_back(theGroup);
00389     //std::cout<<" group "<<seedCollection.size() <<" w/"<< theGroup.size() <<" seeds"<<std::endl; 
00390     theGroup.clear(); 
00391   }
00392   return seedCollection;
00393 
00394 }
00395 
00396 unsigned int MuonSeedCleaner::OverlapSegments( TrajectorySeed seed1, TrajectorySeed seed2 ) {
00397 
00398   unsigned int overlapping = 0;
00399   for (edm::OwnVector<TrackingRecHit>::const_iterator r1 = seed1.recHits().first; r1 != seed1.recHits().second; r1++){
00400       
00401       DetId id1 = (*r1).geographicalId();
00402       const GeomDet* gdet1 = theService->trackingGeometry()->idToDet( id1 );
00403       GlobalPoint gp1 = gdet1->toGlobal( (*r1).localPosition() );
00404 
00405       for (edm::OwnVector<TrackingRecHit>::const_iterator r2 = seed2.recHits().first; r2 != seed2.recHits().second; r2++){
00406 
00407           DetId id2 = (*r2).geographicalId();
00408           if (id1 != id2 ) continue;
00409 
00410           const GeomDet* gdet2 = theService->trackingGeometry()->idToDet( id2 );
00411           GlobalPoint gp2 = gdet2->toGlobal( (*r2).localPosition() );
00412 
00413           double dx = gp1.x() - gp2.x() ;
00414           double dy = gp1.y() - gp2.y() ;
00415           double dz = gp1.z() - gp2.z() ;
00416           double dL = sqrt( dx*dx + dy*dy + dz*dz);
00417 
00418           if ( dL < 1. ) overlapping ++;
00419       
00420       }
00421   }
00422   return overlapping ;
00423 
00424 }
00425 
00426 double MuonSeedCleaner::SeedChi2( TrajectorySeed seed ) {
00427 
00428   double theChi2 = 0.;  
00429   for (edm::OwnVector<TrackingRecHit>::const_iterator r1 = seed.recHits().first; r1 != seed.recHits().second; r1++){
00430       //std::cout<<"    segmet : "<<it <<std::endl; 
00431       theChi2 += NChi2OfSegment( *r1 );
00432   }
00433   theChi2 = theChi2 / seed.nHits() ;
00434 
00435   //std::cout<<" final Length :"<<NSegs<<std::endl;
00436   return theChi2 ;
00437 
00438 }
00439 
00440 int MuonSeedCleaner::SeedLength( TrajectorySeed seed ) {
00441 
00442   int theHits = 0;  
00443   for (edm::OwnVector<TrackingRecHit>::const_iterator r1 = seed.recHits().first; r1 != seed.recHits().second; r1++){
00444       //std::cout<<"    segmet : "<<it <<std::endl; 
00445       theHits += NRecHitsFromSegment( *r1 );
00446   }
00447 
00448   //std::cout<<" final Length :"<<NSegs<<std::endl;
00449   return theHits ;
00450 
00451 }
00452 
00453 GlobalPoint MuonSeedCleaner::SeedPosition( TrajectorySeed seed ) {
00454 
00455   
00456 
00457   PTrajectoryStateOnDet pTSOD = seed.startingState();
00458   DetId SeedDetId(pTSOD.detId());
00459   const GeomDet* geoDet = theService->trackingGeometry()->idToDet( SeedDetId );
00460   TrajectoryStateOnSurface SeedTSOS = trajectoryStateTransform::transientState(pTSOD, &(geoDet->surface()), &*theService->magneticField());
00461   GlobalPoint  pos  = SeedTSOS.globalPosition();
00462 
00463   return pos ;
00464 
00465 }
00466 
00467 GlobalVector MuonSeedCleaner::SeedMomentum( TrajectorySeed seed ) {
00468 
00469   
00470 
00471   PTrajectoryStateOnDet pTSOD = seed.startingState();
00472   DetId SeedDetId(pTSOD.detId());
00473   const GeomDet* geoDet = theService->trackingGeometry()->idToDet( SeedDetId );
00474   TrajectoryStateOnSurface SeedTSOS = trajectoryStateTransform::transientState(pTSOD, &(geoDet->surface()), &*theService->magneticField());
00475   GlobalVector  mom  = SeedTSOS.globalMomentum();
00476 
00477   return mom ;
00478 
00479 }
00480 
00481 int MuonSeedCleaner::NRecHitsFromSegment( const TrackingRecHit& rhit ) {
00482 
00483       int NRechits = 0 ; 
00484       const GeomDet* gdet = theService->trackingGeometry()->idToDet( rhit.geographicalId() );
00485       MuonTransientTrackingRecHit::MuonRecHitPointer theSeg = 
00486       MuonTransientTrackingRecHit::specificBuild(gdet, rhit.clone() );
00487 
00488       DetId geoId = gdet->geographicalId();
00489       if ( geoId.subdetId() == MuonSubdetId::DT ) {
00490          DTChamberId DT_Id( rhit.geographicalId() );
00491          std::vector<TrackingRecHit*> DThits = theSeg->recHits();
00492          int dt1DHits = 0;
00493          for (size_t j=0; j< DThits.size(); j++) {
00494              dt1DHits += (DThits[j]->recHits()).size();
00495          }
00496          NRechits = dt1DHits ;
00497       }
00498 
00499       if ( geoId.subdetId() == MuonSubdetId::CSC ) {
00500          NRechits = (theSeg->recHits()).size() ;
00501       }
00502       return NRechits ;
00503 }
00504 
00505 int MuonSeedCleaner::NRecHitsFromSegment( MuonTransientTrackingRecHit *rhit ) {
00506 
00507     int NRechits = 0 ; 
00508     DetId geoId = rhit->geographicalId();
00509     if ( geoId.subdetId() == MuonSubdetId::DT ) {
00510        DTChamberId DT_Id( geoId );
00511        std::vector<TrackingRecHit*> DThits = rhit->recHits();
00512        int dt1DHits = 0;
00513        for (size_t j=0; j< DThits.size(); j++) {
00514            dt1DHits += (DThits[j]->recHits()).size();
00515        }
00516        NRechits = dt1DHits ;
00517        //std::cout<<" D_rh("<< dt1DHits  <<") " ;
00518     }
00519     if ( geoId.subdetId() == MuonSubdetId::CSC ) {
00520        NRechits = (rhit->recHits()).size() ;
00521        //std::cout<<" C_rh("<<(rhit->recHits()).size() <<") " ;
00522     }
00523     return NRechits;
00524 
00525 }
00526 
00527 double MuonSeedCleaner::NChi2OfSegment( const TrackingRecHit& rhit ) {
00528 
00529       double NChi2 = 999999. ; 
00530       const GeomDet* gdet = theService->trackingGeometry()->idToDet( rhit.geographicalId() );
00531       MuonTransientTrackingRecHit::MuonRecHitPointer theSeg = 
00532       MuonTransientTrackingRecHit::specificBuild(gdet, rhit.clone() );
00533 
00534       double dof = static_cast<double>( theSeg->degreesOfFreedom() );
00535       NChi2 = theSeg->chi2() / dof ;
00536       //std::cout<<" Chi2 = "<< NChi2  <<" |" ;
00537 
00538       return NChi2 ;
00539 }
00540 
00541