d9/d44/DAClusterizerInZ_8cc_source.html

 #include "RecoVertex/PrimaryVertexProducer/interface/DAClusterizerInZ.h"

 #include "FWCore/MessageLogger/interface/MessageLogger.h"

 #include "DataFormats/GeometryCommonDetAlgo/interface/Measurement1D.h"

 #include "RecoVertex/VertexPrimitives/interface/VertexException.h"


 using namespace std;


 namespace {


   bool recTrackLessZ1(const DAClusterizerInZ::track_t & tk1,

                      const DAClusterizerInZ::track_t & tk2)

   {

     return tk1.z < tk2.z;

   }

 }


 vector<DAClusterizerInZ::track_t> DAClusterizerInZ::fill(

               const vector<reco::TransientTrack> & tracks

               )const{

   // prepare track data for clustering

   vector<track_t> tks;

   for(vector<reco::TransientTrack>::const_iterator it=tracks.begin(); it!=tracks.end(); it++){

     track_t t;

     t.z=((*it).stateAtBeamLine().trackStateAtPCA()).position().z();

     double tantheta=tan(((*it).stateAtBeamLine().trackStateAtPCA()).momentum().theta());

     double phi=((*it).stateAtBeamLine().trackStateAtPCA()).momentum().phi();

     //  get the beam-spot

     reco::BeamSpot beamspot=(it->stateAtBeamLine()).beamSpot();

     t.dz2= pow((*it).track().dzError(),2)          // track errror

       + (pow(beamspot.BeamWidthX()*cos(phi),2)+pow(beamspot.BeamWidthY()*sin(phi),2))/pow(tantheta,2)  // beam-width induced

       + pow(vertexSize_,2);                        // intrinsic vertex size, safer for outliers and short lived decays

     if (d0CutOff_>0){

       Measurement1D IP=(*it).stateAtBeamLine().transverseImpactParameter();// error constains beamspot

       t.pi=1./(1.+exp(pow(IP.value()/IP.error(),2)-pow(d0CutOff_ ,2)));  // reduce weight for high ip tracks

     }else{

       t.pi=1.;

     }

     t.tt=&(*it);

     t.Z=1.;

     tks.push_back(t);

   }

   return tks;

 }


 double DAClusterizerInZ::Eik(const track_t & t, const vertex_t &k )const{

   return pow(t.z-k.z,2)/t.dz2;

 }


 double DAClusterizerInZ::update(

                        double beta,

                        vector<track_t> & tks,

                        vector<vertex_t> & y

                        )const{

   //update weights and vertex positions

   // mass constrained annealing without noise

   // returns the squared sum of changes of vertex positions


   unsigned int nt=tks.size();


   //initialize sums

   double sumpi=0;

   for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     k->se=0;    k->sw=0;   k->swz=0;

     k->swE=0;  k->Tc=0;

   }


   // loop over tracks

   for(unsigned int i=0; i<nt; i++){


     // update pik and Zi

     double Zi=0.;

     for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

       k->ei=exp(-beta*Eik(tks[i],*k));// cache exponential for one track at a time

       Zi += k->pk * k->ei;

     }

     tks[i].Z=Zi;


     // normalization for pk

     if (tks[i].Z>0){

       sumpi += tks[i].pi;

       // accumulate weighted z and weights for vertex update

       for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     k->se += tks[i].pi* k->ei / Zi;

     double w = k->pk * tks[i].pi* k->ei / Zi / tks[i].dz2;

     k->sw  += w;

     k->swz += w * tks[i].z;

     k->swE+= w*Eik(tks[i],*k);

       }

     }else{

       sumpi += tks[i].pi;

     }


   } // end of track loop


   // now update z and pk

   double delta=0;

   for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     if ( k->sw > 0){

       double znew=k->swz/k->sw;

       delta+=pow(k->z-znew,2);

       k->z=znew;

       k->Tc=2*k->swE/k->sw;

     }else{

       edm::LogInfo("sumw") <<  "invalid sum of weights in fit: " << k->sw << endl;

       if(verbose_){cout << " a cluster melted away ?  pk=" << k->pk <<  " sumw=" << k->sw <<  endl;}

       k->Tc=-1;

     }


     k->pk = k->pk * k->se / sumpi;

   }


   // return how much the prototypes moved

   return delta;

 }


 double DAClusterizerInZ::update(

                 double beta,

                 vector<track_t> & tks,

                 vector<vertex_t> & y,

                 double & rho0

                 )const{

   // MVF style, no more vertex weights, update tracks weights and vertex positions, with noise

   // returns the squared sum of changes of vertex positions


   unsigned int nt=tks.size();


   //initialize sums

   for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     k->se=0;    k->sw=0;   k->swz=0;

     k->swE=0;  k->Tc=0;

   }


   // loop over tracks

   for(unsigned int i=0; i<nt; i++){


     // update pik and Zi

     double Zi=rho0*exp(-beta*dzCutOff_*dzCutOff_);// cut-off

     for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

       k->ei=exp(-beta*Eik(tks[i],*k));// cache exponential for one track at a time

       Zi += k->pk * k->ei;

     }

     tks[i].Z=Zi;


     // normalization

     if (tks[i].Z>0){

        // accumulate weighted z and weights for vertex update

       for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     k->se += tks[i].pi* k->ei / Zi;

     double w = k->pk * tks[i].pi* k->ei / Zi / tks[i].dz2;

     k->sw  += w;

     k->swz += w * tks[i].z;

     k->swE+= w*Eik(tks[i],*k);

       }

     }


   } // end of track loop


   // now update z

   double delta=0;

   for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     if ( k->sw > 0){

       double znew=k->swz/k->sw;

       delta+=pow(k->z-znew,2);

       k->z=znew;

       k->Tc=2*k->swE/k->sw;

     }else{

       edm::LogInfo("sumw") <<  "invalid sum of weights in fit: " << k->sw << endl;

       if(verbose_){cout << " a cluster melted away ?  pk=" << k->pk <<  " sumw=" << k->sw <<  endl;}

       k->Tc=0;

     }


   }


   // return how much the prototypes moved

   return delta;

 }


 bool DAClusterizerInZ::merge(vector<vertex_t> & y, int nt)const{

   // merge clusters that collapsed or never separated, return true if vertices were merged, false otherwise


   if(y.size()<2)  return false;


   for(vector<vertex_t>::iterator k=y.begin(); (k+1)!=y.end(); k++){

     if( fabs( (k+1)->z - k->z ) < 1.e-3 ){  // with fabs if only called after freeze-out (splitAll() at highter T)

      double rho=k->pk + (k+1)->pk;

       if(rho>0){

     k->z=( k->pk * k->z + (k+1)->z * (k+1)->pk)/rho;

       }else{

     k->z=0.5*(k->z + (k+1)->z);

       }

       k->pk=rho;


       y.erase(k+1);

       return true;

     }

   }


   return false;

 }


 bool DAClusterizerInZ::merge(vector<vertex_t> & y, double & beta)const{

   // merge clusters that collapsed or never separated,

   // only merge if the estimated critical temperature of the merged vertex is below the current temperature

   // return true if vertices were merged, false otherwise

   if(y.size()<2)  return false;


   for(vector<vertex_t>::iterator k=y.begin(); (k+1)!=y.end(); k++){

     if (fabs((k+1)->z - k->z)<2.e-3){

       double rho=k->pk + (k+1)->pk;

       double swE=k->swE+(k+1)->swE - k->pk * (k+1)->pk /rho *pow((k+1)->z - k->z,2);

       double Tc=2*swE/(k->sw+(k+1)->sw);


       if(Tc*beta<1){

     if(rho>0){

       k->z=( k->pk * k->z + (k+1)->z * (k+1)->pk)/rho;

     }else{

       k->z=0.5*(k->z + (k+1)->z);

     }

     k->pk=rho;

     k->sw+=(k+1)->sw;

     k->swE=swE;

     k->Tc=Tc;

     y.erase(k+1);

     return true;

       }

     }

   }


   return false;

 }


 bool DAClusterizerInZ::purge(vector<vertex_t> & y, vector<track_t> & tks, double & rho0, const double beta)const{

   // eliminate clusters with only one significant/unique track

   if(y.size()<2)  return false;


   unsigned int nt=tks.size();

   double sumpmin=nt;

   vector<vertex_t>::iterator k0=y.end();

   for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     int nUnique=0;

     double sump=0;

     double pmax=k->pk/(k->pk+rho0*exp(-beta*dzCutOff_*dzCutOff_));

     for(unsigned int i=0; i<nt; i++){

       if(tks[i].Z>0){

     double p=k->pk * exp(-beta*Eik(tks[i],*k)) / tks[i].Z;

     sump+=p;

     if( (p > 0.9*pmax) && (tks[i].pi>0) ){ nUnique++; }

       }

     }


     if((nUnique<2)&&(sump<sumpmin)){

       sumpmin=sump;

       k0=k;

     }

   }


   if(k0!=y.end()){

     if(verbose_){cout << "eliminating prototype at " << k0->z << " with sump=" << sumpmin << endl;}

     //rho0+=k0->pk;

     y.erase(k0);

     return true;

   }else{

     return false;

   }

 }


 double DAClusterizerInZ::beta0(

                    double betamax,

                    vector<track_t> & tks,

                    vector<vertex_t> & y

                    )const{


   double T0=0;  // max Tc for beta=0

   // estimate critical temperature from beta=0 (T=inf)

   unsigned int nt=tks.size();


   for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){


     // vertex fit at T=inf

     double sumwz=0;

     double sumw=0;

     for(unsigned int i=0; i<nt; i++){

       double w=tks[i].pi/tks[i].dz2;

       sumwz+=w*tks[i].z;

       sumw +=w;

     }

     k->z=sumwz/sumw;


     // estimate Tcrit, eventually do this in the same loop

     double a=0, b=0;

     for(unsigned int i=0; i<nt; i++){

       double dx=tks[i].z-(k->z);

       double w=tks[i].pi/tks[i].dz2;

       a+=w*pow(dx,2)/tks[i].dz2;

       b+=w;

     }

     double Tc= 2.*a/b;  // the critical temperature of this vertex

     if(Tc>T0) T0=Tc;

   }// vertex loop (normally there should be only one vertex at beta=0)


   if (T0>1./betamax){

     return betamax/pow(coolingFactor_, int(log(T0*betamax)/log(coolingFactor_))-1 );

   }else{

     // ensure at least one annealing step

     return betamax/coolingFactor_;

   }

 }


 bool DAClusterizerInZ::split(

              double beta,

              vector<track_t> & tks,

              vector<vertex_t> & y,

              double threshold

              )const{

   // split only critical vertices (Tc >~ T=1/beta   <==>   beta*Tc>~1)

   // an update must have been made just before doing this (same beta, no merging)

   // returns true if at least one cluster was split


   double epsilon=1e-3;      // split all single vertices by 10 um

   bool split=false;


   // avoid left-right biases by splitting highest Tc first


   std::vector<std::pair<double, unsigned int> > critical;

   for(unsigned int ik=0; ik<y.size(); ik++){

     if (beta*y[ik].Tc > 1.){

       critical.push_back( make_pair(y[ik].Tc, ik));

     }

   }

   stable_sort(critical.begin(), critical.end(), std::greater<std::pair<double, unsigned int> >() );


   for(unsigned int ic=0; ic<critical.size(); ic++){

     unsigned int ik=critical[ic].second;

     // estimate subcluster positions and weight

     double p1=0, z1=0, w1=0;

     double p2=0, z2=0, w2=0;

     //double sumpi=0;

     for(unsigned int i=0; i<tks.size(); i++){

       if(tks[i].Z>0){

     //sumpi+=tks[i].pi;

     double p=y[ik].pk * exp(-beta*Eik(tks[i],y[ik])) / tks[i].Z*tks[i].pi;

     double w=p/tks[i].dz2;

     if(tks[i].z<y[ik].z){

       p1+=p; z1+=w*tks[i].z; w1+=w;

     }else{

       p2+=p; z2+=w*tks[i].z; w2+=w;

     }

       }

     }

     if(w1>0){  z1=z1/w1;} else{z1=y[ik].z-epsilon;}

     if(w2>0){  z2=z2/w2;} else{z2=y[ik].z+epsilon;}


     // reduce split size if there is not enough room

     if( ( ik   > 0       ) && ( y[ik-1].z>=z1 ) ){ z1=0.5*(y[ik].z+y[ik-1].z); }

     if( ( ik+1 < y.size()) && ( y[ik+1].z<=z2 ) ){ z2=0.5*(y[ik].z+y[ik+1].z); }


     // split if the new subclusters are significantly separated

     if( (z2-z1)>epsilon){

       split=true;

       vertex_t vnew;

       vnew.pk = p1*y[ik].pk/(p1+p2);

       y[ik].pk= p2*y[ik].pk/(p1+p2);

       vnew.z  = z1;

       y[ik].z = z2;

       y.insert(y.begin()+ik, vnew);


      // adjust remaining pointers

       for(unsigned int jc=ic; jc<critical.size(); jc++){

     if (critical[jc].second>ik) {critical[jc].second++;}

       }

     }

   }


   //  stable_sort(y.begin(), y.end(), clusterLessZ);

   return split;

 }


 void DAClusterizerInZ::splitAll(

              vector<vertex_t> & y

              )const{


   double epsilon=1e-3;      // split all single vertices by 10 um

   double zsep=2*epsilon;    // split vertices that are isolated by at least zsep (vertices that haven't collapsed)

   vector<vertex_t> y1;


   for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     if ( ( (k==y.begin())|| (k-1)->z < k->z - zsep) && (((k+1)==y.end()  )|| (k+1)->z > k->z + zsep)) {

       // isolated prototype, split

       vertex_t vnew;

       vnew.z  = k->z -epsilon;

       (*k).z  = k->z+epsilon;

       vnew.pk= 0.5* (*k).pk;

       (*k).pk= 0.5* (*k).pk;

       y1.push_back(vnew);

       y1.push_back(*k);


     }else if( y1.empty() || (y1.back().z < k->z -zsep)){

       y1.push_back(*k);

     }else{

       y1.back().z -=epsilon;

       k->z+=epsilon;

       y1.push_back(*k);

     }

   }// vertex loop


   y=y1;

 }


 DAClusterizerInZ::DAClusterizerInZ(const edm::ParameterSet& conf)

 {

   // some defaults to avoid uninitialized variables

   verbose_= conf.getUntrackedParameter<bool>("verbose", false);

   useTc_=true;

   betamax_=0.1;

   betastop_  =1.0;

   coolingFactor_=0.8;

   maxIterations_=100;

   vertexSize_=0.05;  // 0.5 mm

   dzCutOff_=4.0;   // Adaptive Fitter uses 3.0 but that appears to be a bit tight here sometimes


   // configure


   double Tmin = conf.getParameter<double>("Tmin");

   vertexSize_ = conf.getParameter<double>("vertexSize");

   coolingFactor_ = conf.getParameter<double>("coolingFactor");

   d0CutOff_  =  conf.getParameter<double>("d0CutOff");

   dzCutOff_  =  conf.getParameter<double>("dzCutOff");

   maxIterations_=100;

   if (Tmin==0){

     cout << "DAClusterizerInZ: invalid Tmin" << Tmin << "  reset do default " << 1./betamax_ << endl;

   }else{

     betamax_ = 1./Tmin;

   }


   // for testing, negative cooling factor: revert to old splitting scheme

   if(coolingFactor_<0){

     coolingFactor_=-coolingFactor_; useTc_=false;

   }


 }


 void DAClusterizerInZ::dump(const double beta, const vector<vertex_t> & y, const vector<track_t> & tks0, int verbosity)const{


   // copy and sort for nicer printout

   vector<track_t> tks;

   for(vector<track_t>::const_iterator t=tks0.begin(); t!=tks0.end(); t++){tks.push_back(*t); }

   stable_sort(tks.begin(), tks.end(), recTrackLessZ1);


   cout << "-----DAClusterizerInZ::dump ----" << endl;

   cout << "beta=" << beta << "   betamax= " << betamax_ << endl;

   cout << "                                                               z= ";

   cout.precision(4);

   for(vector<vertex_t>::const_iterator k=y.begin(); k!=y.end(); k++){

     cout  <<  setw(8) << fixed << k->z ;

   }

   cout << endl << "T=" << setw(15) << 1./beta <<"                                             Tc= ";

   for(vector<vertex_t>::const_iterator k=y.begin(); k!=y.end(); k++){

     cout  <<  setw(8) << fixed << k->Tc ;

   }


   cout << endl << "                                                               pk=";

   double sumpk=0;

   for(vector<vertex_t>::const_iterator k=y.begin(); k!=y.end(); k++){

     cout <<  setw(8) <<  setprecision(3) <<  fixed << k->pk;

     sumpk+=k->pk;

   }

   cout  << endl;


   if(verbosity>0){

     double E=0, F=0;

     cout << endl;

     cout << "----       z +/- dz                ip +/-dip       pt    phi  eta    weights  ----" << endl;

     cout.precision(4);

     for(unsigned int i=0; i<tks.size(); i++){

       if (tks[i].Z>0){  F-=log(tks[i].Z)/beta;}

       double tz= tks[i].z;

       cout <<  setw (3)<< i << ")" <<  setw (8) << fixed << setprecision(4)<<  tz << " +/-" <<  setw (6)<< sqrt(tks[i].dz2);


       if(tks[i].tt->track().quality(reco::TrackBase::highPurity)){ cout << " *";}else{cout <<"  ";}

       if(tks[i].tt->track().hitPattern().hasValidHitInFirstPixelBarrel()){ cout <<"+"; }else{ cout << "-"; }

       cout << setw(1) << tks[i].tt->track().hitPattern().pixelBarrelLayersWithMeasurement(); // see DataFormats/TrackReco/interface/HitPattern.h

       cout << setw(1) << tks[i].tt->track().hitPattern().pixelEndcapLayersWithMeasurement();

       cout << setw(1) << hex << tks[i].tt->track().hitPattern().trackerLayersWithMeasurement() -

           tks[i].tt->track().hitPattern().pixelLayersWithMeasurement() << dec;

       cout << "=" << setw(1) << hex << tks[i].tt->track().hitPattern().numberOfHits(reco::HitPattern::MISSING_OUTER_HITS) << dec;


       Measurement1D IP=tks[i].tt->stateAtBeamLine().transverseImpactParameter();

       cout << setw (8) << IP.value() << "+/-" << setw (6) << IP.error();

       cout << " " << setw(6) << setprecision(2)  << tks[i].tt->track().pt()*tks[i].tt->track().charge();

       cout << " " << setw(5) << setprecision(2) << tks[i].tt->track().phi()

        << " "  << setw(5)  << setprecision(2)   << tks[i].tt->track().eta() ;


       double sump=0.;

       for(vector<vertex_t>::const_iterator k=y.begin(); k!=y.end(); k++){

     if((tks[i].pi>0)&&(tks[i].Z>0)){

       //double p=pik(beta,tks[i],*k);

       double p=k->pk * exp(-beta*Eik(tks[i],*k)) / tks[i].Z;

       if( p > 0.0001){

         cout <<  setw (8) <<  setprecision(3) << p;

       }else{

         cout << "    .   ";

       }

       E+=p*Eik(tks[i],*k);

       sump+=p;

     }else{

         cout << "        ";

     }

       }

       cout << endl;

     }

     cout << endl << "T=" << 1/beta  << " E=" << E << " n="<< y.size() << "  F= " << F <<  endl <<  "----------" << endl;

   }

 }


 vector< TransientVertex >

 DAClusterizerInZ::vertices(const vector<reco::TransientTrack> & tracks, const int verbosity)

 const

 {


   vector<track_t> tks=fill(tracks);

   unsigned int nt=tracks.size();

   double rho0=0.0;  // start with no outlier rejection


   vector< TransientVertex > clusters;

   if (tks.empty()) return clusters;


   vector<vertex_t> y; // the vertex prototypes


   // initialize:single vertex at infinite temperature

   vertex_t vstart;

   vstart.z=0.;

   vstart.pk=1.;

   y.push_back(vstart);

   int niter=0;      // number of iterations


   // estimate first critical temperature

   double beta=beta0(betamax_, tks, y);

   niter=0; while((update(beta, tks,y)>1.e-6)  && (niter++ < maxIterations_)){ }


  // annealing loop, stop when T<Tmin  (i.e. beta>1/Tmin)

   while(beta<betamax_){


     if(useTc_){

       update(beta, tks,y);

       while(merge(y,beta)){update(beta, tks,y);}

       split(beta, tks,y, 1.);

       beta=beta/coolingFactor_;

     }else{

       beta=beta/coolingFactor_;

       splitAll(y);

     }


    // make sure we are not too far from equilibrium before cooling further

    niter=0; while((update(beta, tks,y)>1.e-6)  && (niter++ < maxIterations_)){ }


   }


   if(useTc_){

     // last round of splitting, make sure no critical clusters are left

     update(beta, tks,y);

     while(merge(y,beta)){update(beta, tks,y);}

     unsigned int ntry=0;

     while( split(beta, tks,y,1.) && (ntry++<10) ){

       niter=0;

       while((update(beta, tks,y)>1.e-6)  && (niter++ < maxIterations_)){}

       merge(y,beta);

       update(beta, tks,y);

     }

   }else{

     // merge collapsed clusters

     while(merge(y,beta)){update(beta, tks,y);}

     if(verbose_ ){ cout << "dump after 1st merging " << endl;  dump(beta,y,tks,2);}

   }


   // switch on outlier rejection

   rho0=1./nt; for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){ k->pk =1.; }  // democratic

   niter=0; while((update(beta, tks,y,rho0) > 1.e-8)  && (niter++ < maxIterations_)){  }

   if(verbose_  ){ cout << "rho0=" << rho0 <<   " niter=" << niter <<  endl; dump(beta,y,tks,2);}


   // merge again  (some cluster split by outliers collapse here)

   while(merge(y,tks.size())){}

   if(verbose_  ){ cout << "dump after 2nd merging " << endl;  dump(beta,y,tks,2);}


   // continue from freeze-out to Tstop (=1) without splitting, eliminate insignificant vertices

   while(beta<=betastop_){

     while(purge(y,tks,rho0, beta)){

       niter=0; while((update(beta, tks,y,rho0) > 1.e-6)  && (niter++ < maxIterations_)){  }

     }

     beta/=coolingFactor_;

     niter=0; while((update(beta, tks,y,rho0) > 1.e-6)  && (niter++ < maxIterations_)){  }

   }


 //   // new, one last round of cleaning at T=Tstop

 //   while(purge(y,tks,rho0, beta)){

 //     niter=0; while((update(beta, tks,y,rho0) > 1.e-6)  && (niter++ < maxIterations_)){  }

 //   }


   if(verbose_){

    cout << "Final result, rho0=" << rho0 << endl;

    dump(beta,y,tks,2);

   }


   // select significant tracks and use a TransientVertex as a container

   GlobalError dummyError;


   // ensure correct normalization of probabilities, should make double assginment reasonably impossible

   for(unsigned int i=0; i<nt; i++){

     tks[i].Z=rho0*exp(-beta*dzCutOff_*dzCutOff_);

     for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

       tks[i].Z+=k->pk * exp(-beta*Eik(tks[i],*k));

     }

   }


   for(vector<vertex_t>::iterator k=y.begin(); k!=y.end(); k++){

     GlobalPoint pos(0, 0, k->z);

     vector< reco::TransientTrack > vertexTracks;

     for(unsigned int i=0; i<nt; i++){

       if(tks[i].Z>0){

     double p=k->pk * exp(-beta*Eik(tks[i],*k)) / tks[i].Z;

     if( (tks[i].pi>0) && ( p > 0.5 ) ){ vertexTracks.push_back(*(tks[i].tt)); tks[i].Z=0; } // setting Z=0 excludes double assignment

       }

     }

     TransientVertex v(pos, dummyError, vertexTracks, 5);

     clusters.push_back(v);

   }


   return clusters;


 }


 vector< vector<reco::TransientTrack> >

 DAClusterizerInZ::clusterize(const vector<reco::TransientTrack> & tracks)

   const

 {

   if(verbose_) {

     cout << "###################################################" << endl;

     cout << "# DAClusterizerInZ::clusterize   nt="<<tracks.size() << endl;

     cout << "###################################################" << endl;

   }


   vector< vector<reco::TransientTrack> > clusters;

   vector< TransientVertex > pv=vertices(tracks);


   if(verbose_){ cout << "# DAClusterizerInZ::clusterize   pv.size="<<pv.size() << endl;  }

   if (pv.size()==0){ return clusters;}


   // fill into clusters and merge

   vector< reco::TransientTrack>  aCluster=pv.begin()->originalTracks();


   for(vector<TransientVertex>::iterator k=pv.begin()+1; k!=pv.end(); k++){

     if ( fabs(k->position().z() - (k-1)->position().z()) > (2*vertexSize_) ){

       // close a cluster

       clusters.push_back(aCluster);

       aCluster.clear();

     }

     for(unsigned int i=0; i<k->originalTracks().size(); i++){ aCluster.push_back( k->originalTracks().at(i)); }


   }

   clusters.push_back(aCluster);


   return clusters;


 }


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Definition: DAClusterizerInZ.h:30

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Definition: DAClusterizerInZ.cc:347

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Definition: DAClusterizerInZ.h:35

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Definition: BeamSpot.h:88

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Definition: DAClusterizerInZ.h:29

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Definition: Measurement1D.h:28

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Definition: MatrixUtil.py:172

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Definition: relval_steps.py:1709

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