trkf::BezierTrackerAlgorithm Class Reference

#include "BezierTrackerAlgorithm.h"

Public Member Functions
	BezierTrackerAlgorithm (fhicl::ParameterSet const &pset)
virtual	~BezierTrackerAlgorithm ()
void	FilterOverlapTracks (std::vector< trkf::BezierTrack > &BTracks, std::vector< art::PtrVector< recob::Hit > > &HitVecs, std::vector< std::vector< std::pair< int, int > > > &ClustersUsed)
void	MakeDirectJoins (std::vector< trkf::BezierTrack > &BTracks, std::vector< art::PtrVector< recob::Hit > > &HitVecs, std::vector< std::vector< std::pair< int, int > > > &ClustersUsed)
void	AddPtrVectors (art::PtrVector< recob::Hit > &Receiever, art::PtrVector< recob::Hit > const &ToAdd)
trkf::SeedFinderAlgorithm *	GetSeedFinderAlgorithm ()
void	MakeVertexJoins (std::vector< trkf::BezierTrack > &BTracks, std::vector< recob::Vertex > &Vertices, std::vector< std::vector< int > > &Mapping)
void	MakeOverlapJoins (std::vector< trkf::BezierTrack > &BTracks, std::vector< art::PtrVector< recob::Hit > > &HitVecs, std::vector< std::vector< std::pair< int, int > > > &ClustersUsed)
std::vector< trkf::BezierTrack >	MakeTracks (std::vector< std::vector< art::PtrVector< recob::Hit > > > &SortedHits, std::vector< art::PtrVector< recob::Hit > > &HitAssocs, std::vector< std::vector< std::pair< int, int > > > &ClustersUsed)
void	GetTracksForCombo (std::vector< recob::Seed > &Seeds, art::PtrVector< recob::Hit > &UHits, art::PtrVector< recob::Hit > &VHits, art::PtrVector< recob::Hit > &WHits)
std::vector< std::vector< recob::Seed > >	OrganizeSeedsIntoTracks (std::vector< recob::Seed > &AllSeeds, std::vector< art::PtrVector< recob::Hit > * > &AllHits, std::vector< art::PtrVector< recob::Hit > > &WhichHitsPerSeed, std::vector< std::vector< std::vector< int > > * > &OrgHits, std::vector< std::vector< std::vector< int > > > &WhichHitsPerTrack)
void	GetSeedDirProjected (recob::Seed const &TheSeed, std::vector< double > &WireCoord, std::vector< double > &TimeCoord)
bool	EvaluateOccupancy (recob::Seed &Seed1, recob::Seed &Seed2, double dThresh, std::vector< art::PtrVector< recob::Hit > * > &AllHits, std::vector< std::vector< std::vector< int > > * > &OrgHits, std::vector< uint32_t > &LowChan, std::vector< uint32_t > &HighChan, std::vector< std::vector< int > > &HitStatus, std::vector< std::vector< int > > &TheseHits)
void	SortTracksByLength (std::vector< trkf::BezierTrack > &BTracks, std::vector< art::PtrVector< recob::Hit > > &HitVecs, std::vector< std::vector< std::pair< int, int > > > &ClustersUsed)
void	CalculateGeometricalElements ()
trkf::BezierTrack	JoinTracks (trkf::BezierTrack &BT1, trkf::BezierTrack &BT2)
void	reconfigure (fhicl::ParameterSet const &pset)

Private Member Functions
void	GetImpact (TVector3 t1pt, TVector3 t1dir, TVector3 t2pt, TVector3 t2dir, double &ImpactParam, double &Dist1, double &Dist2)

Private Attributes
double	fOverlapCut
double	fDirectJoinDistance
double	fTrackJoinAngle
double	fOccupancyThresh
double	fTrackResolution
double	fVertexImpactThreshold
double	fVertexExtrapDistance
std::vector< double >	fPitches
std::vector< double >	fPlaneTimeOffsets
std::vector< TVector3 >	fPitchDir
std::vector< TVector3 >	fWireDir
std::vector< double >	fWireZeroOffset
TVector3	fXDir
TVector3	fYDir
TVector3	fZDir
SeedFinderAlgorithm *	fTheSeedFinder

Detailed Description

Definition at line 34 of file BezierTrackerAlgorithm.h.

Constructor & Destructor Documentation

trkf::BezierTrackerAlgorithm::BezierTrackerAlgorithm ( fhicl::ParameterSet const &  pset )

explicit

Definition at line 33 of file BezierTrackerAlgorithm.cxx.

References reconfigure().

  {
    
    reconfigure(pset);
  }

trkf::BezierTrackerAlgorithm::~BezierTrackerAlgorithm ( )

virtual

Definition at line 41 of file BezierTrackerAlgorithm.cxx.

  {
  }

Member Function Documentation

void trkf::BezierTrackerAlgorithm::AddPtrVectors	(	art::PtrVector< recob::Hit > &	Receiever,
		art::PtrVector< recob::Hit > const &	ToAdd
	)

Definition at line 533 of file BezierTrackerAlgorithm.cxx.

References art::PtrVector< T >::at(), art::PtrVector< T >::push_back(), and art::PtrVector< T >::size().

Referenced by MakeDirectJoins(), and MakeOverlapJoins().

  {
    for(size_t i=0; i!=ToAdd.size(); ++i)
      {
        Receiver.push_back(ToAdd.at(i));
      }
  } 

void trkf::BezierTrackerAlgorithm::CalculateGeometricalElements

(

)

Definition at line 1050 of file BezierTrackerAlgorithm.cxx.

References fPitchDir, fPitches, fPlaneTimeOffsets, fWireDir, fWireZeroOffset, fXDir, fYDir, fZDir, detinfo::DetectorProperties::GetXTicksOffset(), geo::kU, geo::kV, geo::kW, n, geo::GeometryCore::WireEndPoints(), and geo::GeometryCore::WirePitch().

Referenced by reconfigure().

  {
    art::ServiceHandle<geo::Geometry> geom;
    const detinfo::DetectorProperties* det = lar::providerFrom<detinfo::DetectorPropertiesService>();


    // Find pitch of each wireplane
    fPitches.resize(3);
    fPitches.at(0) = fabs(geom->WirePitch(geo::kU));
    fPitches.at(1) = fabs(geom->WirePitch(geo::kV));
    fPitches.at(2) = fabs(geom->WirePitch(geo::kW));

    fPlaneTimeOffsets.resize(3);
    for(size_t n=0; n!=3; ++n)
      fPlaneTimeOffsets.at(n) = det->GetXTicksOffset(n,0,0);
    
    // Setup basis vectors
    fXDir = TVector3(1,0,0);
    fYDir = TVector3(0,1,0);
    fZDir = TVector3(0,0,1);

    fWireDir.resize(3);
    fPitchDir.resize(3);
    fWireZeroOffset.resize(3);

    double xyzStart1[3], xyzStart2[3];
    double xyzEnd1[3], xyzEnd2[3];

    // Calculate wire coordinate systems
    for(size_t n=0; n!=3; ++n)
      {
        geom->WireEndPoints(0,0,n,0,xyzStart1,xyzEnd1);
        geom->WireEndPoints(0,0,n,1,xyzStart2,xyzEnd2);
        fWireDir[n] = TVector3(xyzEnd1[0] - xyzStart1[0],
                               xyzEnd1[1] - xyzStart1[1],
                               xyzEnd1[2] - xyzStart1[2]).Unit();
        fPitchDir[n] = fWireDir[n].Cross(fXDir).Unit();
        if(fPitchDir[n].Dot(TVector3(xyzEnd2[0] - xyzEnd1[0],
                                     xyzEnd2[1] - xyzEnd1[1],
                                     xyzEnd2[2] - xyzEnd1[2]))<0) fPitchDir[n] = -fPitchDir[n];

        fWireZeroOffset[n] =
          xyzEnd1[0]*fPitchDir[n][0] +
          xyzEnd1[1]*fPitchDir[n][1] +
          xyzEnd1[2]*fPitchDir[n][2];

      } 


  }

bool trkf::BezierTrackerAlgorithm::EvaluateOccupancy	(	recob::Seed &	Seed1,
		recob::Seed &	Seed2,
		double	dThresh,
		std::vector< art::PtrVector< recob::Hit > * > &	AllHits,
		std::vector< std::vector< std::vector< int > > * > &	OrgHits,
		std::vector< uint32_t > &	LowChan,
		std::vector< uint32_t > &	HighChan,
		std::vector< std::vector< int > > &	HitStatus,
		std::vector< std::vector< int > > &	TheseHits
	)

Definition at line 969 of file BezierTrackerAlgorithm.cxx.

References detinfo::DetectorProperties::ConvertTicksToX(), d, fOccupancyThresh, fPitchDir, fPitches, fWireDir, fWireZeroOffset, fXDir, trkf::BezierCurveHelper::GetBezierPoints(), recob::Seed::GetDistance(), n, recob::Hit::PeakTime(), geo::WireID::Wire, and recob::Hit::WireID().

Referenced by OrganizeSeedsIntoTracks().

  {
    const detinfo::DetectorProperties* det = lar::providerFrom<detinfo::DetectorPropertiesService>();
      
    int NSteps = 2 * Seed1.GetDistance(Seed2) / dThresh;
    if(NSteps<2) NSteps=2;
    BezierCurveHelper bhlp(NSteps);
  
    std::vector<TVector3> Pts = bhlp.GetBezierPoints(Seed2, Seed1, NSteps);
  

    for(size_t n=0; n!=3; ++n)
      {
        if((HighChan[n]-LowChan[n])<=2) continue;
        
        size_t EmptyChanLimit = int((1.-fOccupancyThresh)*(HighChan[n]-LowChan[n]-2));
        size_t NEmptyChannels=0;

        for(uint32_t iChan = LowChan[n]+1; iChan < (HighChan[n]-1); ++iChan)
              {
                bool GotThisChannel=false;
        
                for(size_t iH = 0; iH!=OrgHits[n]->at(iChan).size(); ++iH)
                  {
                    if(HitStatus[n][OrgHits[n]->at(iChan).at(iH)]==0)
                      {
                        art::Ptr<recob::Hit> ThisHit = AllHits[n]->at(OrgHits[n]->at(iChan)[iH]);
                
                        TVector3 WirePoint1 = ( fPitchDir[n]*(fWireZeroOffset[n] + fPitches[n] * ThisHit->WireID().Wire) )+ fXDir * det->ConvertTicksToX(ThisHit->PeakTime(), n, 0, 0);
                
                        for(size_t ipt=0; ipt!=Pts.size(); ++ipt)
                          {
                            float d = ((WirePoint1-Pts.at(ipt))-fWireDir[n]*((WirePoint1-Pts.at(ipt)).Dot(fWireDir[n]))).Mag();
                            if(d < dThresh) 
                              {
                                TheseHits[n].push_back(OrgHits[n]->at(iChan).at(iH));
                                GotThisChannel=true;
                                break;
                              }
                          }
                      }
                  }
                if(!GotThisChannel) NEmptyChannels++;
                if(NEmptyChannels > EmptyChanLimit) return false; 
              }
      }
     return true;
    
  }

void trkf::BezierTrackerAlgorithm::FilterOverlapTracks	(	std::vector< trkf::BezierTrack > &	BTracks,
		std::vector< art::PtrVector< recob::Hit > > &	HitVecs,
		std::vector< std::vector< std::pair< int, int > > > &	ClustersUsed
	)

Definition at line 276 of file BezierTrackerAlgorithm.cxx.

References fTrackResolution, t1, and t2.

  {
    
    std::map<int, bool> ToErase;

    std::vector<double> Lengths;
    std::vector<TVector3> End1Points, End2Points;

   
    for(size_t i=0; i!=BTracks.size(); ++i)
      {
        End1Points.push_back(BTracks.at(i).GetTrackPointV(0));
        End2Points.push_back(BTracks.at(i).GetTrackPointV(1));
        Lengths.push_back(BTracks.at(i).GetLength());
      }
    
    for(size_t t1=0; t1!=BTracks.size(); ++t1)
      for(size_t t2=0; t2!=BTracks.size(); ++t2)
        {
          if(t1!=t2)
            {
              if(Lengths.at(t1)>Lengths.at(t2))
                {
                  double s1,d1,s2,d2;
                  BTracks.at(t1).GetClosestApproach(End1Points.at(t2),s1,d1);
                  BTracks.at(t1).GetClosestApproach(End2Points.at(t2),s2,d2);
                  if((s1>0.01)&&(s1<0.99)&&(s2>0.01)&&(s2<0.99)&&
                     (d1<fTrackResolution)&&(d2<fTrackResolution))
                    {
                      // Track t2 is a fraud - toss it
                      ToErase[t2]=true;
                    }
                }
              else
                {
                  double s1,d1,s2,d2;
                  BTracks.at(t2).GetClosestApproach(End1Points.at(t1),s1,d1);
                  BTracks.at(t2).GetClosestApproach(End2Points.at(t1),s2,d2);
                  if((s1>0.01)&&(s1<0.99)&&(s2>0.01)&&(s2<0.99)&&
                     (d1<fTrackResolution)&&(d2<fTrackResolution))
                    {
                      // Track t2 is a fraud - toss it
                      ToErase[t1]=true;
                    }
                }
            }
        }
    
    // Remove the tracks we marked for deletion
     for(int i=BTracks.size()-1; i >= 0; --i)
      {
        if(ToErase[i])
          {
            BTracks.erase(BTracks.begin()+i);
            HitVecs.erase(HitVecs.begin()+i);
            ClustersUsed.erase(ClustersUsed.begin()+i);
          }
      }
  }

void trkf::BezierTrackerAlgorithm::GetImpact ( TVector3  t1pt, TVector3  t1dir, TVector3  t2pt, TVector3  t2dir, double &  ImpactParam, double &  Dist1, double &  Dist2  )

private

Definition at line 1332 of file BezierTrackerAlgorithm.cxx.

Referenced by MakeVertexJoins().

  {
    double lambda1 = ((t2pt-t1pt).Cross(t2dir)).Dot(t1dir.Cross(t2dir)) / (t1dir.Cross(t2dir)).Mag2();
    double lambda2 = ((t1pt-t2pt).Cross(t1dir)).Dot(t2dir.Cross(t1dir)) / (t2dir.Cross(t1dir)).Mag2();
    TVector3 c = t1pt + t1dir*lambda1 - t2pt - t2dir*lambda2;
    
    ImpactParam = c.Mag();
    Dist1 = lambda1 * t1dir.Mag();
    Dist2 = lambda2 * t2dir.Mag();
  }

void trkf::BezierTrackerAlgorithm::GetSeedDirProjected	(	recob::Seed const &	TheSeed,
		std::vector< double > &	WireCoord,
		std::vector< double > &	TimeCoord
	)

Definition at line 1022 of file BezierTrackerAlgorithm.cxx.

References detinfo::DetectorProperties::ConvertXToTicks(), dir, fPitchDir, fPitches, fXDir, recob::Seed::GetDirection(), and n.

Referenced by OrganizeSeedsIntoTracks().

  {
    const detinfo::DetectorProperties* det = lar::providerFrom<detinfo::DetectorPropertiesService>();
    
    WireCoord.clear();
    WireCoord.resize(3);
    TimeCoord.clear();
    TimeCoord.resize(3);
    
    double dir[3], err[3];
    
    TheSeed.GetDirection(dir,err);
    TVector3 DirVec(dir[0],dir[1],dir[2]);
    
    for(size_t n=0; n!=3; ++n)
      {
        WireCoord[n] = DirVec.Dot(fPitchDir[n]) / fPitches[n];
        TimeCoord[n] = det->ConvertXToTicks(DirVec.Dot(fXDir),n,0,0);
      }

  }

trkf::SeedFinderAlgorithm* trkf::BezierTrackerAlgorithm::GetSeedFinderAlgorithm ( )

inline

Definition at line 53 of file BezierTrackerAlgorithm.h.

References lar::dump::vector().

Referenced by MakeTracks().

{ return fTheSeedFinder;}

void trkf::BezierTrackerAlgorithm::GetTracksForCombo	(	std::vector< recob::Seed > &	Seeds,
		art::PtrVector< recob::Hit > &	UHits,
		art::PtrVector< recob::Hit > &	VHits,
		art::PtrVector< recob::Hit > &	WHits
	)

trkf::BezierTrack trkf::BezierTrackerAlgorithm::JoinTracks	(	trkf::BezierTrack &	BT1,
		trkf::BezierTrack &	BT2
	)

Definition at line 519 of file BezierTrackerAlgorithm.cxx.

References trkf::BezierTrack::GetSeedVector().

Referenced by MakeDirectJoins(), and MakeOverlapJoins().

  {

    std::vector<recob::Seed> SeedCol1 = BT1.GetSeedVector();
    std::vector<recob::Seed> SeedCol2 = BT2.GetSeedVector();
        
    SeedCol1.insert(SeedCol1.end(),SeedCol2.begin(),SeedCol2.end());
   
    return trkf::BezierTrack(SeedCol1);
  }

void trkf::BezierTrackerAlgorithm::MakeDirectJoins	(	std::vector< trkf::BezierTrack > &	BTracks,
		std::vector< art::PtrVector< recob::Hit > > &	HitVecs,
		std::vector< std::vector< std::pair< int, int > > > &	ClustersUsed
	)

Definition at line 448 of file BezierTrackerAlgorithm.cxx.

References AddPtrVectors(), fDirectJoinDistance, fTrackJoinAngle, fTrackResolution, JoinTracks(), t1, and t2.

  {
    
    int LoopStatus=1;

    // 0 : Quit loop
    // 1 : Keep looping
    // 2 : Deleted a seed : start again from the beginning
    
    while(LoopStatus>0)
      {
        LoopStatus = 0;
        for(size_t t1=0; t1!=BTracks.size(); ++t1)
          {
            for(size_t t2=0; t2!=BTracks.size(); ++t2)
              {
                if(t1==t2) continue;
                
                TVector3 End1Dir_i = BTracks.at(t1).GetTrackDirectionV(1.0).Unit();
                TVector3 End0Dir_j = BTracks.at(t2).GetTrackDirectionV(0.0).Unit();

                TVector3 End0Point_i = BTracks.at(t1).GetTrackPointV(0.0);
                TVector3 End0Point_j = BTracks.at(t2).GetTrackPointV(0.0);
                TVector3 End1Point_i = BTracks.at(t1).GetTrackPointV(1.0);
                TVector3 End1Point_j = BTracks.at(t2).GetTrackPointV(1.0);
                    

                
                double JoinAngle   = End1Dir_i.Angle(End0Dir_j);
                double JoinSign    = (End0Point_j-End1Point_i).Dot(End1Dir_i);
                double Colinearity = ((End0Point_j-End1Point_i) - End1Dir_i*((End0Point_j-End1Point_i).Dot(End1Dir_i))).Mag();
                

                if((JoinAngle<fTrackJoinAngle)&&(JoinSign>0)&&(Colinearity<fTrackResolution))
                  {
                    double EndSep10 = (End1Point_i-End0Point_j).Mag();
                    double EndSep01 = (End0Point_i-End1Point_j).Mag();
                    double EndSep11 = (End1Point_i-End1Point_j).Mag();
                    double EndSep00 = (End0Point_i-End0Point_j).Mag();
                    

                    if( (EndSep10   < fDirectJoinDistance)
                        &&(EndSep10 < EndSep11)
                        &&(EndSep10 < EndSep00)
                        &&(EndSep10 < EndSep01) )
                      {
                        
                        BTracks.at(t1) = JoinTracks(BTracks.at(t1), BTracks.at(t2));
                        BTracks.erase(BTracks.begin()+t2);
                        
                        // Add the pointervectors into 1 and remove 2
                        AddPtrVectors(HitVecs.at(t1), HitVecs.at(t2));
                        ClustersUsed.at(t1).insert(ClustersUsed.at(t1).begin(),
                                                   ClustersUsed.at(t2).begin(),
                                                   ClustersUsed.at(t2).end());
                
                        HitVecs.erase(HitVecs.begin()+t2);
                        ClustersUsed.erase(ClustersUsed.begin()+t2);
                        LoopStatus=3;
                      }
                  }
                if(LoopStatus==3) break;
              }
            if(LoopStatus==3) break;
          }
      }
  }

void trkf::BezierTrackerAlgorithm::MakeOverlapJoins	(	std::vector< trkf::BezierTrack > &	BTracks,
		std::vector< art::PtrVector< recob::Hit > > &	HitVecs,
		std::vector< std::vector< std::pair< int, int > > > &	ClustersUsed
	)

Definition at line 340 of file BezierTrackerAlgorithm.cxx.

References AddPtrVectors(), fTrackResolution, JoinTracks(), t1, and t2.

  {
    
    std::vector<double> Lengths;
    std::vector<TVector3> End1Directions, End1Points, End2Directions, End2Points;
    for(size_t i=0; i!=BTracks.size(); ++i)
      {
        Lengths.push_back(BTracks.at(i).GetLength());
        End1Points.push_back(BTracks.at(i).GetTrackPointV(0));
        End2Points.push_back(BTracks.at(i).GetTrackPointV(1));
        End1Directions.push_back(BTracks.at(i).GetTrackDirectionV(0).Unit());
        End2Directions.push_back(BTracks.at(i).GetTrackDirectionV(1).Unit());
      }
    
    int LoopStatus=1;
    while(LoopStatus!=0)
      {
        LoopStatus=0;
        for(size_t t1=0; t1!=BTracks.size(); ++t1)
          {       
            for(size_t t2=0; t2!=BTracks.size(); ++t2)
              {
                if(t1!=t2)
                  {
                    double s12,d12;
                    double s21,d21;
                    BTracks.at(t1).GetClosestApproach(End1Points.at(t2),s12,d12);
                    BTracks.at(t2).GetClosestApproach(End2Points.at(t1),s21,d21);
                                                    
                    if((s12>0.0001)&&(s12<0.999)
                       &&(s21>0.0001)&&(s21<0.999)
                       &&(d12<fTrackResolution)
                       &&(d21<fTrackResolution))
                      {
                        // In this situation we want to join track 1 onto the end of track 2
                        trkf::BezierTrack Part1 = BTracks.at(t1).GetPartialTrack(0,s21);
                        trkf::BezierTrack Part2 = BTracks.at(t2).GetPartialTrack(s12,1);
                        BTracks.at(t1) = JoinTracks(Part1, Part2);
                        BTracks.erase(BTracks.begin()+t2);
                        
                        // Add the pointervectors into 1 and remove 2
                        AddPtrVectors(HitVecs.at(t1), HitVecs.at(t2));
                        ClustersUsed.at(t1).insert(ClustersUsed.at(t1).begin(),
                                                   ClustersUsed.at(t2).begin(),
                                                   ClustersUsed.at(t2).end());
                       
                        HitVecs.erase(HitVecs.begin()+t2);
                        ClustersUsed.erase(ClustersUsed.begin()+t2);
                        
                        LoopStatus=3;
                      }
                  }
                if(LoopStatus==3) break;
              }
            if(LoopStatus==3) break;
          }
      }   
  }

std::vector< trkf::BezierTrack > trkf::BezierTrackerAlgorithm::MakeTracks	(	std::vector< std::vector< art::PtrVector< recob::Hit > > > &	SortedHits,
		std::vector< art::PtrVector< recob::Hit > > &	HitAssocs,
		std::vector< std::vector< std::pair< int, int > > > &	ClustersUsed
	)

Definition at line 71 of file BezierTrackerAlgorithm.cxx.

References fPitches, fPlaneTimeOffsets, fWireZeroOffset, GetSeedFinderAlgorithm(), trkf::SeedFinderAlgorithm::GetSeedsFromUnSortedHits(), trkf::SeedFinderAlgorithm::GetSpacePointAlg(), geo::GeometryCore::IntersectionPoint(), geo::kU, geo::kV, geo::kW, max, trkf::SpacePointAlg::maxDT(), min, geo::GeometryCore::Nchannels(), OrganizeSeedsIntoTracks(), art::PtrVector< T >::push_back(), y, and z.

  {
    
    std::vector<trkf::BezierTrack> ReturnVector;

    size_t UEntries = SortedHits[0].size();
    size_t VEntries = SortedHits[1].size();
    size_t WEntries = SortedHits[2].size();

    // Get seeds from the hit collection    

    std::vector< std::vector< std::vector<int> > > OrgHitsU(UEntries);
    std::vector< std::vector< std::vector<int> > > OrgHitsV(VEntries);
    std::vector< std::vector< std::vector<int> > > OrgHitsW(WEntries);


    art::ServiceHandle<geo::Geometry> geo;
    size_t NChannels = geo->Nchannels();
    
    std::vector<double> MinUTime(UEntries,10000);
    std::vector<double> MaxUTime(UEntries,0);
    std::vector<double> MinVTime(VEntries,10000);
    std::vector<double> MaxVTime(VEntries,0);
    std::vector<double> MinWTime(WEntries,10000);
    std::vector<double> MaxWTime(WEntries,0);

    std::vector<int> MinUWire(UEntries,10000);
    std::vector<int> MaxUWire(UEntries,0);
    std::vector<int> MinVWire(VEntries,10000);
    std::vector<int> MaxVWire(VEntries,0);
    std::vector<int> MinWWire(WEntries,10000);
    std::vector<int> MaxWWire(WEntries,0);
    

    for(size_t nU=0; nU!=UEntries; ++nU)
      {
        OrgHitsU[nU].resize(NChannels);
        for(size_t iH=0; iH!=SortedHits[0][nU].size(); ++iH)
          {
            OrgHitsU[nU][SortedHits[0][nU][iH]->Channel()].push_back(iH);
            double Time = SortedHits[0][nU][iH]->PeakTime();
            if(Time<MinUTime[nU]) MinUTime[nU]=Time;
            if(Time>MaxUTime[nU]) MaxUTime[nU]=Time;
            int    Wire = SortedHits[0][nU][iH]->WireID().Wire;
            if(Wire<MinUWire[nU]) MinUWire[nU]=Wire;
            if(Wire>MaxUWire[nU]) MaxUWire[nU]=Wire;
          
          }
        MaxUTime[nU] -= fPlaneTimeOffsets[0];
        MinUTime[nU] -= fPlaneTimeOffsets[0];
      }
    
    for(size_t nV=0; nV!=VEntries; ++nV)
      {
        OrgHitsV[nV].resize(NChannels);
        for(size_t iH=0; iH!=SortedHits[1][nV].size(); ++iH)
          {
            OrgHitsV[nV][SortedHits[1][nV][iH]->Channel()].push_back(iH);
            double Time = SortedHits[1][nV][iH]->PeakTime();
            if(Time<MinVTime[nV]) MinVTime[nV]=Time;
            if(Time>MaxVTime[nV]) MaxVTime[nV]=Time;
            int    Wire = SortedHits[1][nV][iH]->WireID().Wire;
            if(Wire<MinVWire[nV]) MinVWire[nV]=Wire;
            if(Wire>MaxVWire[nV]) MaxVWire[nV]=Wire;
          }
        MaxVTime[nV] -= fPlaneTimeOffsets[1];
        MinVTime[nV] -= fPlaneTimeOffsets[1];    
      }

   for(size_t nW=0; nW!=WEntries; ++nW)
     {
       OrgHitsW[nW].resize(NChannels);
       for(size_t iH=0; iH!=SortedHits[2][nW].size(); ++iH)
         {
           OrgHitsW[nW][SortedHits[2][nW][iH]->Channel()].push_back(iH);
           double Time = SortedHits[2][nW][iH]->PeakTime();
           if(Time<MinWTime[nW]) MinWTime[nW]=Time;
           if(Time>MaxWTime[nW]) MaxWTime[nW]=Time;
           int    Wire = SortedHits[2][nW][iH]->WireID().Wire;
           if(Wire<MinWWire[nW]) MinWWire[nW]=Wire;
           if(Wire>MaxWWire[nW]) MaxWWire[nW]=Wire;
         }
       MaxWTime[nW] -= fPlaneTimeOffsets[2];
       MinWTime[nW] -= fPlaneTimeOffsets[2];
     }
   
    for(size_t nU =0; nU != UEntries; ++nU)
      for(size_t nV =0; nV != VEntries; ++nV)
        for(size_t nW =0; nW != WEntries; ++nW)
          
          {
            // First check if there is some chance of overlap. If not, move on.

            // check time region            
            
            if(MaxUTime[nU] < MinWTime[nW] ) continue;
            if(MaxUTime[nU] < MinVTime[nV] ) continue;
            if(MaxVTime[nV] < MinUTime[nU] ) continue;
            if(MaxVTime[nV] < MinWTime[nW] ) continue;
            if(MaxWTime[nW] < MinUTime[nU] ) continue;
            if(MaxWTime[nW] < MinVTime[nV] ) continue;

            // We won't need to include hits outside this time range
            double SpacePointRes = GetSeedFinderAlgorithm()->GetSpacePointAlg()->maxDT();
            double MinTime = std::max(std::max(MinUTime[nU],MinVTime[nV]),MinWTime[nW])-SpacePointRes;
            double MaxTime = std::min(std::min(MaxUTime[nU],MaxVTime[nV]),MaxWTime[nW])+SpacePointRes;

            // check wire region
            double y=0,z=0;
            geo->IntersectionPoint(MaxUWire[nU],MaxVWire[nV],0,1,0,0,y,z);
            double MaxUVOnW = ( z - fWireZeroOffset[2] ) / fPitches[2];
            if(MaxUVOnW < MinWWire[nW]) continue;
            geo->IntersectionPoint(MinUWire[nU],MinVWire[nV],0,1,0,0,y,z);
            double MinUVOnW = ( z - fWireZeroOffset[2] ) / fPitches[2];
            if(MinUVOnW > MaxWWire[nW]) continue;
          
            
            
            art::PtrVector<recob::Hit> HitsFlat;
            
            double EffMinTime =  MinTime + fPlaneTimeOffsets[0];
            double EffMaxTime =  MaxTime + fPlaneTimeOffsets[0];

            for(size_t i=0; i!=SortedHits[0][nU].size(); ++i)
              if((SortedHits[0][nU][i]->PeakTimePlusRMS(+1.) > EffMinTime)
                 &&(SortedHits[0][nU][i]->PeakTimePlusRMS(-1.)<EffMaxTime))
                HitsFlat.push_back(SortedHits[0][nU][i]);

            EffMinTime =  MinTime + fPlaneTimeOffsets[1];
            EffMaxTime =  MaxTime + fPlaneTimeOffsets[1];

            for(size_t i=0; i!=SortedHits[1][nV].size(); ++i)
              if((SortedHits[1][nV][i]->PeakTimePlusRMS(+1.)>EffMinTime)
                 &&(SortedHits[1][nV][i]->PeakTimePlusRMS(-1.)<EffMaxTime))
                HitsFlat.push_back(SortedHits[1][nV][i]);
            
            EffMinTime =  MinTime + fPlaneTimeOffsets[2];
            EffMaxTime =  MaxTime + fPlaneTimeOffsets[2];

            for(size_t i=0; i!=SortedHits[2][nW].size(); ++i)
              if((SortedHits[2][nW][i]->PeakTimePlusRMS(+1.)>EffMinTime)
                 &&(SortedHits[2][nW][i]->PeakTimePlusRMS(-1.)<EffMaxTime))
                HitsFlat.push_back(SortedHits[2][nW][i]);
                 
            std::vector<art::PtrVector<recob::Hit> > HitsPerSeed;
            
            std::vector<recob::Seed> SeedsThisCombo = 
              GetSeedFinderAlgorithm()->GetSeedsFromUnSortedHits(HitsFlat, HitsPerSeed);
            
                   
            if(SeedsThisCombo.size()>0)
              {


                std::vector<art::PtrVector<recob::Hit>* > HitStruct(3);
                HitStruct[0] = & SortedHits[0].at(nU);
                HitStruct[1] = & SortedHits[1].at(nV);
                HitStruct[2] = & SortedHits[2].at(nW);
                
                std::vector<std::vector< std::vector<int> >* > OrgHits(3);
                OrgHits[0] = & OrgHitsU[nU];
                OrgHits[1] = & OrgHitsV[nV];
                OrgHits[2] = & OrgHitsW[nW];

                

                std::vector<std::vector<std::vector<int > > > HitsPerTrack;
        
                std::vector<std::vector<recob::Seed> > SeedsForTracks = OrganizeSeedsIntoTracks(SeedsThisCombo, HitStruct, HitsPerSeed, OrgHits, HitsPerTrack);
                for(size_t iTrack=0; iTrack!=SeedsForTracks.size(); ++iTrack)
                  {
                    std::vector<std::pair<int, int> > ClustersThisTrack;
                    ClustersThisTrack.push_back(std::pair<int,int>(0,nU));
                    ClustersThisTrack.push_back(std::pair<int,int>(1,nV));
                    ClustersThisTrack.push_back(std::pair<int,int>(2,nW));

                    ClustersUsed.push_back(ClustersThisTrack);
                    
                    ReturnVector.push_back(trkf::BezierTrack(SeedsForTracks.at(iTrack)));
                    // Fill up the hit vector
                    art::PtrVector<recob::Hit> HitsForThisTrack;
                    
                    for(size_t iH=0; iH!=HitsPerTrack.at(iTrack)[0].size(); ++iH)
                      HitsForThisTrack.push_back(SortedHits[geo::kU][nU][HitsPerTrack.at(iTrack)[0].at(iH)]);
                    
                    for(size_t iH=0; iH!=HitsPerTrack.at(iTrack)[1].size(); ++iH)
                      HitsForThisTrack.push_back(SortedHits[geo::kV][nV][HitsPerTrack.at(iTrack)[1].at(iH)]);
                    
                    for(size_t iH=0; iH!=HitsPerTrack.at(iTrack)[2].size(); ++iH)
                      HitsForThisTrack.push_back(SortedHits[geo::kW][nW][HitsPerTrack.at(iTrack)[2].at(iH)]);
                    
                    HitAssocs.push_back(HitsForThisTrack);
                    
                  }
                                
              }
            
          }
    
    return ReturnVector;
  }

void trkf::BezierTrackerAlgorithm::MakeVertexJoins	(	std::vector< trkf::BezierTrack > &	BTracks,
		std::vector< recob::Vertex > &	Vertices,
		std::vector< std::vector< int > > &	Mapping
	)

Definition at line 1103 of file BezierTrackerAlgorithm.cxx.

References fVertexExtrapDistance, fVertexImpactThreshold, GetImpact(), n, and pt.

  {
    
    std::vector<TVector3> TrackEnd1s;
    std::vector<TVector3> TrackEnd2s;
    std::vector<TVector3> TrackDir1s;
    std::vector<TVector3> TrackDir2s;


    for(size_t i=0; i!=BTracks.size(); ++i)
      {
        TrackEnd1s.push_back( BTracks.at(i).GetTrackPointV(0));
        TrackEnd2s.push_back( BTracks.at(i).GetTrackPointV(1));
        TrackDir1s.push_back( BTracks.at(i).GetTrackDirectionV(0));
        TrackDir2s.push_back( BTracks.at(i).GetTrackDirectionV(1));     
      }
 
    std::vector<std::map<int,int> >     TracksMeetAtPoints;    
    std::vector<std::vector<TVector3> >  MeetPoints;
     
    // The connection[i][j] gives impact parameters for track ends
    //  The sign tells us which end of track j 
    for(size_t i=0; i!=BTracks.size(); ++i)
      {
        for(size_t j=0; j!=BTracks.size(); ++j)
          {
            if(i!=j)
              {
                double impact, disti, distj;
                GetImpact(TrackEnd1s[i],TrackDir1s[i],TrackEnd1s[j],TrackDir1s[j], impact, disti, distj);

                if((impact < fVertexImpactThreshold)
                   && (fabs(disti) < fVertexExtrapDistance )
                   && (fabs(distj) < fVertexExtrapDistance )
                   && (disti < 0 )
                   && (distj < 0 ))
                  {
                    bool ThisTrackAlreadyMet =false;
                    TVector3 ExtrapPoint1 = TrackEnd1s[i] + TrackDir1s[j].Unit()*disti;
                    TVector3 ExtrapPoint2 = TrackEnd1s[j] + TrackDir1s[j].Unit()*distj;
                    
                    for(size_t pt=0; pt!=TracksMeetAtPoints.size(); ++pt)
                      {
                        if(TracksMeetAtPoints.at(pt)[i]==-1)
                          {
                            TracksMeetAtPoints.at(pt)[j]=-1;
                            MeetPoints.at(pt).push_back(ExtrapPoint1);
                            MeetPoints.at(pt).push_back(ExtrapPoint2);
                            ThisTrackAlreadyMet=true;
                            
                          }
                        else if(TracksMeetAtPoints.at(pt)[j]==-1)
                          {
                            TracksMeetAtPoints.at(pt)[i]=-1;
                            MeetPoints.at(pt).push_back(ExtrapPoint1);
                            MeetPoints.at(pt).push_back(ExtrapPoint2);
                            ThisTrackAlreadyMet=true;
                          }
                      }
                    if(!ThisTrackAlreadyMet)
                      {
                        size_t pt = TracksMeetAtPoints.size();
                        TracksMeetAtPoints.push_back(std::map<int,int>());
                        TracksMeetAtPoints.at(pt)[i]=-1;
                        TracksMeetAtPoints.at(pt)[j]=-1;
                        MeetPoints.push_back(std::vector<TVector3>());
                        MeetPoints.at(pt).push_back(ExtrapPoint1);
                        MeetPoints.at(pt).push_back(ExtrapPoint2);
                      }

                  }

                GetImpact(TrackEnd2s[i],TrackDir2s[i],TrackEnd2s[j],TrackDir2s[j], impact, disti, distj);
                if((impact < fVertexImpactThreshold)
                   && (fabs(disti) < fVertexExtrapDistance )
                   && (fabs(distj) < fVertexExtrapDistance )
                   && (disti > 0 )
                   && (distj > 0 ))
                  {
                    bool ThisTrackAlreadyMet =false;
                    TVector3 ExtrapPoint1 = TrackEnd1s[i] + TrackDir2s[j].Unit()*disti;
                    TVector3 ExtrapPoint2 = TrackEnd2s[j] + TrackDir2s[j].Unit()*distj;
                    
                    for(size_t pt=0; pt!=TracksMeetAtPoints.size(); ++pt)
                      {
                        if(TracksMeetAtPoints.at(pt)[i]==1)
                          {
                            TracksMeetAtPoints.at(pt)[j]=1;
                            MeetPoints.at(pt).push_back(ExtrapPoint1);
                            MeetPoints.at(pt).push_back(ExtrapPoint2);
                            ThisTrackAlreadyMet=true;
                            
                          }
                        else if(TracksMeetAtPoints.at(pt)[j]==1)
                          {
                            TracksMeetAtPoints.at(pt)[i]=1;
                            MeetPoints.at(pt).push_back(ExtrapPoint1);
                            MeetPoints.at(pt).push_back(ExtrapPoint2);
                            ThisTrackAlreadyMet=true;
                          }
                      }
                    if(!ThisTrackAlreadyMet)
                      {
                        size_t pt = TracksMeetAtPoints.size();
                        TracksMeetAtPoints.push_back(std::map<int,int>());
                        TracksMeetAtPoints.at(pt)[i]=1;
                        TracksMeetAtPoints.at(pt)[j]=1;
                        MeetPoints.push_back(std::vector<TVector3>());
                        MeetPoints.at(pt).push_back(ExtrapPoint1);
                        MeetPoints.at(pt).push_back(ExtrapPoint2);
                      }
                    
                    
                  }
                
                GetImpact(TrackEnd1s[i],TrackDir1s[i],TrackEnd2s[j],TrackDir2s[j], impact, disti, distj);
                if((impact < fVertexImpactThreshold)
                   && (fabs(disti) < fVertexExtrapDistance )
                   && (fabs(distj) < fVertexExtrapDistance )
                   && (disti < 0 )
                   && (distj > 0 ))
                  {
                    bool ThisTrackAlreadyMet =false;
                    TVector3 ExtrapPoint1 = TrackEnd1s[i] + TrackDir2s[j].Unit()*disti;
                    TVector3 ExtrapPoint2 = TrackEnd2s[j] + TrackDir2s[j].Unit()*distj;
                    
                    for(size_t pt=0; pt!=TracksMeetAtPoints.size(); ++pt)
                      {
                        if(TracksMeetAtPoints.at(pt)[i]==-1)
                          {
                            TracksMeetAtPoints.at(pt)[j]=1;
                            MeetPoints.at(pt).push_back(ExtrapPoint1);
                            MeetPoints.at(pt).push_back(ExtrapPoint2);
                            ThisTrackAlreadyMet=true;
                            
                          }
                        else if(TracksMeetAtPoints.at(pt)[j]==1)
                          {
                            TracksMeetAtPoints.at(pt)[i]=-1;
                            MeetPoints.at(pt).push_back(ExtrapPoint1);
                            MeetPoints.at(pt).push_back(ExtrapPoint2);
                            ThisTrackAlreadyMet=true;
                          }
                      }
                    if(!ThisTrackAlreadyMet)
                      {
                        size_t pt = TracksMeetAtPoints.size();
                        TracksMeetAtPoints.push_back(std::map<int,int>());
                        TracksMeetAtPoints.at(pt)[i]=-1;
                        TracksMeetAtPoints.at(pt)[j]=1;
                        MeetPoints.push_back(std::vector<TVector3>());
                        MeetPoints.at(pt).push_back(ExtrapPoint1);
                        MeetPoints.at(pt).push_back(ExtrapPoint2);
                      }
          
                                    
                  }
                
              }
          }
      }


    for(size_t pt=0; pt!=TracksMeetAtPoints.size(); ++pt)
      {
        std::vector<int> TracksThisVertex;
        mf::LogVerbatim("BezierTrackerAlgorithm")<<" Making track adjustments for vertex " <<pt<<std::endl;
        TVector3 FinalMeetPt(0,0,0);
        for(size_t i=0; i!=MeetPoints.at(pt).size(); ++i)
          {
            FinalMeetPt += MeetPoints.at(pt).at(i);
          } 
        FinalMeetPt *= (1./float(MeetPoints.at(pt).size()));
        
        for(size_t i=0; i!=BTracks.size(); ++i)
          {
            if(TracksMeetAtPoints.at(pt)[i]==1)
              {
                TracksThisVertex.push_back(i);
                TVector3 NewDirection = (FinalMeetPt - TrackEnd2s[i])*0.5;
                double NewPos[3];
                double NewDir[3];
                double Err[3];
                
                for(size_t n=0; n!=3; ++n)
                  {
                    NewPos[n]=FinalMeetPt[n]-NewDirection[n];
                    NewDir[n]=NewDirection[n];
                  }
                
                recob::Seed NewSeed(NewPos, NewDir, Err, Err);
                std::vector<recob::Seed> SeedCol = BTracks.at(i).GetSeedVector();
                SeedCol.at(SeedCol.size()-1) = NewSeed;
                BTracks.at(i) = trkf::BezierTrack(SeedCol);
              }
            else if(TracksMeetAtPoints.at(pt)[i]==-1)
              {
                TracksThisVertex.push_back(i);
                TVector3 NewDirection = -(FinalMeetPt - TrackEnd1s[i])*0.5;
                double NewPos[3];
                double NewDir[3];
                double Err[3];
                
                for(size_t n=0; n!=3; ++n)
                  {
                    NewPos[n]=FinalMeetPt[n] + NewDirection[n];
                    NewDir[n]=NewDirection[n];
                  }
                
                recob::Seed NewSeed(NewPos, NewDir, Err, Err);
                std::vector<recob::Seed> SeedCol = BTracks.at(i).GetSeedVector();
                SeedCol.at(0) = NewSeed;
                BTracks.at(i) = trkf::BezierTrack(SeedCol);
              }

            
          }
        Mapping.push_back(TracksThisVertex);
        double VtxPoint[3];
        for(size_t n=0; n!=3; ++n)
          VtxPoint[n]=FinalMeetPt[n];
        Vertices.push_back(recob::Vertex(VtxPoint, pt));
      }
    
  }

std::vector< std::vector< recob::Seed > > trkf::BezierTrackerAlgorithm::OrganizeSeedsIntoTracks	(	std::vector< recob::Seed > &	AllSeeds,
		std::vector< art::PtrVector< recob::Hit > * > &	AllHits,
		std::vector< art::PtrVector< recob::Hit > > &	WhichHitsPerSeed,
		std::vector< std::vector< std::vector< int > > * > &	OrgHits,
		std::vector< std::vector< std::vector< int > > > &	WhichHitsPerTrack
	)

Definition at line 545 of file BezierTrackerAlgorithm.cxx.

References EvaluateOccupancy(), fOverlapCut, fTrackJoinAngle, fTrackResolution, fZDir, GetSeedDirProjected(), geo::kU, geo::kV, geo::kW, max, min, n, and lar::dump::vector().

Referenced by MakeTracks().

  {
    mf::LogVerbatim("BezierTrackerAlgorithm")<<"Organizing seed collection into track collections ";

    std::vector<std::vector<uint32_t> > MaxSeedChanPerView(3);
    std::vector<std::vector<uint32_t> > MinSeedChanPerView(3);
    
    // This vector will keep track of which hits we are still allowed
    //  to use.  Key : 
    //   0 - hit available
    //   1 - hit taken by an extrapolated bezier curve
    //   2 - hit taken by a seed on the track

    std::vector<std::vector<int> > HitStatus(3);
    for(size_t n=0; n!=3; ++n) HitStatus.at(n).resize(AllHits[n]->size());


    // This map keeps track of the indices of the hits (in the AllHits vector)
    //  which go with each seed, in each view
    //   SeedToHitMap[per_view][per_seed][1_to_n_with_this_seed] = index 

    std::vector<std::vector<std::vector<int> > >  SeedToHitMap(3);
    
    // Fill Seed <--> Hit lookups
    for(size_t iSeed=0; iSeed!=AllSeeds.size(); ++iSeed)
      { 
        // first make sure we have at least one hit in each view.
        
        bool CompleteSet = false;
        std::vector<bool> AtLeastOneHitThisView(3,false);
        for(size_t iHit=0; iHit!=WhichHitsPerSeed.at(iSeed).size(); ++iHit)
          {
            if(!AtLeastOneHitThisView[WhichHitsPerSeed.at(iSeed).at(iHit)->View()])
              {
                AtLeastOneHitThisView[WhichHitsPerSeed.at(iSeed).at(iHit)->View()] = true;
                if(AtLeastOneHitThisView[0]&&AtLeastOneHitThisView[1]&&AtLeastOneHitThisView[2])
                  {
                    CompleteSet = true;
                    break;
                  }
              }
          }
        if(!CompleteSet)
          {
            // If we don't have at least one hit in each view from this 
            //  seed, we're not going to be able to use it.
            //  ditch it (and its corresponding hits) from the game.
            AllSeeds.erase(AllSeeds.begin() + iSeed);
            WhichHitsPerSeed.erase(WhichHitsPerSeed.begin() + iSeed);
            --iSeed;
            continue;
          }
        else
          {
            // if we didn't throw out that seed, push back a new entry in 
            //  the seed <-> hit map vector, and                    
            // Find the min and max channels for each seed
            for(size_t n=0; n!=3; ++n)
              {
                SeedToHitMap[n].push_back(std::vector<int>());
                MinSeedChanPerView[n].push_back(10000);
                MaxSeedChanPerView[n].push_back(0);
              }
            for(size_t iHit=0; iHit!=WhichHitsPerSeed.at(iSeed).size(); ++iHit)
              {
                uint32_t Channel = WhichHitsPerSeed.at(iSeed).at(iHit)->Channel();
                geo::View_t View = WhichHitsPerSeed.at(iSeed).at(iHit)->View();
                
                int ViewID=0;
                if(View==geo::kU)      ViewID=0; 
                else if(View==geo::kV) ViewID=1; 
                else if(View==geo::kW) ViewID=2;            
                
                double      eta     = 0.01;
                
                for(size_t iH=0; iH!=OrgHits[ViewID]->at(Channel).size();++iH)
                  {
                    double PeakTime1 = AllHits[ViewID]->at(OrgHits[ViewID]->at(Channel).at(iH))->PeakTime();
                    double PeakTime2 = WhichHitsPerSeed.at(iSeed).at(iHit)->PeakTime();
                    
                    if( fabs(PeakTime1-PeakTime2)<eta)
                      
                      SeedToHitMap[ViewID][iSeed].push_back(OrgHits[ViewID]->at(Channel).at(iH));
                  }
                
            
                if(Channel>MaxSeedChanPerView[ViewID][iSeed]) MaxSeedChanPerView[ViewID][iSeed] = Channel;
                if(Channel<MinSeedChanPerView[ViewID][iSeed]) MinSeedChanPerView[ViewID][iSeed] = Channel;
                
              }
          }
      }
    
    // Now we've set up the book keeping, we get into the real
    //  work of track finding.

    // This will store our proposed track vectors
    std::vector<std::vector<recob::Seed > > OrganizedByTrack;
     
    TVector3 AverageDir;

    std::vector<TVector3> VSeedDirs;
    std::vector<TVector3> VSeedPoss;
    std::vector<std::vector<int> >       SeedSDirs;
    std::vector<std::vector<uint32_t> >  SeedHighSChans;
    std::vector<std::vector<uint32_t> >  SeedLowSChans;
    
      

    for(size_t i=0; i!=AllSeeds.size(); ++i)
      {
        double SeedDir[3], SeedPos[3], Err[3];

        AllSeeds.at(i).GetDirection(SeedDir,Err);
        AllSeeds.at(i).GetPoint(SeedPos,Err);
        TVector3 VSeedDir = TVector3(SeedDir[0],SeedDir[1],SeedDir[2]);
        VSeedDirs.push_back(VSeedDir);
        TVector3 VSeedPos = TVector3(SeedPos[0],SeedPos[1],SeedPos[2]);
        VSeedPoss.push_back(VSeedPos);
        
        // This is a two directional degeneracy
        //  This is one way to resolve it (maybe not the best)

        if(VSeedDir.Dot(fZDir)<0)
          AverageDir -= VSeedDir;
        else
          AverageDir += VSeedDir;
        
        // Work out which direction the seed points out in each plane
        std::vector<double> TimeDir, WireDir;
        
        GetSeedDirProjected(AllSeeds.at(i), WireDir, TimeDir);
        
        SeedSDirs.push_back(std::vector<int>(3));
        SeedHighSChans.push_back(std::vector<uint32_t>(3));
        SeedLowSChans.push_back(std::vector<uint32_t>(3));
        

        for(size_t n=0; n!=3; ++n)
          {
            if(WireDir[n]>0)
              {
                SeedSDirs[i][n]=1;
                SeedHighSChans[i][n] = MaxSeedChanPerView[n][i];
                SeedLowSChans[i][n]  = MinSeedChanPerView[n][i];
              }
            else
              {
                SeedSDirs[i][n]=-1;
                SeedHighSChans[i][n] = MinSeedChanPerView[n][i];
                SeedLowSChans[i][n]  = MaxSeedChanPerView[n][i];
              }
          }
      }
    
    AverageDir *= (1.0/AverageDir.Mag());
       
    std::vector<double> AngleToAve;
    std::vector<double> ProjAlongAve;
    
    for(size_t i=0; i!=AllSeeds.size(); ++i)
      {
        ProjAlongAve.push_back(VSeedPoss.at(i).Dot(AverageDir));
        AngleToAve.push_back(VSeedDirs.at(i).Dot(AverageDir)/VSeedDirs.at(i).Mag());
      }

    
    // For now we'll only look for 1 long track per cluster combo.
    //  There is room for improvement here if we need it.
    
    std::vector<size_t> TrackParts;
    std::vector<size_t> DoesNotFit;
    std::vector<size_t> AlreadyUsed;
    std::vector<size_t> ThrownByHits;
    std::map<int, bool> SeedNotAvailable;
  
    // This loop keeps running whilst there are still tracks to make
    while((AlreadyUsed.size()+ThrownByHits.size())<AllSeeds.size())
      {
               
        // This loop keeps running whilst there are still seeds
        //  to check for this track

        
        while((ThrownByHits.size()+TrackParts.size()+DoesNotFit.size()+AlreadyUsed.size())<AllSeeds.size())
          {
            
            // First find the lowest track proj remaining
            int LowestLeft=-1;
            for(size_t i=0; i!=AllSeeds.size(); ++i)
              {
                if(!SeedNotAvailable[i])
                  {
                    if(LowestLeft < 0) LowestLeft = i;
                    if(ProjAlongAve.at(i)<ProjAlongAve.at(LowestLeft))
                      LowestLeft = i;           
                  }
              }
        
            std::vector<std::vector<int> > InterpHits(3);
            
            if(TrackParts.size()==0) 
              {
                // If there are no seeds on the track, accept this seed
                //  as the first one to start running with.
                TrackParts.push_back(LowestLeft);
                SeedNotAvailable[LowestLeft]=true;
        
                // Mark the hits that go with this seed as taken
                for(size_t View=0; View!=3; ++View)
                  for(size_t iH=0; iH!=SeedToHitMap[View][LowestLeft].size();++iH)
                    HitStatus[View][SeedToHitMap[View][LowestLeft][iH]] = 2;
                
              }
            else if(TrackParts.size()>0) 
              {
                int a = TrackParts.at(TrackParts.size()-1);
                int b = LowestLeft;

                double Angle           = AllSeeds.at(a).GetAngle(AllSeeds.at(b));
                double ProjDisc        = AllSeeds.at(a).GetProjAngleDiscrepancy(AllSeeds.at(b));
                int PointingSign_ab    = AllSeeds.at(a).GetPointingSign(AllSeeds.at(b));
                int PointingSign_ba    = AllSeeds.at(b).GetPointingSign(AllSeeds.at(a));
                int PointingSign_ac    = 0;
        
                if(TrackParts.size()>1) PointingSign_ac = AllSeeds.at(a).GetPointingSign(AllSeeds.at(TrackParts.size()-2));
                
                bool SeedFits=false;

                // Check seed join conditions (no hits yet)
                bool JoinAngleOK    = fabs(Angle)<fTrackJoinAngle;
                bool PointingSignOK = (PointingSign_ac * PointingSign_ab)<0.5;
                bool ProjDiscOK     = false;
                if(PointingSign_ab > 0)
                  {
                    ProjDiscOK = fabs(ProjDisc) < fTrackJoinAngle;
                  }
                else
                  {
                    ProjDiscOK = fabs(ProjDisc - 3.142) < fTrackJoinAngle;
                  }
                
                if(JoinAngleOK && PointingSignOK && ProjDiscOK)
                  {
                    std::vector<uint32_t> EndChan_a(3), EndChan_b(3), LowChan(3), HighChan(3);
                    std::vector<std::vector<int> > HitsUnderConsideration(3);
  
                    for(size_t n=0; n!=3; ++n)
                      {
                        if(PointingSign_ab > 0)
                          EndChan_a[n] = SeedHighSChans[a][n];   
                        else
                          EndChan_a[n] = SeedLowSChans[a][n];
                        
                        if(PointingSign_ba > 0)
                          EndChan_b[n] = SeedHighSChans[b][n];   
                        else
                          EndChan_b[n] = SeedLowSChans[b][n];
                        
                        LowChan[n]  = std::min(EndChan_a[n], EndChan_b[n]) ;
                        HighChan[n] = std::max(EndChan_a[n], EndChan_b[n]) ;
                      }
                    
                    std::vector<std::vector<int> > TheseHits(3);
                    
                    
                    SeedFits = EvaluateOccupancy(AllSeeds.at(a), AllSeeds.at(b), fTrackResolution, AllHits, OrgHits, LowChan, HighChan, HitStatus, TheseHits);
                    
                    if(SeedFits) 
                      {
                        // This seed is good! Store it on the track
                        TrackParts.push_back(LowestLeft);
                        SeedNotAvailable[LowestLeft]=true;
                        
                        // Remove the hits that went with this seed from consideration
                        for(size_t View=0; View!=3; ++View)
                          for(size_t iH=0; iH!=SeedToHitMap[View][LowestLeft].size();++iH)
                            HitStatus[View][SeedToHitMap[View][LowestLeft][iH]] = 2;
                        // Remove the hits that were interpolated through from consideration
                        for(size_t n=0; n!=3; ++n)
                          for(size_t i=0; i!=InterpHits[n].size(); ++i)
                            {
                              HitStatus[n][InterpHits[n][i]] = 1;
                            }
                        // Kick out any seeds which are not invalidated by their
                        //  hits being stolen
                        for(size_t j=0; j!=AllSeeds.size(); ++j)
                          {
                            if(!SeedNotAvailable[j])
                              {
                                double OverlapFrac[3];
                                for(size_t n=0; n!=3; ++n)
                                  {
                                    int TotalInSeed=0;
                                    int TotalRejected=0;
                                    for(size_t iH=0; iH!=SeedToHitMap[n][j].size(); ++iH)
                                      {
                                        TotalInSeed++;
                                        if(HitStatus[n][SeedToHitMap[n][j][iH]]!=0)
                                          TotalRejected++;
                                      }
                                    OverlapFrac[n] = float(TotalRejected)/float(TotalInSeed);
                                  }
                                for(size_t n=0; n!=3; ++n)
                                  {
                                    size_t n1=(n+1)%3; size_t n2=(n+2)%3;
                                    if( (OverlapFrac[n]<=OverlapFrac[n1]) &&
                                        (OverlapFrac[n]<=OverlapFrac[n2]) )
                                      {
                                        if(OverlapFrac[n] > fOverlapCut)
                                          {
                                            SeedNotAvailable[j]=true;
                                            ThrownByHits.push_back(j);
                                            break;
                                          }
                                      }
                                  
                                  }// End view loop (seed tossing)
                              } // End checking seed availability (seed tossing)
                          } // End seed loop (seed tossing)
                      } // End if positive seed fit
                  }
                if(!SeedFits)
                  {
                    // If seed doesn't fit, mark it as such, and make it
                    //  temporarily unavailable.
                    DoesNotFit.push_back(LowestLeft);
                    SeedNotAvailable[LowestLeft]=true;
                  }
              } // End if(not first seed)
          } // End loop over all remaining seeds
        if(TrackParts.size()>0)
          {
            mf::LogVerbatim("BezierTrackerAlgorithm")<<" Prototrack runs through seeds: " ;
            std::vector<recob::Seed> TheTrackSeeds;
            
            TVector3 AveTrackDir =
              VSeedPoss.at(TrackParts.at(TrackParts.size()-1))
              - VSeedPoss.at(TrackParts.at(0));
            
            for(size_t i=0; i!=TrackParts.size(); ++i)
              {
                mf::LogVerbatim("BezierTrackerAlgorithm")<<"  " << TrackParts.at(i)<<", ";
                if(VSeedDirs.at(TrackParts.at(i)).Dot(AveTrackDir)>0)
                  TheTrackSeeds.push_back(AllSeeds.at(TrackParts.at(i)));
                else
                  TheTrackSeeds.push_back(AllSeeds.at(TrackParts.at(i)).Reverse());
                AlreadyUsed.push_back(TrackParts.at(i));
              }
            OrganizedByTrack.push_back(TheTrackSeeds);  
            
            HitsWithTracks.push_back(std::vector<std::vector<int> >(3));
            for(size_t n=0; n!=3; ++n)
              for(size_t iH=0; iH!=HitStatus[n].size(); ++iH)
                {
                  if((HitStatus[n][iH]==1)||(HitStatus[n][iH]==2))
                    {
                      HitStatus[n][iH]=3;
                      HitsWithTracks[HitsWithTracks.size()-1][n].push_back(iH);
                    }
                }
          }


        // Reset the count of unavailable seeds
        SeedNotAvailable.clear();

        // Anything which is either part of a track,
        //  or which has had its hits used, is not fair game.           
        for(size_t j=0; j!=AlreadyUsed.size(); ++j)
          {
            SeedNotAvailable[AlreadyUsed[j]]=true;
          }

        // For all the seeds which didn't fit, see how many
        //  are now ruled out by hit overlaps
        for(size_t i=0; i!=DoesNotFit.size(); ++i)
          {
            size_t j=DoesNotFit[i];
            double OverlapFrac[3];
            for(size_t n=0; n!=3; ++n)
              {
                int TotalInSeed=0;
                int TotalRejected=0;
                for(size_t iH=0; iH!=SeedToHitMap[n][j].size(); ++iH)
                  {
                    TotalInSeed++;
                    if(HitStatus[n][SeedToHitMap[n][j][iH]]!=0)
                      TotalRejected++;
                  }
                OverlapFrac[n] = float(TotalRejected)/float(TotalInSeed);
              }
            for(size_t n=0; n!=3; ++n)
              {
                size_t n1=(n+1)%3; size_t n2=(n+2)%3;
                if( (OverlapFrac[n]<=OverlapFrac[n1]) &&
                    (OverlapFrac[n]<=OverlapFrac[n2]) )
                  {
                    if(OverlapFrac[n] > fOverlapCut)
                      {
                        SeedNotAvailable[j]=true;
                        ThrownByHits.push_back(j);
                        break;
                      }
                  }
              }// End view loop (seed tossing)
          } // Loop over DoesNotFit
      
        
        for(size_t i=0; i!=ThrownByHits.size(); ++i)
          SeedNotAvailable[ThrownByHits[i]]=true;
        
        // Ready to go around again

        TrackParts.clear();     
        DoesNotFit.clear();
      }
    
    return OrganizedByTrack;
  }

void trkf::BezierTrackerAlgorithm::reconfigure

(

fhicl::ParameterSet const &

pset

)

Definition at line 48 of file BezierTrackerAlgorithm.cxx.

References CalculateGeometricalElements(), fDirectJoinDistance, fOccupancyThresh, fOverlapCut, fTheSeedFinder, fTrackJoinAngle, fTrackResolution, fVertexExtrapDistance, fVertexImpactThreshold, and fhicl::ParameterSet::get().

Referenced by BezierTrackerAlgorithm().

  {
    
    CalculateGeometricalElements();
    
    fTrackJoinAngle    = pset.get<double>("TrackJoinAngle");
    fDirectJoinDistance= pset.get<double>("DirectJoinDistance");
    
    fVertexImpactThreshold = pset.get<double>("VertexImpactThreshold");
    fVertexExtrapDistance = pset.get<double>("VertexExtrapDistance");
    
    fOccupancyThresh = pset.get<double>("OccupancyThresh");
    fTrackResolution = pset.get<double>("TrackResolution");
    fOverlapCut      = pset.get<double>("OverlapCut");



    fTheSeedFinder = new SeedFinderAlgorithm(pset.get<fhicl::ParameterSet>("SeedFinder"));
    
  }

void trkf::BezierTrackerAlgorithm::SortTracksByLength	(	std::vector< trkf::BezierTrack > &	BTracks,
		std::vector< art::PtrVector< recob::Hit > > &	HitVecs,
		std::vector< std::vector< std::pair< int, int > > > &	ClustersUsed
	)

Definition at line 401 of file BezierTrackerAlgorithm.cxx.

References fZDir.

  {
    
    std::vector<double> Lengths;
    std::vector<int>    SortedOrder;
    std::vector<bool>   Counted(BTracks.size());
    
    for(size_t i=0; i!=BTracks.size(); ++i) 
      {
        Lengths.push_back(BTracks.at(i).GetLength());
        if(BTracks.at(i).GetTrackDirectionV(0.0).Dot(fZDir)<0.0) BTracks.at(i)=BTracks.at(i).Reverse();
      }
    while(SortedOrder.size()<BTracks.size())
    {
      int Longest=-1;
      for(size_t i=0; i!=BTracks.size(); ++i)
        {
          if(!Counted[i])
            {
              if(Longest==-1) Longest=i;
              else
                if(Lengths.at(i)>Lengths.at(Longest)) Longest=i;
            }
        }
      Counted[Longest]=true;
      SortedOrder.push_back(Longest);
    }
    
    std::vector<trkf::BezierTrack> BTracksNew;
    std::vector<art::PtrVector<recob::Hit> >  HitVecsNew;
    std::vector<std::vector<std::pair<int, int> > > ClustersUsedNew;
    for(size_t i=0; i!=SortedOrder.size(); ++i)
      {
        BTracksNew.push_back(BTracks.at(SortedOrder.at(i)));
        HitVecsNew.push_back(HitVecs.at(SortedOrder.at(i)));
        ClustersUsedNew.push_back(ClustersUsed.at(SortedOrder.at(i)));
      }
    
    BTracks=BTracksNew;
    HitVecs=HitVecsNew;
    ClustersUsed=ClustersUsedNew;
  }

Member Data Documentation

double trkf::BezierTrackerAlgorithm::fDirectJoinDistance

private

Definition at line 93 of file BezierTrackerAlgorithm.h.

Referenced by MakeDirectJoins(), and reconfigure().

double trkf::BezierTrackerAlgorithm::fOccupancyThresh

private

Definition at line 95 of file BezierTrackerAlgorithm.h.

Referenced by EvaluateOccupancy(), and reconfigure().

double trkf::BezierTrackerAlgorithm::fOverlapCut

private

Definition at line 92 of file BezierTrackerAlgorithm.h.

Referenced by OrganizeSeedsIntoTracks(), and reconfigure().

std::vector<TVector3> trkf::BezierTrackerAlgorithm::fPitchDir

private

Definition at line 103 of file BezierTrackerAlgorithm.h.

Referenced by CalculateGeometricalElements(), EvaluateOccupancy(), and GetSeedDirProjected().

std::vector<double> trkf::BezierTrackerAlgorithm::fPitches

private

Definition at line 101 of file BezierTrackerAlgorithm.h.

Referenced by CalculateGeometricalElements(), EvaluateOccupancy(), GetSeedDirProjected(), and MakeTracks().

std::vector<double> trkf::BezierTrackerAlgorithm::fPlaneTimeOffsets

private

Definition at line 102 of file BezierTrackerAlgorithm.h.

Referenced by CalculateGeometricalElements(), and MakeTracks().

SeedFinderAlgorithm* trkf::BezierTrackerAlgorithm::fTheSeedFinder

private

Definition at line 114 of file BezierTrackerAlgorithm.h.

Referenced by reconfigure().

double trkf::BezierTrackerAlgorithm::fTrackJoinAngle

private

Definition at line 94 of file BezierTrackerAlgorithm.h.

Referenced by MakeDirectJoins(), OrganizeSeedsIntoTracks(), and reconfigure().

double trkf::BezierTrackerAlgorithm::fTrackResolution

private

Definition at line 96 of file BezierTrackerAlgorithm.h.

Referenced by FilterOverlapTracks(), MakeDirectJoins(), MakeOverlapJoins(), OrganizeSeedsIntoTracks(), and reconfigure().

double trkf::BezierTrackerAlgorithm::fVertexExtrapDistance

private

Definition at line 99 of file BezierTrackerAlgorithm.h.

Referenced by MakeVertexJoins(), and reconfigure().

double trkf::BezierTrackerAlgorithm::fVertexImpactThreshold

private

Definition at line 98 of file BezierTrackerAlgorithm.h.

Referenced by MakeVertexJoins(), and reconfigure().

std::vector<TVector3> trkf::BezierTrackerAlgorithm::fWireDir

private

Definition at line 104 of file BezierTrackerAlgorithm.h.

Referenced by CalculateGeometricalElements(), and EvaluateOccupancy().

std::vector<double> trkf::BezierTrackerAlgorithm::fWireZeroOffset

private

Definition at line 105 of file BezierTrackerAlgorithm.h.

Referenced by CalculateGeometricalElements(), EvaluateOccupancy(), and MakeTracks().

TVector3 trkf::BezierTrackerAlgorithm::fXDir

private

Definition at line 106 of file BezierTrackerAlgorithm.h.

Referenced by CalculateGeometricalElements(), EvaluateOccupancy(), and GetSeedDirProjected().

TVector3 trkf::BezierTrackerAlgorithm::fYDir

private

Definition at line 106 of file BezierTrackerAlgorithm.h.

Referenced by CalculateGeometricalElements().

TVector3 trkf::BezierTrackerAlgorithm::fZDir

private

Definition at line 106 of file BezierTrackerAlgorithm.h.

Referenced by CalculateGeometricalElements(), OrganizeSeedsIntoTracks(), and SortTracksByLength().

---

The documentation for this class was generated from the following files:

• /cvmfs/larsoft.opensciencegrid.org/products/larreco/v07_10_02/source/larreco/RecoAlg/BezierTrackerAlgorithm.h
• /cvmfs/larsoft.opensciencegrid.org/products/larreco/v07_10_02/source/larreco/RecoAlg/BezierTrackerAlgorithm.cxx