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DTCombinatorialPatternReco Class Reference

#include <DTCombinatorialPatternReco.h>

Inheritance diagram for DTCombinatorialPatternReco:
DTRecSegment2DBaseAlgo

List of all members.

Classes

class  TriedPattern

Public Types

typedef boost::unordered_set
< TriedPattern
TriedPatterns

Public Member Functions

virtual std::string algoName () const
 return the algo name
 DTCombinatorialPatternReco (const edm::ParameterSet &pset)
 Constructor.
virtual edm::OwnVector
< DTSLRecSegment2D
reconstruct (const DTSuperLayer *sl, const std::vector< DTRecHit1DPair > &hits)
 this function is called in the producer
virtual void setES (const edm::EventSetup &setup)
virtual ~DTCombinatorialPatternReco ()
 Destructor.

Private Types

typedef std::pair
< DTHitPairForFit
*, DTEnums::DTCellSide
AssPoint

Private Member Functions

DTSegmentCandbuildBestSegment (std::vector< AssPoint > &assHits, const DTSuperLayer *sl)
void buildPointsCollection (std::vector< AssPoint > &points, std::deque< DTHitPairForFit * > &pointsNoLR, std::vector< DTSegmentCand * > &candidates, const DTSuperLayer *sl)
std::vector< DTSegmentCand * > buildSegments (const DTSuperLayer *sl, const std::vector< DTHitPairForFit * > &hits)
bool checkDoubleCandidates (std::vector< DTSegmentCand * > &segs, DTSegmentCand *seg)
std::vector< AssPointfindCompatibleHits (const LocalPoint &pos, const LocalVector &dir, const std::vector< DTHitPairForFit * > &hits)
std::vector< DTHitPairForFit * > initHits (const DTSuperLayer *sl, const std::vector< DTRecHit1DPair > &hits)

Private Attributes

bool debug
std::string theAlgoName
double theAlphaMaxPhi
double theAlphaMaxTheta
DTSegmentCleanertheCleaner
edm::ESHandle< DTGeometrytheDTGeometry
unsigned int theMaxAllowedHits
TriedPatterns theTriedPattern
DTSegmentUpdatortheUpdator
bool usePairs

Friends

class DTCombinatorialPatternReco4D

Detailed Description

Algo for reconstructing 2d segment in DT using a combinatorial approach

Date:
2009/11/27 11:59:48
Revision:
1.12
Author:
Stefano Lacaprara - INFN Legnaro <stefano.lacaprara@pd.infn.it>
Riccardo Bellan - INFN TO <riccardo.bellan@cern.ch>

Definition at line 42 of file DTCombinatorialPatternReco.h.


Member Typedef Documentation

Definition at line 71 of file DTCombinatorialPatternReco.h.

Definition at line 145 of file DTCombinatorialPatternReco.h.


Constructor & Destructor Documentation

DTCombinatorialPatternReco::DTCombinatorialPatternReco ( const edm::ParameterSet pset)

Constructor.

Definition at line 36 of file DTCombinatorialPatternReco.cc.

References debug, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), theAlphaMaxPhi, theAlphaMaxTheta, theCleaner, theMaxAllowedHits, theUpdator, and usePairs.

                                                                                  : 
DTRecSegment2DBaseAlgo(pset), theAlgoName("DTCombinatorialPatternReco")
{
  theMaxAllowedHits = pset.getParameter<unsigned int>("MaxAllowedHits"); // 100
  theAlphaMaxTheta = pset.getParameter<double>("AlphaMaxTheta");// 0.1 ;
  theAlphaMaxPhi = pset.getParameter<double>("AlphaMaxPhi");// 1.0 ;
  debug = pset.getUntrackedParameter<bool>("debug"); //true;
  theUpdator = new DTSegmentUpdator(pset);
  theCleaner = new DTSegmentCleaner(pset);
  string theHitAlgoName = pset.getParameter<string>("recAlgo");
  usePairs = !(theHitAlgoName=="DTNoDriftAlgo");
}
DTCombinatorialPatternReco::~DTCombinatorialPatternReco ( ) [virtual]

Destructor.

Definition at line 50 of file DTCombinatorialPatternReco.cc.

References theCleaner, and theUpdator.

                                                        {
  delete theUpdator;
  delete theCleaner;
}

Member Function Documentation

virtual std::string DTCombinatorialPatternReco::algoName ( void  ) const [inline, virtual]

return the algo name

Implements DTRecSegment2DBaseAlgo.

Definition at line 60 of file DTCombinatorialPatternReco.h.

References theAlgoName.

{ return theAlgoName; }
DTSegmentCand * DTCombinatorialPatternReco::buildBestSegment ( std::vector< AssPoint > &  assHits,
const DTSuperLayer sl 
) [private]

Definition at line 318 of file DTCombinatorialPatternReco.cc.

References buildPointsCollection(), gather_cfg::cout, debug, and DTEnums::undefLR.

Referenced by buildSegments().

                                                                     {
  if (hits.size()<3) {
    //cout << "buildBestSegment: hits " << hits.size()<< endl;
    return 0; // a least 3 point
  }

  // hits with defined LR
  vector<AssPoint> points;

  // without: I store both L and R, a deque since I need front insertion and
  // deletion
  deque<DTHitPairForFit* > pointsNoLR; 

  // first add only the hits with LR assigned
  for (vector<AssPoint>::const_iterator hit=hits.begin();
       hit!=hits.end(); ++hit) {
    if ((*hit).second != DTEnums::undefLR) {
      points.push_back(*hit);
    } else { // then also for the undef'd one
      pointsNoLR.push_back((*hit).first);
    }
  }

  if(debug) {
    cout << "points " << points.size() << endl;
    cout << "pointsNoLR " << pointsNoLR.size() << endl;
  }

  // build all possible candidates using L/R ambiguity
  vector<DTSegmentCand*> candidates ;

  buildPointsCollection(points, pointsNoLR, candidates, sl);

  if(debug)
    cout << "candidates " << candidates.size() << endl;

  // so now I have build a given number of segments, I should find the best one,
  // by #hits and chi2.
  vector<DTSegmentCand*>::const_iterator bestCandIter = candidates.end();
  double minChi2=999999.;
  unsigned int maxNumHits=0;
  for (vector<DTSegmentCand*>::const_iterator iter=candidates.begin();
       iter!=candidates.end(); ++iter) {
    if ((*iter)->nHits()==maxNumHits && (*iter)->chi2()<minChi2) {
      minChi2=(*iter)->chi2();
      bestCandIter=iter;
    } else if ((*iter)->nHits()>maxNumHits) {
      maxNumHits=(*iter)->nHits();
      minChi2=(*iter)->chi2();
      bestCandIter=iter;
    }
  }

  // delete all candidates but the best one!
  for (vector<DTSegmentCand*>::iterator iter=candidates.begin();
       iter!=candidates.end(); ++iter) if (iter!=bestCandIter) delete *iter;

       // return the best candate if any
       if (bestCandIter != candidates.end()) {
         return (*bestCandIter);
       }
       return 0;
}
void DTCombinatorialPatternReco::buildPointsCollection ( std::vector< AssPoint > &  points,
std::deque< DTHitPairForFit * > &  pointsNoLR,
std::vector< DTSegmentCand * > &  candidates,
const DTSuperLayer sl 
) [private]

build collection of compatible hits for L/R hits: the candidates is updated with the segment candidates found

Definition at line 376 of file DTCombinatorialExtendedPatternReco.cc.

References DTCombinatorialExtendedPatternReco::buildPointsCollection(), filterCSVwithJSON::copy, gather_cfg::cout, DTCombinatorialExtendedPatternReco::debug, DTSegmentUpdator::fit(), DTEnums::Left, DTEnums::Right, and DTCombinatorialExtendedPatternReco::theUpdator.

Referenced by buildBestSegment().

                                                                          {

  if(debug) {
    cout << "DTCombinatorialExtendedPatternReco::buildPointsCollection " << endl;
    cout << "points: " << points.size() << " NOLR: " << pointsNoLR.size()<< endl;
  }
  if (pointsNoLR.size()>0) { // still unassociated points!
    DTHitPairForFit* unassHit = pointsNoLR.front();
    // try with the right
    if(debug)
      cout << "Right hit" << endl;
    points.push_back(AssPoint(unassHit, DTEnums::Right));
    pointsNoLR.pop_front();
    buildPointsCollection(points, pointsNoLR, candidates, sl);
    pointsNoLR.push_front((unassHit));
    points.pop_back();

    // try with the left
    if(debug)
      cout << "Left hit" << endl;
    points.push_back(AssPoint(unassHit, DTEnums::Left));
    pointsNoLR.pop_front();
    buildPointsCollection(points, pointsNoLR, candidates, sl);
    pointsNoLR.push_front((unassHit));
    points.pop_back();
  } else { // all associated

    if(debug) {
      cout << "The Hits were" << endl;
      copy(points.begin(), points.end(),
           ostream_iterator<DTSegmentCand::AssPoint>(std::cout));
      cout << "----" << endl;
      cout << "All associated " << endl;
    }
    DTSegmentCand::AssPointCont pointsSet;

    // for (vector<AssPoint>::const_iterator point=points.begin();
    //      point!=points.end(); ++point) 
    pointsSet.insert(points.begin(),points.end());

    if(debug) {
      cout << "The Hits are" << endl;
      copy(pointsSet.begin(), pointsSet.end(),
           ostream_iterator<DTSegmentCand::AssPoint>(std::cout));
      cout << "----" << endl;
    }

    DTSegmentCand* newCand = new DTSegmentCand(pointsSet,sl);
    if (theUpdator->fit(newCand)) candidates.push_back(newCand);
    else delete newCand; // bad seg, too few hits
  }
}
vector< DTSegmentCand * > DTCombinatorialPatternReco::buildSegments ( const DTSuperLayer sl,
const std::vector< DTHitPairForFit * > &  hits 
) [private]

get two hits in different layers and see if there are other / hits

Definition at line 106 of file DTCombinatorialPatternReco.cc.

References buildBestSegment(), checkDoubleCandidates(), DTSegmentCleaner::clean(), gather_cfg::cout, debug, findCompatibleHits(), DTSegmentCand::good(), DTSuperLayer::id(), listHistos::IP, DTEnums::Left, query::result, DTEnums::Right, theAlphaMaxPhi, theAlphaMaxTheta, theCleaner, theMaxAllowedHits, PV3DBase< T, PVType, FrameType >::theta(), theTriedPattern, GeomDet::toGlobal(), and csvLumiCalc::unit.

Referenced by DTMeantimerPatternReco4D::buildPhiSuperSegmentsCandidates(), and reconstruct().

                                                                                  {
  // clear the patterns tried
  if (debug) {
      cout << "theTriedPattern.size is " << theTriedPattern.size() << "\n";
  }
  theTriedPattern.clear();

  typedef vector<DTHitPairForFit*> hitCont;
  typedef hitCont::const_iterator  hitIter;
  vector<DTSegmentCand*> result;
  
  if(debug) {
    cout << "buildSegments: " << sl->id() << " nHits " << hits.size() << endl;
    for (vector<DTHitPairForFit*>::const_iterator hit=hits.begin();
         hit!=hits.end(); ++hit) cout << **hit<< endl;
  }

  // 10-Mar-2004 SL
  // put a protection against heavily populated chambers, for which the segment
  // building could lead to infinite memory usage...
  if (hits.size() > theMaxAllowedHits ) {
    if(debug) {
      cout << "Warning: this SuperLayer " << sl->id() << " has too many hits : "
        << hits.size() << " max allowed is " << theMaxAllowedHits << endl;
      cout << "Skipping segment reconstruction... " << endl;
    }
    return result;
  }

  //  compatible with them
  for (hitCont::const_iterator firstHit=hits.begin(); firstHit!=hits.end();
       ++firstHit) {
    for (hitCont::const_reverse_iterator lastHit=hits.rbegin(); 
         (*lastHit)!=(*firstHit); ++lastHit) {
      //if ( (*lastHit)->id().layerId() == (*firstHit)->id().layerId() ) continue; // hits must be in different layers!
      // hits must nor in the same nor in adiacent layers
      if ( fabs((*lastHit)->id().layerId()-(*firstHit)->id().layerId())<=1 ) continue;
      if(debug) {
        cout << "Selected these two hits pair " << endl;
        cout << "First " << *(*firstHit) << " Layer Id: " << (*firstHit)->id().layerId() << endl;
        cout << "Last "  << *(*lastHit)  << " Layer Id: " << (*lastHit)->id().layerId()  << endl;
      }

      GlobalPoint IP;
      float DAlphaMax;
      if ((sl->id()).superlayer()==2)  // Theta SL
        DAlphaMax=theAlphaMaxTheta;
      else // Phi SL
        DAlphaMax=theAlphaMaxPhi;

      DTEnums::DTCellSide codes[2]={DTEnums::Right, DTEnums::Left};
      for (int firstLR=0; firstLR<2; ++firstLR) {
        for (int lastLR=0; lastLR<2; ++lastLR) {
          // TODO move the global transformation in the DTHitPairForFit class
          // when it will be moved I will able to remove the sl from the input parameter
          GlobalPoint gposFirst=sl->toGlobal( (*firstHit)->localPosition(codes[firstLR]) );
          GlobalPoint gposLast= sl->toGlobal( (*lastHit)->localPosition(codes[lastLR]) );

          GlobalVector gvec=gposLast-gposFirst;
          GlobalVector gvecIP=gposLast-IP;

          // difference in angle measured
          float DAlpha=fabs(gvec.theta()-gvecIP.theta());

          // cout << "DAlpha " << DAlpha << endl;
          if (DAlpha<DAlphaMax) {

            // create a segment hypotesis
            // I don't need a true segment, just direction and position
            LocalPoint posIni = (*firstHit)->localPosition(codes[firstLR]);
            LocalVector dirIni = 
              ((*lastHit)->localPosition(codes[lastLR])-posIni).unit();

            // search for other compatible hits, with or without the L/R solved
            vector<AssPoint> assHits = findCompatibleHits(posIni, dirIni, hits);
            if(debug) 
              cout << "compatible hits " << assHits.size() << endl;

            // get the best segment with these hits: it's just one! 
            // (is it correct?)
            DTSegmentCand* seg = buildBestSegment(assHits, sl);

            if (seg) {
              if(debug) 
                cout << "segment " << *seg<< endl;

              // check if the chi2 and #hits are ok
              if (!seg->good()) {
                delete seg;
              } else { 

                // remove duplicated segments (I know, would be better to do it before the
                // fit...)
                if (checkDoubleCandidates(result,seg)) {
                  // add to the vector of hypotesis
                  result.push_back(seg);
                  if(debug) 
                    cout << "result is now " << result.size() << endl;
                } else { // delete it!
                  delete seg;
                  if(debug) 
                    cout << "already existing" << endl;
                }
              }
            }
          }
        }
      }
    }
  }
  if (debug) {
    for (vector<DTSegmentCand*>::const_iterator seg=result.begin();
         seg!=result.end(); ++seg) 
      cout << *(*seg) << endl;
  }

  // now I have a couple of segment hypotesis, should check for ghost
  result = theCleaner->clean(result);
  if (debug) {
    cout << "result no ghost  " << result.size() << endl;
    for (vector<DTSegmentCand*>::const_iterator seg=result.begin();
         seg!=result.end(); ++seg) 
      cout << *(*seg) << endl;
  }

  return result;
}
bool DTCombinatorialPatternReco::checkDoubleCandidates ( std::vector< DTSegmentCand * > &  segs,
DTSegmentCand seg 
) [private]

Referenced by buildSegments().

vector< DTCombinatorialPatternReco::AssPoint > DTCombinatorialPatternReco::findCompatibleHits ( const LocalPoint pos,
const LocalVector dir,
const std::vector< DTHitPairForFit * > &  hits 
) [private]

Definition at line 240 of file DTCombinatorialExtendedPatternReco.cc.

References filterCSVwithJSON::copy, gather_cfg::cout, DTCombinatorialExtendedPatternReco::debug, spr::find(), DTEnums::Left, query::result, DTEnums::Right, lumiQTWidget::t, DTCombinatorialExtendedPatternReco::theTriedPattern, DTEnums::undefLR, and DTCombinatorialExtendedPatternReco::usePairs.

Referenced by buildSegments().

                                                                                     {
  if (debug) cout << "Pos: " << posIni << " Dir: "<< dirIni << endl;
  vector<AssPoint> result;

  // counter to early-avoid double counting in hits pattern
  vector<int> tried;
  int nCompatibleHits=0;

  typedef vector<DTHitPairForFit*> hitCont;
  typedef hitCont::const_iterator  hitIter;
  for (hitIter hit=hits.begin(); hit!=hits.end(); ++hit) {
    pair<bool,bool> isCompatible = (*hit)->isCompatible(posIni, dirIni);
    if (debug) 
      cout << "isCompatible " << isCompatible.first << " " <<
        isCompatible.second << endl;

    // if only one of the two is compatible, then the LR is assigned,
    // otherwise is undefined

    DTEnums::DTCellSide lrcode;
    if (isCompatible.first && isCompatible.second) {
      usePairs ? lrcode=DTEnums::undefLR : lrcode=DTEnums::Left ; // if not usePairs then only use single side 
      tried.push_back(3);
      nCompatibleHits++;
    }
    else if (isCompatible.first) {
      lrcode=DTEnums::Left;
      tried.push_back(2);
      nCompatibleHits++;
    }
    else if (isCompatible.second) {
      lrcode=DTEnums::Right;
      tried.push_back(1);
      nCompatibleHits++;
    }
    else {
      tried.push_back(0);
      continue; // neither is compatible
    }
    result.push_back(AssPoint(*hit, lrcode));
  }
  

  // check if too few associated hits or pattern already tried
  if ( nCompatibleHits < 3 || find(theTriedPattern.begin(), theTriedPattern.end(),tried) == theTriedPattern.end()) {
    theTriedPattern.push_back(tried);
  } else {
    if (debug) {
      vector<vector<int> >::const_iterator t=find(theTriedPattern.begin(),
                                                  theTriedPattern.end(),
                                                  tried);
      cout << "Already tried";
      copy((*t).begin(), (*t).end(), ostream_iterator<int>(std::cout));
      cout << endl;
    }
    // empty the result vector
    result.clear();
  }
  return result;
}
vector< DTHitPairForFit * > DTCombinatorialPatternReco::initHits ( const DTSuperLayer sl,
const std::vector< DTRecHit1DPair > &  hits 
) [private]

Definition at line 94 of file DTCombinatorialPatternReco.cc.

References query::result, and theDTGeometry.

Referenced by DTMeantimerPatternReco4D::buildPhiSuperSegmentsCandidates(), and reconstruct().

                                                                           {  
  
  vector<DTHitPairForFit*> result;
  for (vector<DTRecHit1DPair>::const_iterator hit=hits.begin();
       hit!=hits.end(); ++hit) {
    result.push_back(new DTHitPairForFit(*hit, *sl, theDTGeometry));
  }
  return result;
}
edm::OwnVector< DTSLRecSegment2D > DTCombinatorialPatternReco::reconstruct ( const DTSuperLayer sl,
const std::vector< DTRecHit1DPair > &  hits 
) [virtual]

this function is called in the producer

Implements DTRecSegment2DBaseAlgo.

Definition at line 57 of file DTCombinatorialPatternReco.cc.

References edm::OwnVector< T, P >::back(), buildSegments(), gather_cfg::cout, debug, initHits(), edm::OwnVector< T, P >::push_back(), query::result, theUpdator, and DTSegmentUpdator::update().

Referenced by DTCombinatorialPatternReco4D::reconstruct().

                                                                               {

  edm::OwnVector<DTSLRecSegment2D> result;
  vector<DTHitPairForFit*> hitsForFit = initHits(sl, pairs);

  vector<DTSegmentCand*> candidates = buildSegments(sl, hitsForFit);

  vector<DTSegmentCand*>::const_iterator cand=candidates.begin();
  while (cand<candidates.end()) {
    
    DTSLRecSegment2D *segment = (**cand);

    theUpdator->update(segment);

    result.push_back(segment);

    if (debug) {
      cout<<"Reconstructed 2D segments "<< result.back() <<endl;
    }

    delete *(cand++); // delete the candidate!
  }

  for (vector<DTHitPairForFit*>::iterator it = hitsForFit.begin(), ed = hitsForFit.end(); 
        it != ed; ++it) delete *it;

  return result;
}
void DTCombinatorialPatternReco::setES ( const edm::EventSetup setup) [virtual]

Through this function the EventSetup is percolated to the objs which request it

Implements DTRecSegment2DBaseAlgo.

Definition at line 87 of file DTCombinatorialPatternReco.cc.

References edm::EventSetup::get(), DTSegmentUpdator::setES(), theDTGeometry, and theUpdator.

Referenced by DTCombinatorialPatternReco4D::setES().

                                                                {
  // Get the DT Geometry
  setup.get<MuonGeometryRecord>().get(theDTGeometry);
  theUpdator->setES(setup);
}

Friends And Related Function Documentation

friend class DTCombinatorialPatternReco4D [friend]

Definition at line 69 of file DTCombinatorialPatternReco.h.


Member Data Documentation

Definition at line 101 of file DTCombinatorialPatternReco.h.

Referenced by algoName().

Definition at line 104 of file DTCombinatorialPatternReco.h.

Referenced by buildSegments(), and DTCombinatorialPatternReco().

Definition at line 103 of file DTCombinatorialPatternReco.h.

Referenced by buildSegments(), and DTCombinatorialPatternReco().

Definition at line 110 of file DTCombinatorialPatternReco.h.

Referenced by initHits(), and setES().

Definition at line 102 of file DTCombinatorialPatternReco.h.

Referenced by buildSegments(), and DTCombinatorialPatternReco().

Definition at line 148 of file DTCombinatorialPatternReco.h.

Referenced by buildSegments().

Definition at line 106 of file DTCombinatorialPatternReco.h.

Referenced by DTCombinatorialPatternReco().