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Public Member Functions | Private Types | Private Member Functions | Private Attributes

RKPropagatorInS Class Reference

#include <RKPropagatorInS.h>

Inheritance diagram for RKPropagatorInS:
Propagator

List of all members.

Public Member Functions

virtual Propagatorclone () const
virtual const MagneticFieldmagneticField () const
virtual TrajectoryStateOnSurface propagate (const FreeTrajectoryState &, const Cylinder &) const
virtual TrajectoryStateOnSurface propagate (const FreeTrajectoryState &, const Plane &) const
TrajectoryStateOnSurface propagate (const TrajectoryStateOnSurface &ts, const Plane &plane) const
virtual std::pair
< TrajectoryStateOnSurface,
double > 
propagateWithPath (const FreeTrajectoryState &, const Plane &) const
virtual std::pair
< TrajectoryStateOnSurface,
double > 
propagateWithPath (const FreeTrajectoryState &, const Cylinder &) const
 RKPropagatorInS (const MagVolume &vol, PropagationDirection dir=alongMomentum, double tolerance=5.e-5)
 ~RKPropagatorInS ()

Private Types

typedef std::pair
< TrajectoryStateOnSurface,
double > 
TsosWP

Private Member Functions

RKLocalFieldProvider fieldProvider () const
RKLocalFieldProvider fieldProvider (const Cylinder &cyl) const dso_internal
GlobalVector globalMomentum (const Basic3DVector< double > &mom) const dso_internal
GlobalPoint globalPosition (const Basic3DVector< double > &pos) const dso_internal
GlobalTrajectoryParameters gtpFromLocal (const Basic3DVector< double > &lpos, const Basic3DVector< double > &lmom, TrackCharge ch, const Surface &surf) const dso_internal
GlobalTrajectoryParameters gtpFromVolumeLocal (const CartesianStateAdaptor &state, TrackCharge charge) const dso_internal
PropagationDirection invertDirection (PropagationDirection dir) const dso_internal
GlobalParametersWithPath propagateParametersOnCylinder (const FreeTrajectoryState &ts, const Cylinder &cyl) const dso_internal
GlobalParametersWithPath propagateParametersOnPlane (const FreeTrajectoryState &ts, const Plane &plane) const dso_internal
Basic3DVector< double > rkMomentum (const GlobalVector &mom) const dso_internal
Basic3DVector< double > rkPosition (const GlobalPoint &pos) const dso_internal

Private Attributes

double theTolerance
const MagVolumetheVolume

Detailed Description

Definition at line 20 of file RKPropagatorInS.h.


Member Typedef Documentation

typedef std::pair<TrajectoryStateOnSurface,double> RKPropagatorInS::TsosWP [private]

Definition at line 61 of file RKPropagatorInS.h.


Constructor & Destructor Documentation

RKPropagatorInS::RKPropagatorInS ( const MagVolume vol,
PropagationDirection  dir = alongMomentum,
double  tolerance = 5.e-5 
) [inline, explicit]

Definition at line 27 of file RKPropagatorInS.h.

Referenced by clone().

                                                      : 
    Propagator(dir), theVolume( &vol), theTolerance( tolerance) {}
RKPropagatorInS::~RKPropagatorInS ( ) [inline]

Definition at line 31 of file RKPropagatorInS.h.

{}

Member Function Documentation

Propagator * RKPropagatorInS::clone ( void  ) const [virtual]

Implements Propagator.

Definition at line 345 of file RKPropagatorInS.cc.

References RKPropagatorInS().

{
    return new RKPropagatorInS(*this);
}
RKLocalFieldProvider RKPropagatorInS::fieldProvider ( ) const [private]

Definition at line 358 of file RKPropagatorInS.cc.

References theVolume.

Referenced by propagateParametersOnCylinder(), and propagateParametersOnPlane().

RKLocalFieldProvider RKPropagatorInS::fieldProvider ( const Cylinder cyl) const [private]

Definition at line 363 of file RKPropagatorInS.cc.

References theVolume.

{
  return RKLocalFieldProvider( *theVolume, cyl);
}
GlobalVector RKPropagatorInS::globalMomentum ( const Basic3DVector< double > &  mom) const [private]

Definition at line 392 of file RKPropagatorInS.cc.

References theVolume, and GloballyPositioned< T >::toGlobal().

Referenced by gtpFromVolumeLocal().

{
  if (theVolume != 0) return theVolume->toGlobal( LocalVector(mom));
  else return GlobalVector(mom);
}
GlobalPoint RKPropagatorInS::globalPosition ( const Basic3DVector< double > &  pos) const [private]

Definition at line 386 of file RKPropagatorInS.cc.

References theVolume, and GloballyPositioned< T >::toGlobal().

Referenced by gtpFromVolumeLocal(), and propagateParametersOnPlane().

{
  if (theVolume != 0) return theVolume->toGlobal( LocalPoint(pos));
  else return GlobalPoint(pos);
}
GlobalTrajectoryParameters RKPropagatorInS::gtpFromLocal ( const Basic3DVector< double > &  lpos,
const Basic3DVector< double > &  lmom,
TrackCharge  ch,
const Surface surf 
) const [private]

Definition at line 350 of file RKPropagatorInS.cc.

References theVolume, and Surface::toGlobal().

Referenced by propagateParametersOnCylinder().

{
    return GlobalTrajectoryParameters( surf.toGlobal( LocalPoint( lpos)),
                                       surf.toGlobal( LocalVector( lmom)), ch, theVolume);
}
GlobalTrajectoryParameters RKPropagatorInS::gtpFromVolumeLocal ( const CartesianStateAdaptor state,
TrackCharge  charge 
) const [private]
PropagationDirection RKPropagatorInS::invertDirection ( PropagationDirection  dir) const [private]
virtual const MagneticField* RKPropagatorInS::magneticField ( ) const [inline, virtual]

Implements Propagator.

Definition at line 57 of file RKPropagatorInS.h.

References theVolume.

Referenced by NavPropagator::propagateInVolume().

{return theVolume;}
TrajectoryStateOnSurface RKPropagatorInS::propagate ( const FreeTrajectoryState fts,
const Cylinder cyl 
) const [virtual]

Implements Propagator.

Definition at line 340 of file RKPropagatorInS.cc.

References propagateWithPath().

{
  return propagateWithPath( fts, cyl).first;
}
TrajectoryStateOnSurface RKPropagatorInS::propagate ( const TrajectoryStateOnSurface ts,
const Plane plane 
) const [inline, virtual]

Reimplemented from Propagator.

Definition at line 48 of file RKPropagatorInS.h.

References first, TrajectoryStateOnSurface::freeState(), and propagateWithPath().

                                                               {
    return propagateWithPath( *ts.freeState(),plane).first;
  }
TrajectoryStateOnSurface RKPropagatorInS::propagate ( const FreeTrajectoryState fts,
const Plane plane 
) const [virtual]

Implements Propagator.

Definition at line 334 of file RKPropagatorInS.cc.

References propagateWithPath().

{
  return propagateWithPath( fts, plane).first;
}
GlobalParametersWithPath RKPropagatorInS::propagateParametersOnCylinder ( const FreeTrajectoryState ts,
const Cylinder cyl 
) const [private]

Definition at line 200 of file RKPropagatorInS.cc.

References abs, FreeTrajectoryState::charge(), alignCSCRings::e, fieldProvider(), gtpFromLocal(), invertDirection(), likely, LogDebug, FreeTrajectoryState::momentum(), CartesianStateAdaptor::momentum(), getHLTPrescaleColumns::path, StraightLineBarrelCylinderCrossing::pathLength(), StraightLineCylinderCrossing::pathLength(), perp(), pos, CartesianStateAdaptor::position(), StraightLineBarrelCylinderCrossing::position(), GloballyPositioned< T >::position(), FreeTrajectoryState::position(), Propagator::propagationDirection(), Cylinder::radius(), rho, CartesianStateAdaptor::rkstate(), alignCSCRings::s, theTolerance, theVolume, GloballyPositioned< T >::toLocal(), FreeTrajectoryState::transverseCurvature(), unlikely, PV3DBase< T, PVType, FrameType >::x(), x, and PV3DBase< T, PVType, FrameType >::y().

Referenced by propagateWithPath().

                                                                           {

  typedef RKAdaptiveSolver<double,RKOneCashKarpStep, 6>   Solver;
  typedef Solver::Vector                                  RKVector;
  
  
  GlobalPoint sp = cyl.position();
  if unlikely(sp.x()!=0. || sp.y()!=0.) {
      throw PropagationException("Cannot propagate to an arbitrary cylinder");
    }
  
  GlobalPoint gpos( ts.position());
  GlobalVector gmom( ts.momentum());
  LocalPoint pos(cyl.toLocal(gpos));
  LocalVector mom(cyl.toLocal(gmom));
  double startR = cyl.radius() - pos.perp();
  
  // LogDebug("RKPropagatorInS")  << "RKPropagatorInS: starting from FTS " << ts ;
  
  
  // (transverse) curvature
  double rho = ts.transverseCurvature();
  //
  // Straight line approximation? |rho|<1.e-10 equivalent to ~ 1um 
  // difference in transversal position at 10m.
  //
  if  unlikely( fabs(rho)<1.e-10 ) {
      //
      // Instantiate auxiliary object for finding intersection.
      // Frame-independant point and vector are created explicitely to 
      // avoid confusing gcc (refuses to compile with temporary objects
      // in the constructor).
      //
      
      StraightLineBarrelCylinderCrossing cylCrossing(gpos,gmom,propagationDirection());
      
      //
      // get solution
      //
      std::pair<bool,double> propResult = cylCrossing.pathLength(cyl);
      if  likely( propResult.first && theVolume !=0) {
          double s = propResult.second;
          // point (reconverted to GlobalPoint)
          GlobalPoint x (cylCrossing.position(s));
          GlobalTrajectoryParameters res( x, gmom, ts.charge(), theVolume);
          LogDebug("RKPropagatorInS")  << "Straight line propagation to cylinder succeeded !!";
          return GlobalParametersWithPath( res, s);
        } 
      
      //do someting 
      edm::LogError("RKPropagatorInS")  <<"Straight line propagation to cylinder failed !!";
      return GlobalParametersWithPath( );
      
    }
  
  
  RKLocalFieldProvider field( fieldProvider(cyl));
  // StraightLineCylinderCrossing pathLength( pos, mom, propagationDirection());
  CartesianLorentzForce deriv(field, ts.charge());
  
  RKCartesianDistance dist;
  double eps = theTolerance;
  Solver solver;
  double stot = 0;
  PropagationDirection currentDirection = propagationDirection();
  
  RKVector start( CartesianStateAdaptor::rkstate( pos.basicVector(), mom.basicVector()));
  int safeGuard = 0;
  while (safeGuard++<100) {
    CartesianStateAdaptor startState(start);
    StraightLineCylinderCrossing pathLength( LocalPoint(startState.position()), 
                                             LocalVector(startState.momentum()), 
                                             currentDirection, eps);
    
    std::pair<bool,double> path = pathLength.pathLength( cyl);
    if  unlikely(!path.first) { 
        LogDebug("RKPropagatorInS")  << "RKPropagatorInS: Path length calculation to cylinder failed!" 
                                     << "Radius " << cyl.radius() << " pos.perp() " << LocalPoint(startState.position()).perp() ;
        return GlobalParametersWithPath();
      }
    
    LogDebug("RKPropagatorInS")  << "RKPropagatorInS: Path lenght to cylinder is " << path.second 
                                 << " from point (R,z) " << startState.position().perp() 
                                 << ", " << startState.position().z()
                                 << " to R " << cyl.radius() 
      ;
    
    
    double sstep = path.second;
    if  unlikely( std::abs(sstep) < eps) {
        LogDebug("RKPropagatorInS")  << "accuracy not reached, but pathLength calculation says we are there! "
                                     << path.second ;
        
        GlobalTrajectoryParameters res( gtpFromLocal( startState.position(), 
                                                      startState.momentum(), 
                                                      ts.charge(), cyl));
        return GlobalParametersWithPath( res, stot);
      }
    
    LogDebug("RKPropagatorInS")  << "RKPropagatorInS: Solving for " << sstep 
                                 << " current distance to cylinder is " << startR ;
    
    RKVector rkresult = solver( 0, start, sstep, deriv, dist, eps);
    stot += sstep;
    CartesianStateAdaptor cur( rkresult);
    double remainingR = cyl.radius() - cur.position().perp();

    if ( fabs(remainingR) < eps) {
      LogDebug("RKPropagatorInS")  << "Accuracy reached! " << remainingR ;
      GlobalTrajectoryParameters res( gtpFromLocal( cur.position(), 
                                                    cur.momentum(), 
                                                    ts.charge(), cyl));
      return GlobalParametersWithPath( res, stot);
    }
    
    start = rkresult;
    if (remainingR * startR > 0) {
      LogDebug("RKPropagatorInS")  << "Accuracy not reached yet, trying in same direction again " 
                                   << remainingR ;
    }
    else {
      LogDebug("RKPropagatorInS")  << "Accuracy not reached yet, trying in opposite direction " 
                                   << remainingR ;
      currentDirection = invertDirection( currentDirection);
    }
    startR = remainingR;
  }
  
  edm::LogError("FailedPropagation") << " too many iterations trying to reach cylinder ";
  return GlobalParametersWithPath();
}
GlobalParametersWithPath RKPropagatorInS::propagateParametersOnPlane ( const FreeTrajectoryState ts,
const Plane plane 
) const [private]

Definition at line 53 of file RKPropagatorInS.cc.

References abs, PV3DBase< T, PVType, FrameType >::basicVector(), FreeTrajectoryState::charge(), cross(), dir, alignCSCRings::e, fieldProvider(), RKLocalFieldProvider::frame(), globalPosition(), gtpFromVolumeLocal(), RKLocalFieldProvider::inTesla(), invertDirection(), likely, Plane::localZ(), LogDebug, FreeTrajectoryState::momentum(), CartesianStateAdaptor::momentum(), getHLTPrescaleColumns::path, StraightLinePlaneCrossing::pathLength(), pos, CartesianStateAdaptor::position(), StraightLinePlaneCrossing::position(), GloballyPositioned< T >::position(), FreeTrajectoryState::position(), Propagator::propagationDirection(), rho, rkMomentum(), rkPosition(), CartesianStateAdaptor::rkstate(), alignCSCRings::s, theTolerance, theVolume, GloballyPositioned< T >::toGlobal(), GloballyPositioned< T >::toLocal(), FrameChanger::transformPlane(), FreeTrajectoryState::transverseCurvature(), unlikely, and x.

Referenced by propagateWithPath().

{

  GlobalPoint gpos( ts.position());
  GlobalVector gmom( ts.momentum());
  double startZ = plane.localZ(gpos);
  // (transverse) curvature
  double rho = ts.transverseCurvature();
  //
  // Straight line approximation? |rho|<1.e-10 equivalent to ~ 1um 
  // difference in transversal position at 10m.
  //
  if  unlikely( fabs(rho)<1.e-10 ) {
    //
    // Instantiate auxiliary object for finding intersection.
    // Frame-independant point and vector are created explicitely to 
    // avoid confusing gcc (refuses to compile with temporary objects
    // in the constructor).
    //
    LogDebug("RKPropagatorInS")<<" startZ = "<<startZ;

    if unlikely(fabs(startZ) < 1e-5){  
      LogDebug("RKPropagatorInS")<< "Propagation is not performed: state is already on final surface.";
      GlobalTrajectoryParameters res( gpos, gmom, ts.charge(), 
                                      theVolume);
      return GlobalParametersWithPath( res, 0.0);
    }

    StraightLinePlaneCrossing::PositionType pos(gpos);
    StraightLinePlaneCrossing::DirectionType dir(gmom);
    StraightLinePlaneCrossing planeCrossing(pos,dir, propagationDirection());
    //
    // get solution
    //
    std::pair<bool,double> propResult = planeCrossing.pathLength(plane);
    if likely( propResult.first && theVolume !=0) {
      double s = propResult.second;
      // point (reconverted to GlobalPoint)
      GlobalPoint x (planeCrossing.position(s));
      GlobalTrajectoryParameters res( x, gmom, ts.charge(), theVolume);
      return GlobalParametersWithPath( res, s);
      }
    //do someting
    LogDebug("RKPropagatorInS")<< "Straight line propgation to plane failed !!"; 
    return GlobalParametersWithPath( );

  }


#ifdef EDM_LM_DEBUG
  if (theVolume != 0) {
    LogDebug("RKPropagatorInS")  << "RKPropagatorInS: starting prop to plane in volume with pos " << theVolume->position()
              << " Z axis " << theVolume->toGlobal( LocalVector(0,0,1)) ;

    LogDebug("RKPropagatorInS")  << "The starting position is " << ts.position() << " (global) "
              << theVolume->toLocal(ts.position()) << " (local) " ;
  
    FrameChanger changer;
    FrameChanger::PlanePtr localPlane = changer.transformPlane( plane, *theVolume);
    LogDebug("RKPropagatorInS")  << "The plane position is " << plane.position() << " (global) "
              << localPlane->position() << " (local) " ;

    LogDebug("RKPropagatorInS")  << "The initial distance to plane is " << plane.localZ( ts.position()) ;

    StraightLinePlaneCrossing cross( ts.position().basicVector(), ts.momentum().basicVector());
    std::pair<bool,double> res3 = cross.pathLength(plane);
    LogDebug("RKPropagatorInS")  << "straight line distance " << res3.first << " " << res3.second ;
  }
#endif

  typedef RKAdaptiveSolver<double,RKOneCashKarpStep, 6>   Solver;
  typedef Solver::Vector                                  RKVector;
  
  RKLocalFieldProvider field( fieldProvider());
  PathToPlane2Order pathLength( field, &field.frame());
  CartesianLorentzForce deriv(field, ts.charge());

  RKCartesianDistance dist;
  double eps = theTolerance;
  Solver solver;
  double stot = 0;
  PropagationDirection currentDirection = propagationDirection();

  // in magVolume frame
  RKVector start( CartesianStateAdaptor::rkstate( rkPosition(gpos), rkMomentum(gmom)));
  int safeGuard = 0;
  while (safeGuard++<100) {
    CartesianStateAdaptor startState(start);

    std::pair<bool,double> path = pathLength( plane, startState.position(), 
                                              startState.momentum(), 
                                              (double) ts.charge(), currentDirection);
    if  unlikely(!path.first) { 
      LogDebug("RKPropagatorInS")  << "RKPropagatorInS: Path length calculation to plane failed!" 
                                   << "...distance to plane " << plane.localZ( globalPosition(startState.position()))
                                   << "...Local starting position in volume " << startState.position() 
                                   << "...Magnetic field " << field.inTesla( startState.position()) ;


      return GlobalParametersWithPath();
    }

    LogDebug("RKPropagatorInS")  << "RKPropagatorInS: Path lenght to plane is " << path.second ;
   

    double sstep = path.second;
    if  unlikely( std::abs(sstep) < eps) {
      LogDebug("RKPropagatorInS")  << "On-surface accuracy not reached, but pathLength calculation says we are there! "
                 << "path " << path.second << " distance to plane is " << startZ ;
      GlobalTrajectoryParameters res( gtpFromVolumeLocal( startState, ts.charge()));
      return GlobalParametersWithPath( res, stot);
    }

    LogDebug("RKPropagatorInS")  << "RKPropagatorInS: Solving for " << sstep 
              << " current distance to plane is " << startZ ;

    RKVector rkresult = solver( 0, start, sstep, deriv, dist, eps);
    stot += sstep;
    CartesianStateAdaptor cur( rkresult);
    double remainingZ = plane.localZ( globalPosition(cur.position()));

    if ( fabs(remainingZ) < eps) {
      LogDebug("RKPropagatorInS")  << "On-surface accuracy reached! " << remainingZ ;
      GlobalTrajectoryParameters res( gtpFromVolumeLocal( cur, ts.charge()));
      return GlobalParametersWithPath( res, stot);
    }

    start = rkresult;

    if (remainingZ * startZ > 0) {
      LogDebug("RKPropagatorInS")  << "Accuracy not reached yet, trying in same direction again " 
                << remainingZ ;
    }
    else {
      LogDebug("RKPropagatorInS")  << "Accuracy not reached yet, trying in opposite direction " 
                << remainingZ ;
      currentDirection = invertDirection( currentDirection);
    }
    startZ = remainingZ;
  }

  edm::LogError("FailedPropagation") << " too many iterations trying to reach plane ";
  return GlobalParametersWithPath();
}
std::pair< TrajectoryStateOnSurface, double > RKPropagatorInS::propagateWithPath ( const FreeTrajectoryState fts,
const Cylinder cyl 
) const [virtual]
std::pair< TrajectoryStateOnSurface, double > RKPropagatorInS::propagateWithPath ( const FreeTrajectoryState fts,
const Plane plane 
) const [virtual]
Basic3DVector< double > RKPropagatorInS::rkMomentum ( const GlobalVector mom) const [private]
Basic3DVector< double > RKPropagatorInS::rkPosition ( const GlobalPoint pos) const [private]

Member Data Documentation

Definition at line 64 of file RKPropagatorInS.h.

Referenced by propagateParametersOnCylinder(), and propagateParametersOnPlane().