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AnalyticalTrajectoryExtrapolatorToLine Class Reference

#include <AnalyticalTrajectoryExtrapolatorToLine.h>

List of all members.

Public Member Functions

 AnalyticalTrajectoryExtrapolatorToLine (const MagneticField *field)
 constructor with default geometrical propagator
 AnalyticalTrajectoryExtrapolatorToLine (const Propagator &)
 constructor with alternative propagator
TrajectoryStateOnSurface extrapolate (const FreeTrajectoryState &fts, const Line &L) const
 extrapolation from FreeTrajectoryState
TrajectoryStateOnSurface extrapolate (const TrajectoryStateOnSurface tsos, const Line &L) const
 extrapolation from TrajectoryStateOnSurface

Private Member Functions

TrajectoryStateOnSurface extrapolateFullState (const TrajectoryStateOnSurface tsos, const Line &line) const dso_internal
 extrapolation of (multi) TSOS
TrajectoryStateOnSurface extrapolateSingleState (const FreeTrajectoryState &fts, const Line &line) const dso_internal
 extrapolation of (single) FTS
bool propagateWithHelix (const IterativeHelixExtrapolatorToLine &extrapolator, const Line &line, GlobalPoint &x, GlobalVector &p, double &s) const dso_internal
 the actual propagation to a new point & momentum vector

Private Attributes

DeepCopyPointerByClone
< Propagator
thePropagator

Detailed Description

Extrapolate to the closest approach w.r.t. a line. This class is faster than the TrajectoryExtrapolatorToLine. The helix model is explicitely used in the determination of the target surface. This target surface is centered on the point of closest approach on the line. The axes of the local coordinate system (x_loc, y_loc, z_loc) are z_loc // trajectory direction at point of closest approach; x_loc normal to trajectory and along impact vector (line->helix); y_loc forms a right-handed system with the other axes.

Definition at line 28 of file AnalyticalTrajectoryExtrapolatorToLine.h.


Constructor & Destructor Documentation

AnalyticalTrajectoryExtrapolatorToLine::AnalyticalTrajectoryExtrapolatorToLine ( const MagneticField field)

constructor with default geometrical propagator

Definition at line 15 of file AnalyticalTrajectoryExtrapolatorToLine.cc.

AnalyticalTrajectoryExtrapolatorToLine::AnalyticalTrajectoryExtrapolatorToLine ( const Propagator propagator)

constructor with alternative propagator

Definition at line 19 of file AnalyticalTrajectoryExtrapolatorToLine.cc.

References anyDirection.

                               : thePropagator(propagator.clone()) 
{
  thePropagator->setPropagationDirection(anyDirection);
}

Member Function Documentation

TrajectoryStateOnSurface AnalyticalTrajectoryExtrapolatorToLine::extrapolate ( const FreeTrajectoryState fts,
const Line L 
) const
TrajectoryStateOnSurface AnalyticalTrajectoryExtrapolatorToLine::extrapolate ( const TrajectoryStateOnSurface  tsos,
const Line L 
) const

extrapolation from TrajectoryStateOnSurface

Definition at line 32 of file AnalyticalTrajectoryExtrapolatorToLine.cc.

References extrapolateFullState(), and TrajectoryStateOnSurface::isValid().

{
  if ( tsos.isValid() )  return extrapolateFullState(tsos,line);
  else  return tsos;
}
TrajectoryStateOnSurface AnalyticalTrajectoryExtrapolatorToLine::extrapolateFullState ( const TrajectoryStateOnSurface  tsos,
const Line line 
) const [private]

extrapolation of (multi) TSOS

Definition at line 40 of file AnalyticalTrajectoryExtrapolatorToLine.cc.

References TrajectoryStateOnSurface::components(), extrapolateSingleState(), TrajectoryStateOnSurface::freeTrajectoryState(), TrajectoryStateOnSurface::isValid(), geometryCSVtoXML::line, TrajectoryStateOnSurface::surface(), and thePropagator.

Referenced by extrapolate().

{
  //
  // first determine IP plane using propagation with (single) FTS
  // could be optimised (will propagate errors even if duplicated below)
  //
  TrajectoryStateOnSurface singleState = 
    extrapolateSingleState(*tsos.freeTrajectoryState(),line);
  if ( !singleState.isValid() || tsos.components().size()==1 )  return singleState;
  //
  // propagate multiTsos to plane found above
  //
  return thePropagator->propagate(tsos,singleState.surface());
}
TrajectoryStateOnSurface AnalyticalTrajectoryExtrapolatorToLine::extrapolateSingleState ( const FreeTrajectoryState fts,
const Line line 
) const [private]

extrapolation of (single) FTS

Definition at line 57 of file AnalyticalTrajectoryExtrapolatorToLine.cc.

References anyDirection, FreeTrajectoryState::charge(), Line::closerPointToLine(), FreeTrajectoryState::curvilinearError(), alignCSCRings::e, FreeTrajectoryState::hasError(), AnalyticalCurvilinearJacobian::jacobian(), PV3DBase< T, PVType, FrameType >::mag(), CurvilinearTrajectoryError::matrix(), FreeTrajectoryState::momentum(), AlCaHLTBitMon_ParallelJobs::p, FreeTrajectoryState::parameters(), PlaneBuilder::plane(), FreeTrajectoryState::position(), GlobalTrajectoryParameters::position(), propagateWithHelix(), rho, makeMuonMisalignmentScenario::rot, alignCSCRings::s, thePropagator, FreeTrajectoryState::transverseCurvature(), and x.

Referenced by extrapolate(), and extrapolateFullState().

{
//   static TimingReport::Item& timer = detailedDetTimer("AnalyticalTrajectoryExtrapolatorToLine");
//   TimeMe t(timer,false);
  //
  // initialisation of position, momentum and transverse curvature
  //
  GlobalPoint x(fts.position());
  GlobalVector p(fts.momentum());
  double rho = fts.transverseCurvature();
  //
  // Straight line approximation? |rho|<1.e-10 equivalent to ~ 1um 
  // difference in transversal position at 10m.
  //
  double s(0);
  if( fabs(rho)<1.e-10 ) {
    Line tangent(x,p);
    GlobalPoint xold(x);
    x = tangent.closerPointToLine(line);
    GlobalVector dx(x-xold);
    float sign = p.dot(x-xold);
    s = sign>0 ? dx.mag() : -dx.mag();
  }
  //
  // Helix case 
  //
  else {
    HelixLineExtrapolation::PositionType helixPos(x);
    HelixLineExtrapolation::DirectionType helixDir(p);
    IterativeHelixExtrapolatorToLine extrapolator(helixPos,helixDir,rho,anyDirection);
    if ( !propagateWithHelix(extrapolator,line,x,p,s) )  return TrajectoryStateOnSurface();
  }
  //
  // Define target surface: origin on line, x_local from line 
  //   to helix at closest approach, z_local along the helix
  //   and y_local to complete right-handed system
  //
  GlobalPoint origin(line.closerPointToLine(Line(x,p)));
  GlobalVector zLocal(p.unit());
  GlobalVector yLocal(zLocal.cross(x-origin).unit());
  GlobalVector xLocal(yLocal.cross(zLocal));
  Surface::RotationType rot(xLocal,yLocal,zLocal);
  PlaneBuilder::ReturnType surface = PlaneBuilder().plane(origin,rot);
  //
  // Compute propagated state
  //
  GlobalTrajectoryParameters gtp(x,p,fts.charge(), thePropagator->magneticField());
  if (fts.hasError()) {
    //
    // compute jacobian
    //
    AnalyticalCurvilinearJacobian analyticalJacobian(fts.parameters(), gtp.position(), gtp.momentum(), s);
    const AlgebraicMatrix55 &jacobian = analyticalJacobian.jacobian();
    CurvilinearTrajectoryError cte( ROOT::Math::Similarity (jacobian, fts.curvilinearError().matrix()) );
    return TrajectoryStateOnSurface(gtp,cte,*surface);
  }
  else {
    //
    // return state without errors
    //
    return TrajectoryStateOnSurface(gtp,*surface);
  }
}
bool AnalyticalTrajectoryExtrapolatorToLine::propagateWithHelix ( const IterativeHelixExtrapolatorToLine extrapolator,
const Line line,
GlobalPoint x,
GlobalVector p,
double &  s 
) const [private]

the actual propagation to a new point & momentum vector

Definition at line 123 of file AnalyticalTrajectoryExtrapolatorToLine.cc.

References IterativeHelixExtrapolatorToLine::direction(), PV3DBase< T, PVType, FrameType >::mag(), Basic3DVector< T >::mag(), IterativeHelixExtrapolatorToLine::pathLength(), and IterativeHelixExtrapolatorToLine::position().

Referenced by extrapolateSingleState().

                                                                                                              {
  //
  // save absolute value of momentum
  //
  double pmag(p.mag());
  //
  // get path length to solution
  //
  std::pair<bool,double> propResult = extrapolator.pathLength(line);
  if ( !propResult.first )  return false;
  s = propResult.second;
  // 
  // get point and (normalised) direction from path length
  //
  HelixLineExtrapolation::PositionType xGen = extrapolator.position(s);
  HelixLineExtrapolation::DirectionType pGen = extrapolator.direction(s);
  //
  // Fix normalisation and convert back to GlobalPoint / GlobalVector
  //
  x = GlobalPoint(xGen);
  pGen *= pmag/pGen.mag();
  p = GlobalVector(pGen);
  //
  return true;
}

Member Data Documentation