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

HelixBarrelCylinderCrossing Class Reference

#include <HelixBarrelCylinderCrossing.h>

List of all members.

Public Types

typedef GlobalVector DirectionType
typedef GlobalPoint PositionType

Public Member Functions

DirectionType direction () const
bool hasSolution () const
 HelixBarrelCylinderCrossing (const GlobalPoint &startingPos, const GlobalVector &startingDir, double rho, PropagationDirection propDir, const Cylinder &cyl)
double pathLength () const
PositionType position () const
PositionType position1 () const
 Method to access separately each solution of the helix-cylinder crossing equations.
PositionType position2 () const
 Method to access separately each solution of the helix-cylinder crossing equations.

Private Types

typedef Basic2DVector< TmpTypePoint
typedef double TmpType
typedef Basic2DVector< TmpTypeVector

Private Member Functions

void chooseSolution (const Point &p1, const Point &p2, const PositionType &startingPos, const DirectionType &startingDir, PropagationDirection propDir) dso_internal

Private Attributes

int theActualDir
Vector theD
DirectionType theDir
PositionType thePos
PositionType thePos1
PositionType thePos2
double theS
bool theSolExists

Detailed Description

Calculates the crossing of a helix with a barrel cylinder.

Definition at line 16 of file HelixBarrelCylinderCrossing.h.


Member Typedef Documentation

Definition at line 25 of file HelixBarrelCylinderCrossing.h.

Definition at line 19 of file HelixBarrelCylinderCrossing.h.

Definition at line 24 of file HelixBarrelCylinderCrossing.h.

typedef double HelixBarrelCylinderCrossing::TmpType [private]

Definition at line 18 of file HelixBarrelCylinderCrossing.h.

Definition at line 20 of file HelixBarrelCylinderCrossing.h.


Constructor & Destructor Documentation

HelixBarrelCylinderCrossing::HelixBarrelCylinderCrossing ( const GlobalPoint startingPos,
const GlobalVector startingDir,
double  rho,
PropagationDirection  propDir,
const Cylinder cyl 
)

Definition at line 14 of file HelixBarrelCylinderCrossing.cc.

References abs, alongMomentum, funct::C, chooseSolution(), Vispa::Plugins::EdmBrowser::EdmDataAccessor::eq(), F(), RealQuadEquation::first, RealQuadEquation::hasSolution, Basic2DVector< T >::mag(), PV3DBase< T, PVType, FrameType >::mag(), p2, StraightLineCylinderCrossing::pathLength(), PV3DBase< T, PVType, FrameType >::perp(), PV3DBase< T, PVType, FrameType >::perp2(), dttmaxenums::R, Cylinder::radius(), rho, RealQuadEquation::second, mathSSE::sqrt(), theActualDir, theD, theDir, thePos, thePos1, thePos2, theS, theSolExists, tmp, Surface::toGlobal(), GloballyPositioned< T >::toLocal(), PV3DBase< T, PVType, FrameType >::x(), Basic2DVector< T >::x(), PV3DBase< T, PVType, FrameType >::y(), Basic2DVector< T >::y(), and PV3DBase< T, PVType, FrameType >::z().

{
  // assumes the cylinder is centered at 0,0
  double R = cyl.radius();

  // protect for zero curvature case
  const double sraightLineCutoff = 1.e-7;
  if (fabs(rho)*R < sraightLineCutoff && 
      fabs(rho)*startingPos.perp()  < sraightLineCutoff) {
    // switch to straight line case
    StraightLineCylinderCrossing slc( cyl.toLocal(startingPos), 
                                      cyl.toLocal(startingDir), propDir);
    std::pair<bool,double> pl = slc.pathLength( cyl);
    if (pl.first) {
      theSolExists = true;
      theS = pl.second;
      thePos = cyl.toGlobal(slc.position(theS));
      theDir = startingDir;
    }
    else theSolExists = false;
    return; // all needed data members have been set
  }

  double R2cyl = R*R;
  double pt   = startingDir.perp();
  Point center( startingPos.x()-startingDir.y()/(pt*rho),
                startingPos.y()+startingDir.x()/(pt*rho));
  double p2 = startingPos.perp2();
  bool solveForX;
  double B, C, E, F;
  if (fabs(center.x()) > fabs(center.y())) {
    solveForX = false;
    E = (R2cyl - p2) / (2.*center.x());
    F = center.y()/center.x();
    B = 2.*( startingPos.y() - F*startingPos.x() - E*F);
    C = 2.*E*startingPos.x() + E*E + p2 - R2cyl;
  }
  else {
    solveForX = true;
    E = (R2cyl - p2) / (2.*center.y());
    F = center.x()/center.y();
    B = 2.*( startingPos.x() - F*startingPos.y() - E*F);
    C = 2.*E*startingPos.y() + E*E + p2 - R2cyl;
  }

  RealQuadEquation eq( 1+F*F, B, C);
  if (!eq.hasSolution) {
    theSolExists = false;
    return;
  }

  Vector d1, d2;;
  if (solveForX) {
    d1 = Point(eq.first,  E-F*eq.first);
    d2 = Point(eq.second, E-F*eq.second);
  }
  else {
    d1 = Point( E-F*eq.first,  eq.first);
    d2 = Point( E-F*eq.second, eq.second);
  }
  
  chooseSolution(d1, d2, startingPos, startingDir, propDir);
  if (!theSolExists) return;

  double ipabs = 1./startingDir.mag();
  double sinTheta = pt * ipabs;
  double cosTheta = startingDir.z() * ipabs;


  //-----  BM  
  //double momProj1 = startingDir.x()*d1.x() + startingDir.y()*d1.y();
  //double momProj2 = startingDir.x()*d2.x() + startingDir.y()*d2.y();

 
  int theActualDir1 = propDir==alongMomentum ? 1 : -1;
  int theActualDir2 = propDir==alongMomentum ? 1 : -1;


  double dMag1 = d1.mag();
  double tmp1 = 0.5 * dMag1 * rho;
  if (std::abs(tmp1)>1.) tmp1 = ::copysign(1.,tmp1);
  double theS1 = theActualDir1 * 2.* asin( tmp1 ) / (rho*sinTheta);
  thePos1 =  GlobalPoint( startingPos.x() + d1.x(),
                          startingPos.y() + d1.y(),
                          startingPos.z() + theS1*cosTheta);


  double dMag2 = d2.mag();
  double tmp2 = 0.5 * dMag2 * rho;
  if (std::abs(tmp2)>1.) tmp2 = ::copysign(1.,tmp2);
  double theS2 = theActualDir2 * 2.* asin( tmp2 ) / (rho*sinTheta);
  thePos2 =  GlobalPoint( startingPos.x() + d2.x(),
                          startingPos.y() + d2.y(),
                          startingPos.z() + theS2*cosTheta);    
  // -------

  double dMag = theD.mag();
  double tmp = 0.5 * dMag * rho;
  if (std::abs(tmp)>1.) tmp = ::copysign(1.,tmp);
  theS = theActualDir * 2.* asin( tmp ) / (rho*sinTheta);
  thePos =  GlobalPoint( startingPos.x() + theD.x(),
                         startingPos.y() + theD.y(),
                         startingPos.z() + theS*cosTheta);

  if (theS < 0) tmp = -tmp;
  double sinPhi = 2.*tmp*sqrt(1.-tmp*tmp);
  double cosPhi = 1.-2.*tmp*tmp;
  theDir = DirectionType(startingDir.x()*cosPhi-startingDir.y()*sinPhi,
                         startingDir.x()*sinPhi+startingDir.y()*cosPhi,
                         startingDir.z());
}

Member Function Documentation

void HelixBarrelCylinderCrossing::chooseSolution ( const Point p1,
const Point p2,
const PositionType startingPos,
const DirectionType startingDir,
PropagationDirection  propDir 
) [private]

Definition at line 129 of file HelixBarrelCylinderCrossing.cc.

References alongMomentum, anyDirection, Basic2DVector< T >::mag2(), theActualDir, theD, theSolExists, PV3DBase< T, PVType, FrameType >::x(), Basic2DVector< T >::x(), PV3DBase< T, PVType, FrameType >::y(), and Basic2DVector< T >::y().

Referenced by HelixBarrelCylinderCrossing().

{
  double momProj1 = startingDir.x()*d1.x() + startingDir.y()*d1.y();
  double momProj2 = startingDir.x()*d2.x() + startingDir.y()*d2.y();

  if ( propDir == anyDirection ) {
    theSolExists = true;
    if (d1.mag2()<d2.mag2()) {
      theD = d1;
      theActualDir = (momProj1 > 0) ? 1 : -1;
    }
    else {
      theD = d2;
      theActualDir = (momProj2 > 0) ? 1 : -1;
    }
  }
  else {
    int propSign = propDir==alongMomentum ? 1 : -1;
    if (momProj1*momProj2 < 0) {
      // if different signs return the positive one
      theSolExists = true;
      theD = (momProj1*propSign > 0) ? d1 : d2;
      theActualDir = propSign;
    }
    else if (momProj1*propSign > 0) {
      // if both positive, return the shortest
      theSolExists = true;
      theD = (d1.mag2()<d2.mag2()) ? d1 : d2;
      theActualDir = propSign;
    }
    else theSolExists = false;
  }
}
DirectionType HelixBarrelCylinderCrossing::direction ( ) const [inline]

Returns the direction along the helix that corresponds to path length "s" from the starting point. As for position, the direction of the crossing with a cylinder (if it exists!) is given by direction( pathLength( cylinder)).

Definition at line 60 of file HelixBarrelCylinderCrossing.h.

References theDir.

{ return theDir;}
bool HelixBarrelCylinderCrossing::hasSolution ( ) const [inline]

Definition at line 32 of file HelixBarrelCylinderCrossing.h.

References theSolExists.

{ return theSolExists;}
double HelixBarrelCylinderCrossing::pathLength ( ) const [inline]

Propagation status (true if valid) and (signed) path length along the helix from the starting point to the cylinder. The starting point and the cylinder are given in the constructor.

Definition at line 38 of file HelixBarrelCylinderCrossing.h.

References theS.

Referenced by AnalyticalPropagator::propagateParametersOnCylinder().

{ return theS;}
PositionType HelixBarrelCylinderCrossing::position ( void  ) const [inline]

Returns the position along the helix that corresponds to path length "s" from the starting point. If s is obtained from the pathLength method the position is the destination point, i.e. the position of the crossing with a cylinder (if it exists!) is given by position( pathLength( cylinder)).

Definition at line 46 of file HelixBarrelCylinderCrossing.h.

References thePos.

{ return thePos;}
PositionType HelixBarrelCylinderCrossing::position1 ( ) const [inline]

Method to access separately each solution of the helix-cylinder crossing equations.

Definition at line 49 of file HelixBarrelCylinderCrossing.h.

References thePos1.

{ return thePos1;}
PositionType HelixBarrelCylinderCrossing::position2 ( ) const [inline]

Method to access separately each solution of the helix-cylinder crossing equations.

Definition at line 52 of file HelixBarrelCylinderCrossing.h.

References thePos2.

{ return thePos2;}

Member Data Documentation

Definition at line 69 of file HelixBarrelCylinderCrossing.h.

Referenced by chooseSolution(), and HelixBarrelCylinderCrossing().

Definition at line 68 of file HelixBarrelCylinderCrossing.h.

Referenced by chooseSolution(), and HelixBarrelCylinderCrossing().

Definition at line 67 of file HelixBarrelCylinderCrossing.h.

Referenced by direction(), and HelixBarrelCylinderCrossing().

Definition at line 66 of file HelixBarrelCylinderCrossing.h.

Referenced by HelixBarrelCylinderCrossing(), and position().

Definition at line 71 of file HelixBarrelCylinderCrossing.h.

Referenced by HelixBarrelCylinderCrossing(), and position1().

Definition at line 72 of file HelixBarrelCylinderCrossing.h.

Referenced by HelixBarrelCylinderCrossing(), and position2().

Definition at line 65 of file HelixBarrelCylinderCrossing.h.

Referenced by HelixBarrelCylinderCrossing(), and pathLength().