G4HelixExplicitEuler.cc

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//
// $Id$
//
//
//  Helix Explicit Euler: x_1 = x_0 + helix(h)
//  with helix(h) being a helix piece of length h
//  most simple approach for solving linear differential equations.
//  Take the current derivative and add it to the current position.
//
//  W.Wander <wwc@mit.edu> 12/09/97 
// -------------------------------------------------------------------
 
#include "G4HelixExplicitEuler.hh"
#include "G4PhysicalConstants.hh"
#include "G4ThreeVector.hh"
 
 
void G4HelixExplicitEuler::Stepper(  const G4double  yInput[7],
                               const G4double*,
                                     G4double Step,
                                     G4double yOut[7],
                                     G4double yErr[])
 
{
 
 //Estimation of the Stepping Angle
 
  G4ThreeVector Bfld;
  MagFieldEvaluate(yInput, Bfld); 
  
  const G4int nvar = 6 ;
  G4int i;
  G4double      yTemp[7], yIn[7] ;
  G4ThreeVector  Bfld_midpoint;
  //  Saving yInput because yInput and yOut can be aliases for same array
        for(i=0;i<nvar;i++) yIn[i]=yInput[i];
     
        G4double h = Step * 0.5;
 
     // Do full step and two half steps
        G4double yTemp2[7];
        AdvanceHelix(yIn,   Bfld,  h, yTemp2,yTemp);
        MagFieldEvaluate(yTemp2, Bfld_midpoint) ;     
        AdvanceHelix(yTemp2, Bfld_midpoint, h, yOut);
    
     // Error estimation
        for(i=0;i<nvar;i++) {
         yErr[i] = yOut[i] - yTemp[i] ;
       }
    
}
 
G4double G4HelixExplicitEuler::DistChord()   const 
{
  // Implementation : must check whether h/R > 2 pi  !!
  //   If( h/R <  pi) use G4LineSection::DistLine
  //   Else           DistChord=R_helix
  //
  G4double distChord;
  G4double Ang_curve=GetAngCurve();
 
      
     if(Ang_curve<=pi){
       distChord=GetRadHelix()*(1-std::cos(0.5*Ang_curve));
     }
         else 
         if(Ang_curve<twopi){
           distChord=GetRadHelix()*(1+std::cos(0.5*(twopi-Ang_curve)));
         }
         else{
          distChord=2.*GetRadHelix();  
         }
 
  return distChord;
  
}
void
G4HelixExplicitEuler::DumbStepper( const G4double  yIn[],
                   G4ThreeVector   Bfld,
                   G4double        h,
                   G4double        yOut[])
{
    
       AdvanceHelix(yIn, Bfld, h, yOut);
               
}