G4DNACPA100LogLogInterpolation Class Reference

#include <G4DNACPA100LogLogInterpolation.hh>

Inheritance diagram for G4DNACPA100LogLogInterpolation:

Public Member Functions
G4double	Calculate (G4double point, G4int bin, const G4DataVector &energies, const G4DataVector &data) const
G4double	Calculate (G4double point, G4int bin, const G4DataVector &energies, const G4DataVector &data, const G4DataVector &log_energies, const G4DataVector &log_data) const
virtual G4VDataSetAlgorithm *	Clone () const
	G4DNACPA100LogLogInterpolation ()
	~G4DNACPA100LogLogInterpolation ()

Detailed Description

Definition at line 46 of file G4DNACPA100LogLogInterpolation.hh.

Constructor & Destructor Documentation

G4DNACPA100LogLogInterpolation()

G4DNACPA100LogLogInterpolation::G4DNACPA100LogLogInterpolation

(

)

Definition at line 43 of file G4DNACPA100LogLogInterpolation.cc.

{ }

Referenced by Clone().

~G4DNACPA100LogLogInterpolation()

G4DNACPA100LogLogInterpolation::~G4DNACPA100LogLogInterpolation

(

)

Definition at line 48 of file G4DNACPA100LogLogInterpolation.cc.

{ }

Member Function Documentation

Calculate() [1/2]

G4double G4DNACPA100LogLogInterpolation::Calculate ( G4double  point, G4int  bin, const G4DataVector &  energies, const G4DataVector &  data  ) const

virtual

Implements G4VDataSetAlgorithm.

Definition at line 55 of file G4DNACPA100LogLogInterpolation.cc.

{
  //G4cout << "G4DNACPA100LogLogInterpolation is performed (2 arguments) " << G4endl;
  G4int nBins = data.size() - 1;
//G4double oldresult = 0.;
  G4double value = 0.;
  if (x < points[0])
    {
      value = 0.;
    }
  else if (bin < nBins)
    {
      G4double e1 = points[bin];
      G4double e2 = points[bin+1];
      G4double d1 = data[bin];
      G4double d2 = data[bin+1];
// Check of e1, e2, d1 and d2 values to avoid floating-point errors when estimating the interpolated value below -- S.I., Jun. 2008
      if ((d1 > 0.) && (d2 > 0.) && (e1 > 0.) && (e2 > 0.))
        {
// Streamline the Log-Log Interpolation formula in order to reduce the required number of log10() function calls
// Variable oldresult contains the result of old implementation of Log-Log interpolation -- M.G.P. Jun. 2001
//       oldresult = (std::log10(d1)*std::log10(e2/x) + std::log10(d2)*std::log10(x/e1)) / std::log10(e2/e1);
//       oldresult = std::pow(10.,oldresult);
// Variable value contains the result of new implementation, after streamlining the math operation -- N.A.K. Oct. 2008
         value = std::log10(d1)+(std::log10(d2/d1)/std::log10(e2/e1)*std::log10(x/e1));
         value = std::pow(10.,value);
// Test of the new implementation result (value variable) against the old one (oldresult) -- N.A.K. Dec. 2008
//       G4double diffResult = value - oldresult;
//       G4double relativeDiff = 1e-11;
// Comparison of the two values based on a max allowable relative difference
//       if ( std::fabs(diffResult) > relativeDiff*std::fabs(oldresult) )
//        {
// Abort comparison when at least one of two results is infinite
//           if ((!std::isinf(oldresult)) && (!std::isinf(value)))
//            {
//              G4cout << "G4DNACPA100LogLogInterpolation> Old Interpolated Value is:" << oldresult << G4endl;
//              G4cout << "G4DNACPA100LogLogInterpolation> New Interpolated Value is:" << value << G4endl << G4endl;
//              G4cerr << "G4DNACPA100LogLogInterpolation> Error in Interpolation:" << G4endl;
//              G4cerr << "The difference between new and old interpolated value is:" << diffResult << G4endl << G4endl;
//            }
//        }
        }
      else value = 0.;
    }
  else
    {
      value = data[nBins];
    }
  return value;
}

References d1, d2, e1, and e2.

Calculate() [2/2]

G4double G4DNACPA100LogLogInterpolation::Calculate ( G4double  point, G4int  bin, const G4DataVector &  energies, const G4DataVector &  data, const G4DataVector &  log_energies, const G4DataVector &  log_data  ) const

virtual

Implements G4VDataSetAlgorithm.

Definition at line 112 of file G4DNACPA100LogLogInterpolation.cc.

{
  G4int nBins = data.size() - 1;
  G4double value = 0.;
  G4double log_x = std::log10(x);
  if (x < points[0])
    {
      value = 0.;
    }
  else if (bin < nBins)
    {
      G4double log_e1 = log_points[bin];
      //G4double log_e2 = log_points[bin+1];
      G4double log_d1 = log_data[bin];
      G4double log_d2 = log_data[bin+1];
      
      //G4cout << "x = " << x << " , logx = " << log_x  << " , bin = " << bin << G4endl; 
      //G4cout << "e1 = " << points[bin] << " d1 = " << data[bin] << G4endl;
      //G4cout << "e2 = " << points[bin+1] << " d2 = " << data[bin+1] << G4endl;
      //G4cout << "loge1 = " << log_e1 << " logd1 = " << log_d1 << G4endl;
      //G4cout << "loge2 = " << log_e2 << " logd2 = " << log_d2 << G4endl;
      //G4cout << "interpol " << log_d1 + (log_d2 - log_d1)*(log_x - log_e1)/(log_e2 - log_e1) << " " << G4endl;
 
 
      // Values e1, e2, d1 and d2 are the log values of the corresponding
      // original energy and data values. Simple linear interpolation performed
      // on loagarithmic data should be equivalent to log-log interpolation
 
      // CPA100 specific
       //value = log_d1 + (log_d2 - log_d1)*(log_x - log_e1)/(log_e2 - log_e1);
      // value = log_d1;
 
       value = log_d2; // UPPER VALUE INTERPOLATION
       if (log_x == log_e1) value = log_d1; // IN CASE OF EQUALITY
 
// Delogarithmize to obtain interpolated value
      value = std::pow(10.,value);
   }
 else
   {
     value = data[nBins];
   }
   
  return value;
}

Clone()

G4VDataSetAlgorithm * G4DNACPA100LogLogInterpolation::Clone ( ) const

virtual

Implements G4VDataSetAlgorithm.

Definition at line 51 of file G4DNACPA100LogLogInterpolation.cc.

{ return new G4DNACPA100LogLogInterpolation; }

References G4DNACPA100LogLogInterpolation().

---

The documentation for this class was generated from the following files:

• source/processes/electromagnetic/dna/utils/include/G4DNACPA100LogLogInterpolation.hh
• source/processes/electromagnetic/dna/utils/src/G4DNACPA100LogLogInterpolation.cc