#include <G4GaussJacobiQ.hh>

Inheritance diagram for G4GaussJacobiQ:

Public Member Functions
	G4GaussJacobiQ (function pFunction, G4double alpha, G4double beta, G4int nJacobi)

	G4GaussJacobiQ (const G4GaussJacobiQ &)=delete

G4GaussJacobiQ &	operator= (const G4GaussJacobiQ &)=delete

G4double	Integral () const

Public Member Functions inherited from G4VGaussianQuadrature
	G4VGaussianQuadrature (function pFunction)

virtual	~G4VGaussianQuadrature ()

	G4VGaussianQuadrature (const G4VGaussianQuadrature &)=delete

G4VGaussianQuadrature &	operator= (const G4VGaussianQuadrature &)=delete

G4double	GetAbscissa (G4int index) const

G4double	GetWeight (G4int index) const

G4int	GetNumber () const

Additional Inherited Members
Protected Member Functions inherited from G4VGaussianQuadrature
G4double	GammaLogarithm (G4double xx)

Protected Attributes inherited from G4VGaussianQuadrature
function	fFunction

G4double *	fAbscissa = nullptr

G4double *	fWeight = nullptr

G4int	fNumber = 0

Detailed Description

Definition at line 43 of file G4GaussJacobiQ.hh.

Constructor & Destructor Documentation

◆ G4GaussJacobiQ() [1/2]

G4GaussJacobiQ::G4GaussJacobiQ	(	function	pFunction,
		G4double	alpha,
		G4double	beta,
		G4int	nJacobi )

Definition at line 38 of file G4GaussJacobiQ.cc.

  : G4VGaussianQuadrature(pFunction)
 
{
  const G4double tolerance = 1.0e-12;
  const G4double maxNumber = 12;
  G4int i = 1, k = 1;
  G4double root      = 0.;
  G4double alphaBeta = 0.0, alphaReduced = 0.0, betaReduced = 0.0, root1 = 0.0,
           root2 = 0.0, root3 = 0.0;
  G4double a = 0.0, b = 0.0, c = 0.0, newton1 = 0.0, newton2 = 0.0,
           newton3 = 0.0, newton0 = 0.0, temp = 0.0, rootTemp = 0.0;
 
  fNumber   = nJacobi;
  fAbscissa = new G4double[fNumber];
  fWeight   = new G4double[fNumber];
 
  for(i = 1; i <= nJacobi; ++i)
  {
    if(i == 1)
    {
      alphaReduced = alpha / nJacobi;
      betaReduced  = beta / nJacobi;
      root1        = (1.0 + alpha) * (2.78002 / (4.0 + nJacobi * nJacobi) +
                               0.767999 * alphaReduced / nJacobi);
      root2        = 1.0 + 1.48 * alphaReduced + 0.96002 * betaReduced +
              0.451998 * alphaReduced * alphaReduced +
              0.83001 * alphaReduced * betaReduced;
      root = 1.0 - root1 / root2;
    }
    else if(i == 2)
    {
      root1 = (4.1002 + alpha) / ((1.0 + alpha) * (1.0 + 0.155998 * alpha));
      root2 = 1.0 + 0.06 * (nJacobi - 8.0) * (1.0 + 0.12 * alpha) / nJacobi;
      root3 =
        1.0 + 0.012002 * beta * (1.0 + 0.24997 * std::fabs(alpha)) / nJacobi;
      root -= (1.0 - root) * root1 * root2 * root3;
    }
    else if(i == 3)
    {
      root1 = (1.67001 + 0.27998 * alpha) / (1.0 + 0.37002 * alpha);
      root2 = 1.0 + 0.22 * (nJacobi - 8.0) / nJacobi;
      root3 = 1.0 + 8.0 * beta / ((6.28001 + beta) * nJacobi * nJacobi);
      root -= (fAbscissa[0] - root) * root1 * root2 * root3;
    }
    else if(i == nJacobi - 1)
    {
      root1 = (1.0 + 0.235002 * beta) / (0.766001 + 0.118998 * beta);
      root2 = 1.0 / (1.0 + 0.639002 * (nJacobi - 4.0) /
                             (1.0 + 0.71001 * (nJacobi - 4.0)));
      root3 = 1.0 / (1.0 + 20.0 * alpha / ((7.5 + alpha) * nJacobi * nJacobi));
      root += (root - fAbscissa[nJacobi - 4]) * root1 * root2 * root3;
    }
    else if(i == nJacobi)
    {
      root1 = (1.0 + 0.37002 * beta) / (1.67001 + 0.27998 * beta);
      root2 = 1.0 / (1.0 + 0.22 * (nJacobi - 8.0) / nJacobi);
      root3 =
        1.0 / (1.0 + 8.0 * alpha / ((6.28002 + alpha) * nJacobi * nJacobi));
      root += (root - fAbscissa[nJacobi - 3]) * root1 * root2 * root3;
    }
    else
    {
      root = 3.0 * fAbscissa[i - 2] - 3.0 * fAbscissa[i - 3] + fAbscissa[i - 4];
    }
    alphaBeta = alpha + beta;
    for(k = 1; k <= maxNumber; ++k)
    {
      temp    = 2.0 + alphaBeta;
      newton1 = (alpha - beta + temp * root) / 2.0;
      newton2 = 1.0;
      for(G4int j = 2; j <= nJacobi; ++j)
      {
        newton3 = newton2;
        newton2 = newton1;
        temp    = 2 * j + alphaBeta;
        a       = 2 * j * (j + alphaBeta) * (temp - 2.0);
        b       = (temp - 1.0) *
            (alpha * alpha - beta * beta + temp * (temp - 2.0) * root);
        c       = 2.0 * (j - 1 + alpha) * (j - 1 + beta) * temp;
        newton1 = (b * newton2 - c * newton3) / a;
      }
      newton0 = (nJacobi * (alpha - beta - temp * root) * newton1 +
                 2.0 * (nJacobi + alpha) * (nJacobi + beta) * newton2) /
                (temp * (1.0 - root * root));
      rootTemp = root;
      root     = rootTemp - newton1 / newton0;
      if(std::fabs(root - rootTemp) <= tolerance)
      {
        break;
      }
    }
    if(k > maxNumber)
    {
      G4Exception("G4GaussJacobiQ::G4GaussJacobiQ()", "OutOfRange",
                  FatalException, "Too many iterations in constructor.");
    }
    fAbscissa[i - 1] = root;
    fWeight[i - 1] =
      std::exp(GammaLogarithm((G4double)(alpha + nJacobi)) +
               GammaLogarithm((G4double)(beta + nJacobi)) -
               GammaLogarithm((G4double)(nJacobi + 1.0)) -
               GammaLogarithm((G4double)(nJacobi + alphaBeta + 1.0))) *
      temp * std::pow(2.0, alphaBeta) / (newton0 * newton2);
  }
}

◆ G4GaussJacobiQ() [2/2]

G4GaussJacobiQ::G4GaussJacobiQ ( const G4GaussJacobiQ & )

delete

Member Function Documentation

◆ Integral()

G4double G4GaussJacobiQ::Integral ( ) const

Definition at line 152 of file G4GaussJacobiQ.cc.

{
  G4double integral = 0.0;
  for(G4int i = 0; i < fNumber; ++i)
  {
    integral += fWeight[i] * fFunction(fAbscissa[i]);
  }
  return integral;
}

◆ operator=()

G4GaussJacobiQ & G4GaussJacobiQ::operator= ( const G4GaussJacobiQ & )