d2/dec/Cons_8cc_source.html

 #include "DetectorDescription/Core/src/Cons.h"

 #include "CLHEP/Units/GlobalSystemOfUnits.h"

 #include "CLHEP/Units/GlobalPhysicalConstants.h"

 #include <cmath>

 #include <ostream>


 DDI::Cons::Cons(double zhalf,

      double rInMinusZ,

      double rOutMinusZ,

      double rInPlusZ,

      double rOutPlusZ,

      double startPhi,

      double deltaPhi)

  : Solid(ddcons)

 {

   p_.push_back(zhalf);

   p_.push_back(rInMinusZ);

   p_.push_back(rOutMinusZ);

   p_.push_back(rInPlusZ);

   p_.push_back(rOutPlusZ);

   p_.push_back(startPhi);

   p_.push_back(deltaPhi);


 }


 void DDI::Cons::stream(std::ostream & os) const

 {

    os << " zhalf=" << p_[0]/cm

       << " rIn-Z=" << p_[1]/cm

       << " rOut-Z=" << p_[2]/cm

       << " rIn+Z=" << p_[3]/cm

       << " rOut+Z=" << p_[4]/cm

       << " startPhi=" << p_[5]/deg

       << " deltaPhi=" << p_[6]/deg;

 }


 double DDI::Cons::volume() const

 {

   /* zhalf is the half length of the cone,

      phiTo is always clockwise rotated from phiFrom

      rInMinusZ is always smaller than rOutMinusZ (same for r*PlusZ)

      They are the distances relative to the rotation axes */


   /* calculation normalize from 0 to z */


   /* The function f=rInMinusZ+((rInPlusZ-rInMinusZ)/z)*x defines

      the radius of the the rotation from 0 to z. Raised to the power

      of 2 integrated on x from 0 to z. Multiplied by pi, gives the

      volume that needs to substracted from the other volume */


   /* f^2=rInMinusZ*rInMinusZ+2*rInMinusZ*((rInPlusZ-rInMinusZ)/z)*x+((rInPlusZ-rInMinusZ)*(rInPlusZ-rInMinusZ)*x*x)/(z*z) */


   /* primitive of f^2 is: rInMinusZ*rInMinusZ*x+rInMinusZ*((rInPlusZ-rInMinusZ)/z)*(x*x)+(rInPlusZ-rInMinusZ)*(rInPlusZ-rInMinusZ)*(x*x*x)/(3*z*z) */


   /*integration from 0 to z yields: pi*( rInMinusZ*rInMinusZ*z+rInMinusZ*(rInPlusZ-rInMinusZ)*z+((rInPlusZ-rInMinusZ)*(rInPlusZ-rInMinusZ)*z)/(3) ) */


    double zhalf=p_[0];

    double rInMinusZ=p_[1];

    double rOutMinusZ=p_[2];

    double rInPlusZ=p_[3];

    double rOutPlusZ=p_[4];

    //double phiFrom=p_[5]/rad;

    double deltaPhi=fabs(p_[6]/rad);

    double z=2*zhalf;


   double volume1=pi*(rInPlusZ*rInPlusZ+rInMinusZ*rInMinusZ+rInMinusZ*rInPlusZ)*z/3;


   double volume2=pi*(rOutPlusZ*rOutPlusZ+rOutMinusZ*rOutMinusZ+rOutMinusZ*rOutPlusZ)*z/3;


   double slice=deltaPhi/(2*pi);

   double volume=slice*(volume2-volume1);


   return volume;


 }


detailsBasic3DVector::z
float float float z
Definition: extBasic3DVector.h:15

pi
const Double_t pi
Definition: trackSplitPlot.h:36

DDI::Cons::Cons
Cons(double zhalf, double rInMinusZ, double rOutMinusZ, double rInPlusZ, double rOutPlusZ, double startPhi, double deltaPhi)
Definition: Cons.cc:7

ddcons
Definition: DDSolidShapes.h:7

Cons.h

SiPixelRawToDigiRegional_cfi.deltaPhi
tuple deltaPhi
Definition: SiPixelRawToDigiRegional_cfi.py:9

DDI::Cons::stream
void stream(std::ostream &) const
Definition: Cons.cc:27

DDI::Cons::volume
double volume() const
Definition: Cons.cc:38

DDI::Solid
Definition: Solid.h:10

DDI::Solid::p_
std::vector< double > p_
Definition: Solid.h:32