CMS 3D CMS Logo

EnergyLossSimulator.cc
Go to the documentation of this file.
2 //#include "FastSimulation/Utilities/interface/RandomEngine.h"
4 
5 #include <cmath>
6 
7 EnergyLossSimulator::EnergyLossSimulator(double A, double Z, double density, double radLen) :
8  MaterialEffectsSimulator(A,Z,density,radLen)
9 {
11 }
12 
14 
15  delete theGenerator;
16 
17 }
18 
19 void
21 {
22 
23  // FamosHistos* myHistos = FamosHistos::instance();
24 
25  // double gamma_e = 0.577215664901532861; // Euler constant
26 
27  // The thickness in cm
28  double thick = radLengths * radLenIncm();
29 
30  // This is a simple version (a la PDG) of a dE/dx generator.
31  // It replaces the buggy GEANT3 -> C++ former version.
32  // Author : Patrick Janot - 8-Jan-2004
33 
34  double p2 = Particle.Vect().Mag2();
35  double verySmallP2 = 0.0001;
36  if (p2<=verySmallP2) {
37  deltaP.SetXYZT(0.,0.,0.,0.);
38  return;
39  }
40  double m2 = Particle.mass() * Particle.mass();
41  double e2 = p2+m2;
42 
43  double beta2 = p2/e2;
44  double gama2 = e2/m2;
45 
46  double charge2 = Particle.charge() * Particle.charge();
47 
48  // Energy loss spread in GeV
49  double eSpread = 0.1536E-3*charge2*(theZ()/theA())*rho()*thick/beta2;
50 
51  // Most probable energy loss (from the integrated Bethe-Bloch equation)
52  mostProbableLoss = eSpread * ( log ( 2.*eMass()*beta2*gama2*eSpread
53  / (excitE()*excitE()) )
54  - beta2 + 0.200 );
55 
56  // This one can be needed on output (but is not used internally)
57  // meanEnergyLoss = 2.*eSpread * ( log ( 2.*eMass()*beta2*gama2 /excitE() ) - beta2 );
58 
59  // Generate the energy loss with Landau fluctuations
60  double dedx = mostProbableLoss + eSpread * theGenerator->landau(random);
61 
62  // Compute the new energy and momentum
63  double aBitAboveMass = Particle.mass()*1.0001;
64  double newE = std::max(aBitAboveMass,Particle.e()-dedx);
65  // double newE = std::max(Particle.mass(),Particle.e()-dedx);
66  double fac = std::sqrt((newE*newE-m2)/p2);
67 
68 
69  // Update the momentum
70  deltaP.SetXYZT(Particle.Px()*(1.-fac),Particle.Py()*(1.-fac),
71  Particle.Pz()*(1.-fac),Particle.E()-newE);
72  Particle.SetXYZT(Particle.Px()*fac,Particle.Py()*fac,
73  Particle.Pz()*fac,newE);
74 
75 }
76 
const double Z[kNumberCalorimeter]
double rho() const
Density in g/cm3.
TRandom random
Definition: MVATrainer.cc:138
double mass() const
get the MEASURED mass
Definition: RawParticle.h:283
double mostProbableLoss
The most probable enery loss.
T sqrt(T t)
Definition: SSEVec.h:18
void compute(ParticlePropagator &Particle, RandomEngineAndDistribution const *)
The real dE/dx generation and particle update.
double eMass() const
Electron mass in GeV/c2.
double charge() const
get the MEASURED charge
Definition: RawParticle.h:282
double p2[4]
Definition: TauolaWrapper.h:90
~EnergyLossSimulator()
Default Destructor.
LandauFluctuationGenerator * theGenerator
The Landau Fluctuation generator.
double landau(RandomEngineAndDistribution const *random) const
Random generator of the dE/dX spread (Landau function)
EnergyLossSimulator(double A, double Z, double density, double radLen)
Constructor.
double excitE() const
Mean excitation energy (in GeV)
Float e2
Definition: deltaR.h:21
double radLenIncm() const
One radiation length in cm.
XYZTLorentzVector deltaP
The actual energy loss.