* provided "as is" without express or implied warranty. *
**************************************************************************/
-/*
-$Log$
-Revision 1.7 2000/12/20 13:00:45 cblume
-Modifications for the HP-compiler
-
-Revision 1.6 2000/12/12 10:20:10 cblume
-Initialize fSepctrum = 0 in ctors
-
-Revision 1.5 2000/10/15 23:40:01 cblume
-Remove AliTRDconst
-
-Revision 1.4 2000/10/06 16:49:46 cblume
-Made Getters const
-
-Revision 1.3.2.1 2000/09/18 13:45:30 cblume
-New class AliTRDsim that simulates TR photons
-
-Revision 1.2 1999/09/29 09:24:35 fca
-Introduction of the Copyright and cvs Log
-
-*/
+/* $Id$ */
///////////////////////////////////////////////////////////////////////////////
// //
// 17.07.1998 - A.Andronic //
// 08.12.1998 - simplified version //
// 11.07.2000 - Adapted code to aliroot environment (C.Blume) //
+// 04.06.2004 - Momentum dependent parameters implemented (CBL) //
// //
///////////////////////////////////////////////////////////////////////////////
fSpectrum = 0;
fSigma = 0;
+ fNFoils = 0;
+ fNFoilsUp = 0;
Init();
fSpectrum = 0;
fSigma = 0;
+ fNFoils = 0;
+ fNFoilsUp = 0;
Init();
}
//_____________________________________________________________________________
-AliTRDsim::AliTRDsim(const AliTRDsim &s)
+AliTRDsim::AliTRDsim(const AliTRDsim &s):TObject(s)
{
//
// AliTRDsim copy constructor
// AliTRDsim destructor
//
- if (fSpectrum) delete fSpectrum;
- if (fSigma) delete fSigma;
+ // if (fSpectrum) delete fSpectrum;
+ if (fSigma) delete [] fSigma;
+ if (fNFoils) delete [] fNFoils;
+ if (fNFoilsUp) delete [] fNFoilsUp;
}
// Copy function
//
- ((AliTRDsim &) s).fNFoils = fNFoils;
((AliTRDsim &) s).fFoilThick = fFoilThick;
((AliTRDsim &) s).fFoilDens = fFoilDens;
((AliTRDsim &) s).fFoilOmega = fFoilOmega;
((AliTRDsim &) s).fSpLower = fSpLower;
((AliTRDsim &) s).fSpUpper = fSpUpper;
- if (((AliTRDsim &) s).fSigma) delete ((AliTRDsim &) s).fSigma;
+ if (((AliTRDsim &) s).fNFoils) delete [] ((AliTRDsim &) s).fNFoils;
+ ((AliTRDsim &) s).fNFoils = new Int_t[fNFoilsDim];
+ for (Int_t iFoil = 0; iFoil < fNFoilsDim; iFoil++) {
+ ((AliTRDsim &) s).fNFoils[iFoil] = fNFoils[iFoil];
+ }
+
+ if (((AliTRDsim &) s).fNFoilsUp) delete [] ((AliTRDsim &) s).fNFoilsUp;
+ ((AliTRDsim &) s).fNFoilsUp = new Double_t[fNFoilsDim];
+ for (Int_t iFoil = 0; iFoil < fNFoilsDim; iFoil++) {
+ ((AliTRDsim &) s).fNFoilsUp[iFoil] = fNFoilsUp[iFoil];
+ }
+
+ if (((AliTRDsim &) s).fSigma) delete [] ((AliTRDsim &) s).fSigma;
((AliTRDsim &) s).fSigma = new Double_t[fSpNBins];
for (Int_t iBin = 0; iBin < fSpNBins; iBin++) {
((AliTRDsim &) s).fSigma[iBin] = fSigma[iBin];
{
//
// Initialization
- // The default radiator are 100 prolypropilene foils of 20 mu thickness
- // with gaps of 500 mu filled with CO2.
- //
+ // The default radiator are prolypropilene foils of 10 mu thickness
+ // with gaps of 80 mu filled with N2.
//
- fNFoils = 100;
-
- fFoilThick = 0.0020;
+ fNFoilsDim = 7;
+
+ if (fNFoils) delete [] fNFoils;
+ fNFoils = new Int_t[fNFoilsDim];
+ fNFoils[0] = 170;
+ fNFoils[1] = 250;
+ fNFoils[2] = 310;
+ fNFoils[3] = 380;
+ fNFoils[4] = 430;
+ fNFoils[5] = 490;
+ fNFoils[6] = 550;
+
+ if (fNFoilsUp) delete [] fNFoilsUp;
+ fNFoilsUp = new Double_t[fNFoilsDim];
+ fNFoilsUp[0] = 1.25;
+ fNFoilsUp[1] = 1.75;
+ fNFoilsUp[2] = 2.50;
+ fNFoilsUp[3] = 3.50;
+ fNFoilsUp[4] = 4.50;
+ fNFoilsUp[5] = 5.50;
+ fNFoilsUp[6] = 10000.0;
+
+ fFoilThick = 0.0013;
fFoilDens = 0.92;
fFoilZ = 5.28571;
fFoilA = 10.4286;
fFoilOmega = Omega(fFoilDens,fFoilZ,fFoilA);
- fGapThick = 0.0500;
- fGapDens = 0.001977;
- fGapZ = 7.45455;
- fGapA = 14.9091;
+ fGapThick = 0.0060;
+ fGapDens = 0.00125;
+ fGapZ = 7.0;
+ fGapA = 14.00674;
fGapOmega = Omega(fGapDens ,fGapZ ,fGapA );
fTemp = 293.16;
if (fSpectrum) delete fSpectrum;
fSpectrum = new TH1D("TRspectrum","TR spectrum",fSpNBins,fSpLower,fSpUpper);
+ fSpectrum->SetDirectory(0);
// Set the sigma values
SetSigma();
break;
};
- // Calculate gamma
- Double_t gamma = TMath::Sqrt(p*p + mass*mass) / mass;
-
// Calculate the TR photons
- return TrPhotons(gamma, nPhoton, ePhoton);
+ return TrPhotons(p, mass, nPhoton, ePhoton);
}
//_____________________________________________________________________________
-Int_t AliTRDsim::TrPhotons(Double_t gamma, Int_t &nPhoton, Float_t *ePhoton)
+Int_t AliTRDsim::TrPhotons(Float_t p, Float_t mass
+ , Int_t &nPhoton, Float_t *ePhoton)
{
//
// Produces TR photons.
Double_t kappa = fGapThick / fFoilThick;
+ // Calculate gamma
+ Double_t gamma = TMath::Sqrt(p*p + mass*mass) / mass;
+
+ // Select the number of foils corresponding to momentum
+ Int_t foils = SelectNFoils(p);
+
fSpectrum->Reset();
// The TR spectrum
}
// Absorbtion
- Double_t conv = 1.0 - TMath::Exp(-fNFoils * fSigma[iBin]);
+ Double_t conv = 1.0 - TMath::Exp(-foils * fSigma[iBin]);
// eV -> keV
Float_t energykeV = energyeV * 0.001;
// Sets the absorbtion crosssection for the energies of the TR spectrum
//
- if (fSigma) delete fSigma;
+ if (fSigma) delete [] fSigma;
fSigma = new Double_t[fSpNBins];
for (Int_t iBin = 0; iBin < fSpNBins; iBin++) {
Double_t energykeV = iBin * fSpBinWidth + 1.0;
// Calculates the absorbtion crosssection for a one-foil-one-gap-radiator
//
- // Gas at 0 C
- const Double_t kTemp0 = 273.16;
-
// keV -> MeV
Double_t energyMeV = energykeV * 0.001;
if (energyMeV >= 0.001) {
- return(GetMuPo(energyMeV) * fFoilDens * fFoilThick +
- GetMuCO(energyMeV) * fGapDens * fGapThick * fTemp/kTemp0);
+ return(GetMuPo(energyMeV) * fFoilDens * fFoilThick +
+ GetMuAi(energyMeV) * fGapDens * fGapThick * GetTemp());
}
else {
return 1e6;
}
+//_____________________________________________________________________________
+Double_t AliTRDsim::GetMuAi(Double_t energyMeV)
+{
+ //
+ // Returns the photon absorbtion cross section for air
+ // Implemented by Oliver Busch
+ //
+
+ const Int_t kN = 38;
+
+ Double_t mu[kN] = { 0.35854E+04, 0.11841E+04, 0.52458E+03,
+ 0.16143E+03, 0.14250E+03, 0.15722E+03,
+ 0.77538E+02, 0.40099E+02, 0.23313E+02,
+ 0.98816E+01, 0.51000E+01, 0.16079E+01,
+ 0.77536E+00, 0.35282E+00, 0.24790E+00,
+ 0.20750E+00, 0.18703E+00, 0.16589E+00,
+ 0.15375E+00, 0.13530E+00, 0.12311E+00,
+ 0.10654E+00, 0.95297E-01, 0.86939E-01,
+ 0.80390E-01, 0.70596E-01, 0.63452E-01,
+ 0.56754E-01, 0.51644E-01, 0.44382E-01,
+ 0.35733E-01, 0.30721E-01, 0.27450E-01,
+ 0.25171E-01, 0.22205E-01, 0.20399E-01,
+ 0.18053E-01, 0.18057E-01 };
+
+
+
+ Double_t en[kN] = { 0.10000E-02, 0.15000E-02, 0.20000E-02,
+ 0.30000E-02, 0.32029E-02, 0.32029E-02,
+ 0.40000E-02, 0.50000E-02, 0.60000E-02,
+ 0.80000E-02, 0.10000E-01, 0.15000E-01,
+ 0.20000E-01, 0.30000E-01, 0.40000E-01,
+ 0.50000E-01, 0.60000E-01, 0.80000E-01,
+ 0.10000E+00, 0.15000E+00, 0.20000E+00,
+ 0.30000E+00, 0.40000E+00, 0.50000E+00,
+ 0.60000E+00, 0.80000E+00, 0.10000E+01,
+ 0.12500E+01, 0.15000E+01, 0.20000E+01,
+ 0.30000E+01, 0.40000E+01, 0.50000E+01,
+ 0.60000E+01, 0.80000E+01, 0.10000E+02,
+ 0.15000E+02, 0.20000E+02 };
+
+ return Interpolate(energyMeV,en,mu,kN);
+
+}
+
//_____________________________________________________________________________
Double_t AliTRDsim::Interpolate(Double_t energyMeV
, Double_t *en, Double_t *mu, Int_t n)
return 0;
}
+
+//_____________________________________________________________________________
+Int_t AliTRDsim::SelectNFoils(Float_t p)
+{
+ //
+ // Selects the number of foils corresponding to the momentum
+ //
+
+ Int_t foils = fNFoils[fNFoilsDim-1];
+
+ for (Int_t iFoil = 0; iFoil < fNFoilsDim; iFoil++) {
+ if (p < fNFoilsUp[iFoil]) {
+ foils = fNFoils[iFoil];
+ break;
+ }
+ }
+
+ return foils;
+
+}