// @(#)root/physics:$Id$ // Author: Rene Brun , Valerio Filippini 06/09/2000 //_____________________________________________________________________________________ // // Utility class to generate n-body event, // with constant cross-section (default) // or with Fermi energy dependence (opt="Fermi"). // The event is generated in the center-of-mass frame, // but the decay products are finally boosted // using the betas of the original particle. // // The code is based on the GENBOD function (W515 from CERNLIB) // using the Raubold and Lynch method // F. James, Monte Carlo Phase Space, CERN 68-15 (1968) // // see example of use in $ROOTSYS/tutorials/physics/PhaseSpace.C // // Note that Momentum, Energy units are Gev/C, GeV #include "TGenPhaseSpace.h" #include "TRandom.h" #include "TMath.h" #include <stdlib.h> const Int_t kMAXP = 18; ClassImp(TGenPhaseSpace) //_____________________________________________________________________________________ Double_t TGenPhaseSpace::PDK(Double_t a, Double_t b, Double_t c) { //the PDK function Double_t x = (a-b-c)*(a+b+c)*(a-b+c)*(a+b-c); x = TMath::Sqrt(x)/(2*a); return x; } //_____________________________________________________________________________________ Int_t DoubleMax(const void *a, const void *b) { //special max function Double_t aa = * ((Double_t *) a); Double_t bb = * ((Double_t *) b); if (aa > bb) return 1; if (aa < bb) return -1; return 0; } //__________________________________________________________________________________________________ TGenPhaseSpace::TGenPhaseSpace(const TGenPhaseSpace &gen) : TObject(gen) { //copy constructor fNt = gen.fNt; fWtMax = gen.fWtMax; fTeCmTm = gen.fTeCmTm; fBeta[0] = gen.fBeta[0]; fBeta[1] = gen.fBeta[1]; fBeta[2] = gen.fBeta[2]; for (Int_t i=0;i<fNt;i++) { fMass[i] = gen.fMass[i]; fDecPro[i] = gen.fDecPro[i]; } } //__________________________________________________________________________________________________ TGenPhaseSpace& TGenPhaseSpace::operator=(const TGenPhaseSpace &gen) { // Assignment operator TObject::operator=(gen); fNt = gen.fNt; fWtMax = gen.fWtMax; fTeCmTm = gen.fTeCmTm; fBeta[0] = gen.fBeta[0]; fBeta[1] = gen.fBeta[1]; fBeta[2] = gen.fBeta[2]; for (Int_t i=0;i<fNt;i++) { fMass[i] = gen.fMass[i]; fDecPro[i] = gen.fDecPro[i]; } return *this; } //__________________________________________________________________________________________________ Double_t TGenPhaseSpace::Generate() { // Generate a random final state. // The function returns the weigth of the current event. // The TLorentzVector of each decay product can be obtained using GetDecay(n). // // Note that Momentum, Energy units are Gev/C, GeV Double_t rno[kMAXP]; rno[0] = 0; Int_t n; if (fNt>2) { for (n=1; n<fNt-1; n++) rno[n]=gRandom->Rndm(); // fNt-2 random numbers qsort(rno+1 ,fNt-2 ,sizeof(Double_t) ,DoubleMax); // sort them } rno[fNt-1] = 1; Double_t invMas[kMAXP], sum=0; for (n=0; n<fNt; n++) { sum += fMass[n]; invMas[n] = rno[n]*fTeCmTm + sum; } // //-----> compute the weight of the current event // Double_t wt=fWtMax; Double_t pd[kMAXP]; for (n=0; n<fNt-1; n++) { pd[n] = PDK(invMas[n+1],invMas[n],fMass[n+1]); wt *= pd[n]; } // //-----> complete specification of event (Raubold-Lynch method) // fDecPro[0].SetPxPyPzE(0, pd[0], 0 , TMath::Sqrt(pd[0]*pd[0]+fMass[0]*fMass[0]) ); Int_t i=1; Int_t j; while (1) { fDecPro[i].SetPxPyPzE(0, -pd[i-1], 0 , TMath::Sqrt(pd[i-1]*pd[i-1]+fMass[i]*fMass[i]) ); Double_t cZ = 2*gRandom->Rndm() - 1; Double_t sZ = TMath::Sqrt(1-cZ*cZ); Double_t angY = 2*TMath::Pi() * gRandom->Rndm(); Double_t cY = TMath::Cos(angY); Double_t sY = TMath::Sin(angY); for (j=0; j<=i; j++) { TLorentzVector *v = fDecPro+j; Double_t x = v->Px(); Double_t y = v->Py(); v->SetPx( cZ*x - sZ*y ); v->SetPy( sZ*x + cZ*y ); // rotation around Z x = v->Px(); Double_t z = v->Pz(); v->SetPx( cY*x - sY*z ); v->SetPz( sY*x + cY*z ); // rotation around Y } if (i == (fNt-1)) break; Double_t beta = pd[i] / sqrt(pd[i]*pd[i] + invMas[i]*invMas[i]); for (j=0; j<=i; j++) fDecPro[j].Boost(0,beta,0); i++; } // //---> final boost of all particles // for (n=0;n<fNt;n++) fDecPro[n].Boost(fBeta[0],fBeta[1],fBeta[2]); // //---> return the weigth of event // return wt; } //__________________________________________________________________________________ TLorentzVector *TGenPhaseSpace::GetDecay(Int_t n) { //return Lorentz vector corresponding to decay n if (n>fNt) return 0; return fDecPro+n; } //_____________________________________________________________________________________ Bool_t TGenPhaseSpace::SetDecay(TLorentzVector &P, Int_t nt, const Double_t *mass, Option_t *opt) { // input: // TLorentzVector &P: decay particle (Momentum, Energy units are Gev/C, GeV) // Int_t nt: number of decay products // Double_t *mass: array of decay product masses // Option_t *opt: default -> constant cross section // "Fermi" -> Fermi energy dependece // return value: // kTRUE: the decay is permitted by kinematics // kFALSE: the decay is forbidden by kinematics // Int_t n; fNt = nt; if (fNt<2 || fNt>18) return kFALSE; // no more then 18 particle // // // fTeCmTm = P.Mag(); // total energy in C.M. minus the sum of the masses for (n=0;n<fNt;n++) { fMass[n] = mass[n]; fTeCmTm -= mass[n]; } if (fTeCmTm<=0) return kFALSE; // not enough energy for this decay // //------> the max weigth depends on opt: // opt == "Fermi" --> fermi energy dependence for cross section // else --> constant cross section as function of TECM (default) // if (strcasecmp(opt,"fermi")==0) { // ffq[] = pi * (2*pi)**(FNt-2) / (FNt-2)! Double_t ffq[] = {0 ,3.141592, 19.73921, 62.01255, 129.8788, 204.0131 ,256.3704, 268.4705, 240.9780, 189.2637 ,132.1308, 83.0202, 47.4210, 24.8295 ,12.0006, 5.3858, 2.2560, 0.8859 }; fWtMax = TMath::Power(fTeCmTm,fNt-2) * ffq[fNt-1] / P.Mag(); } else { Double_t emmax = fTeCmTm + fMass[0]; Double_t emmin = 0; Double_t wtmax = 1; for (n=1; n<fNt; n++) { emmin += fMass[n-1]; emmax += fMass[n]; wtmax *= PDK(emmax, emmin, fMass[n]); } fWtMax = 1/wtmax; } // //----> save the betas of the decaying particle // if (P.Beta()) { Double_t w = P.Beta()/P.Rho(); fBeta[0] = P(0)*w; fBeta[1] = P(1)*w; fBeta[2] = P(2)*w; } else fBeta[0]=fBeta[1]=fBeta[2]=0; return kTRUE; }
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