[u/mrichter/AliRoot.git] / EVGEN / AliGenSlowNucleons.cxx

/**************************************************************************
 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 *                                                                        *
 * Author: The ALICE Off-line Project.                                    *
 * Contributors are mentioned in the code where appropriate.              *
 *                                                                        *
 * Permission to use, copy, modify and distribute this software and its   *
 * documentation strictly for non-commercial purposes is hereby granted   *
 * without fee, provided that the above copyright notice appears in all   *
 * copies and that both the copyright notice and this permission notice   *
 * appear in the supporting documentation. The authors make no claims     *
 * about the suitability of this software for any purpose. It is          *
 * provided "as is" without express or implied warranty.                  *
 **************************************************************************/

/* $Id$ */

//
//  Generator for slow nucleons in pA interactions. 
//  Source is modelled by a relativistic Maxwell distributions.
//  This class cooparates with AliCollisionGeometry if used inside AliGenCocktail.
//  In this case the number of slow nucleons is determined from the number of wounded nuclei
//  using a realisation of AliSlowNucleonModel.
//  Original code by  Ferenc Sikler  <sikler@rmki.kfki.hu>
// 

#include <TDatabasePDG.h>
#include <TPDGCode.h>
#include <TH2F.h>
#include <TCanvas.h>

#include "AliCollisionGeometry.h"
#include "AliGenSlowNucleons.h"
#include "AliSlowNucleonModel.h"

 ClassImp(AliGenSlowNucleons)
    
 AliGenSlowNucleons::AliGenSlowNucleons():AliGenerator(-1)
{
// Default constructor
    fSlowNucleonModel = 0;
    fCollisionGeometry = 0;
}

AliGenSlowNucleons::AliGenSlowNucleons(Int_t npart)
    :AliGenerator(npart)
{
// Constructor
    fName  = "SlowNucleons";
    fTitle = "Generator for gray particles in pA collisions";
    SetPmax();
    SetTarget();
    SetNominalCmsEnergy();
    SetCharge();
    SetTemperature();
    SetBetaSource();
    fSlowNucleonModel = new AliSlowNucleonModel();
    fCollisionGeometry = 0;
    fDebug = 0;
}

AliGenSlowNucleons::AliGenSlowNucleons(const AliGenSlowNucleons & sn):
    AliGenerator(sn)
{
// Copy constructor
    sn.Copy(*this);
}

//____________________________________________________________
AliGenSlowNucleons::~AliGenSlowNucleons()
{
// Destructor
    delete  fSlowNucleonModel;
}


void AliGenSlowNucleons::Init()
{
  //
  // Initialization
  //
    Float_t kMass  = TDatabasePDG::Instance()->GetParticle(kProton)->Mass();
    fMomentum = fCMS/2. * fZTarget / fATarget;
    fBeta     = fMomentum / TMath::Sqrt(kMass * kMass + fMomentum * fMomentum);
    if (fDebug) {
	fDebugHist1 = new TH2F("DebugHist1", "nu vs N_slow", 100, 0., 100., 20, 0., 20.);
	fDebugHist2 = new TH2F("DebugHist2", "b  vs N_slow", 100, 0., 100., 15, 0., 15.);
    }
}

void AliGenSlowNucleons::FinishRun()
{
// End of run action
// Show histogram for debugging if requested.
    if (fDebug) {
	TCanvas *c = new TCanvas("c","Canvas 1",400,10,600,700);
	c->Divide(2,1);
	c->cd(1);
	fDebugHist1->Draw();
	c->cd(2);
	fDebugHist2->Draw();
    }
}


void AliGenSlowNucleons::Generate()
{
  //
  // Generate one event
  //
  //
  // Communication with Gray Particle Model 
  // 
    if (fCollisionGeometry) {
	Float_t b   = fCollisionGeometry->ImpactParameter();
	Int_t  nn   = fCollisionGeometry->NN();
	Int_t  nwn  = fCollisionGeometry->NwN();
	Int_t  nnw  = fCollisionGeometry->NNw();
	Int_t  nwnw = fCollisionGeometry->NwNw();

	fSlowNucleonModel->GetNumberOfSlowNucleons(fCollisionGeometry, fNgp, fNgn, fNbp, fNbn);
	if (fDebug) {
	    printf("Nucleons %d %d %d %d \n", fNgp, fNgn, fNbp, fNbn);
	    fDebugHist1->Fill(Float_t(fNgp + fNgn + fNbp + fNbn), fCollisionGeometry->NwN(), 1.);
	    fDebugHist2->Fill(Float_t(fNgp + fNgn + fNbp + fNbn), b, 1.);
	    printf("AliGenSlowNucleons: Impact parameter from Collision Geometry %f %d %d %d %d\n", 
		   b, nn, nwn, nnw, nwnw);
	}
    }     

   //
    Float_t p[3];
    Float_t origin[3] = {0., 0., 0.};
    Float_t polar [3] = {0., 0., 0.};    
    Int_t nt, i, j;
    Int_t kf;
    
    if(fVertexSmear == kPerEvent) {
	Vertex();
	for (j=0; j < 3; j++) origin[j] = fVertex[j];
    } // if kPerEvent
//
//  Gray protons
//
    fCharge = 1;
    kf = kProton;    
    for(i = 0; i < fNgp; i++) {
	GenerateSlow(fCharge, fTemperatureG, fBetaSourceG, p);
	PushTrack(fTrackIt, -1, kf, p, origin, polar,
		 0., kPNoProcess, nt, 1.);
	KeepTrack(nt);
    }
//
//  Gray neutrons
//
    fCharge = 0;
    kf = kNeutron;    
    for(i = 0; i < fNgn; i++) {
	GenerateSlow(fCharge, fTemperatureG, fBetaSourceG, p);
	PushTrack(fTrackIt, -1, kf, p, origin, polar,
		 0., kPNoProcess, nt, 1.);
	KeepTrack(nt);
    }
//
//  Black protons
//
    fCharge = 1;
    kf = kProton;    
    for(i = 0; i < fNbp; i++) {
	GenerateSlow(fCharge, fTemperatureB, fBetaSourceB, p);
	PushTrack(fTrackIt, -1, kf, p, origin, polar,
		 0., kPNoProcess, nt, 1.);
	KeepTrack(nt);
    }
//
//  Black neutrons
//
    fCharge = 0;
    kf = kNeutron;    
    for(i = 0; i < fNbn; i++) {
	GenerateSlow(fCharge, fTemperatureB, fBetaSourceB, p);
	PushTrack(fTrackIt, -1, kf, p, origin, polar,
		 0., kPNoProcess, nt, 1.);
	KeepTrack(nt);
    }
}


void AliGenSlowNucleons::GenerateSlow(Int_t charge, Double_t T, Double_t beta, Float_t* q)

{
/* 
   Emit a slow nucleon with "temperature" T [GeV], 
   from a source moving with velocity beta         
   Three-momentum [GeV/c] is given back in q[3]    
*/

 Double_t m, pmax, p, f, theta, phi;
 TDatabasePDG * pdg = TDatabasePDG::Instance();
 const Double_t kMassProton  = pdg->GetParticle(kProton) ->Mass();
 const Double_t kMassNeutron = pdg->GetParticle(kNeutron)->Mass();
 
 /* Select nucleon type */
 if(charge == 0) m = kMassNeutron;
 else m = kMassProton;

 /* Momentum at maximum of Maxwell-distribution */

 pmax = TMath::Sqrt(2*T*(T+sqrt(T*T+m*m)));

 /* Try until proper momentum                                  */
 /* for lack of primitive function of the Maxwell-distribution */
 /* a brute force trial-accept loop, normalized at pmax        */

 do
 {
     p = Rndm() * fPmax;
     f = Maxwell(m, p, T) / Maxwell(m , pmax, T);
 }
 while(f < Rndm());

 /* Spherical symmetric emission */
 theta = TMath::ACos(2. * Rndm() - 1.);
 phi   = 2. * TMath::Pi() * Rndm();

 /* Determine momentum components in system of the moving source */
 q[0] = p * TMath::Sin(theta) * TMath::Cos(phi);
 q[1] = p * TMath::Sin(theta) * TMath::Sin(phi);
 q[2] = p * TMath::Cos(theta);

 /* Transform to system of the target nucleus                             */
 /* beta is passed as negative, because the gray nucleons are slowed down */
 Lorentz(m, -beta, q);

 /* Transform to laboratory system */
 Lorentz(m, fBeta, q);
}

Double_t AliGenSlowNucleons::Maxwell(Double_t m, Double_t p, Double_t T)
{
/* Relativistic Maxwell-distribution */
    Double_t ekin;
    ekin = TMath::Sqrt(p*p+m*m)-m;
    return (p*p * exp(-ekin/T));
}


void AliGenSlowNucleons::Lorentz(Double_t m, Double_t beta, Float_t* q)
{
/* Lorentz transform in the direction of q[2] */
 
    Double_t gamma  = 1/sqrt(1-beta*beta); 
    Double_t energy = sqrt(m*m + q[0]*q[0] + q[1]*q[1] + q[2]*q[2]);
    q[2] = gamma * (q[2] + beta*energy);
}

	  
AliGenSlowNucleons& AliGenSlowNucleons::operator=(const  AliGenSlowNucleons& rhs)
{
// Assignment operator
    rhs.Copy(*this);
    return *this;
}

void AliGenSlowNucleons::Copy(TObject&) const
{
    //
    // Copy 
    //
    Fatal("Copy","Not implemented!\n");
}
Commit	Line	Data
c9a8628a	1	/**************************************************************************
	2	* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	3	* *
	4	* Author: The ALICE Off-line Project. *
	5	* Contributors are mentioned in the code where appropriate. *
	6	* *
	7	* Permission to use, copy, modify and distribute this software and its *
	8	* documentation strictly for non-commercial purposes is hereby granted *
	9	* without fee, provided that the above copyright notice appears in all *
	10	* copies and that both the copyright notice and this permission notice *
	11	* appear in the supporting documentation. The authors make no claims *
	12	* about the suitability of this software for any purpose. It is *
	13	* provided "as is" without express or implied warranty. *
	14	**************************************************************************/
	15
88cb7938	16	/* $Id$ */
c9a8628a	17
f687abfe	18	//
	19	// Generator for slow nucleons in pA interactions.
	20	// Source is modelled by a relativistic Maxwell distributions.
	21	// This class cooparates with AliCollisionGeometry if used inside AliGenCocktail.
	22	// In this case the number of slow nucleons is determined from the number of wounded nuclei
	23	// using a realisation of AliSlowNucleonModel.
	24	// Original code by Ferenc Sikler <sikler@rmki.kfki.hu>
	25	//
c9a8628a	26
	27	#include <TDatabasePDG.h>
	28	#include <TPDGCode.h>
	29	#include <TH2F.h>
c8f7f6f9	30	#include <TCanvas.h>
c9a8628a	31
	32	#include "AliCollisionGeometry.h"
	33	#include "AliGenSlowNucleons.h"
	34	#include "AliSlowNucleonModel.h"
	35
	36	ClassImp(AliGenSlowNucleons)
	37
	38	AliGenSlowNucleons::AliGenSlowNucleons():AliGenerator(-1)
	39	{
	40	// Default constructor
	41	fSlowNucleonModel = 0;
	42	fCollisionGeometry = 0;
	43	}
	44
	45	AliGenSlowNucleons::AliGenSlowNucleons(Int_t npart)
	46	:AliGenerator(npart)
	47	{
	48	// Constructor
	49	fName = "SlowNucleons";
	50	fTitle = "Generator for gray particles in pA collisions";
	51	SetPmax();
	52	SetTarget();
	53	SetNominalCmsEnergy();
	54	SetCharge();
	55	SetTemperature();
	56	SetBetaSource();
	57	fSlowNucleonModel = new AliSlowNucleonModel();
	58	fCollisionGeometry = 0;
	59	fDebug = 0;
	60	}
	61
f687abfe	62	AliGenSlowNucleons::AliGenSlowNucleons(const AliGenSlowNucleons & sn):
	63	AliGenerator(sn)
	64	{
	65	// Copy constructor
	66	sn.Copy(*this);
	67	}
	68
c9a8628a	69	//____________________________________________________________
	70	AliGenSlowNucleons::~AliGenSlowNucleons()
	71	{
	72	// Destructor
	73	delete fSlowNucleonModel;
	74	}
	75
	76
	77	void AliGenSlowNucleons::Init()
	78	{
	79	//
	80	// Initialization
	81	//
	82	Float_t kMass = TDatabasePDG::Instance()->GetParticle(kProton)->Mass();
	83	fMomentum = fCMS/2. * fZTarget / fATarget;
	84	fBeta = fMomentum / TMath::Sqrt(kMass * kMass + fMomentum * fMomentum);
	85	if (fDebug) {
c8f7f6f9	86	fDebugHist1 = new TH2F("DebugHist1", "nu vs N_slow", 100, 0., 100., 20, 0., 20.);
c8f7f6f9	87	fDebugHist2 = new TH2F("DebugHist2", "b vs N_slow", 100, 0., 100., 15, 0., 15.);
c9a8628a	88	}
	89	}
	90
	91	void AliGenSlowNucleons::FinishRun()
	92	{
f687abfe	93	// End of run action
f687abfe	94	// Show histogram for debugging if requested.
c9a8628a	95	if (fDebug) {
c8f7f6f9	96	TCanvas *c = new TCanvas("c","Canvas 1",400,10,600,700);
	97	c->Divide(2,1);
	98	c->cd(1);
	99	fDebugHist1->Draw();
	100	c->cd(2);
	101	fDebugHist2->Draw();
c9a8628a	102	}
	103	}
	104
	105
	106	void AliGenSlowNucleons::Generate()
	107	{
	108	//
	109	// Generate one event
	110	//
	111	//
	112	// Communication with Gray Particle Model
	113	//
1c22a81e	114	if (fCollisionGeometry) {
	115	Float_t b = fCollisionGeometry->ImpactParameter();
	116	Int_t nn = fCollisionGeometry->NN();
	117	Int_t nwn = fCollisionGeometry->NwN();
	118	Int_t nnw = fCollisionGeometry->NNw();
	119	Int_t nwnw = fCollisionGeometry->NwNw();
	120
99f5114f	121	fSlowNucleonModel->GetNumberOfSlowNucleons(fCollisionGeometry, fNgp, fNgn, fNbp, fNbn);
1c22a81e	122	if (fDebug) {
1c22a81e	123	printf("Nucleons %d %d %d %d \n", fNgp, fNgn, fNbp, fNbn);
c8f7f6f9	124	fDebugHist1->Fill(Float_t(fNgp + fNgn + fNbp + fNbn), fCollisionGeometry->NwN(), 1.);
c8f7f6f9	125	fDebugHist2->Fill(Float_t(fNgp + fNgn + fNbp + fNbn), b, 1.);
1c22a81e	126	printf("AliGenSlowNucleons: Impact parameter from Collision Geometry %f %d %d %d %d\n",
	127	b, nn, nwn, nnw, nwnw);
	128	}
	129	}
c9a8628a	130
	131	//
	132	Float_t p[3];
	133	Float_t origin[3] = {0., 0., 0.};
	134	Float_t polar [3] = {0., 0., 0.};
99f5114f	135	Int_t nt, i, j;
c9a8628a	136	Int_t kf;
99f5114f	137
	138	if(fVertexSmear == kPerEvent) {
	139	Vertex();
	140	for (j=0; j < 3; j++) origin[j] = fVertex[j];
	141	} // if kPerEvent
c9a8628a	142	//
	143	// Gray protons
	144	//
	145	fCharge = 1;
	146	kf = kProton;
1c22a81e	147	for(i = 0; i < fNgp; i++) {
c9a8628a	148	GenerateSlow(fCharge, fTemperatureG, fBetaSourceG, p);
642f15cf	149	PushTrack(fTrackIt, -1, kf, p, origin, polar,
c9a8628a	150	0., kPNoProcess, nt, 1.);
	151	KeepTrack(nt);
	152	}
	153	//
	154	// Gray neutrons
	155	//
	156	fCharge = 0;
	157	kf = kNeutron;
1c22a81e	158	for(i = 0; i < fNgn; i++) {
c9a8628a	159	GenerateSlow(fCharge, fTemperatureG, fBetaSourceG, p);
642f15cf	160	PushTrack(fTrackIt, -1, kf, p, origin, polar,
c9a8628a	161	0., kPNoProcess, nt, 1.);
	162	KeepTrack(nt);
	163	}
	164	//
	165	// Black protons
	166	//
	167	fCharge = 1;
	168	kf = kProton;
1c22a81e	169	for(i = 0; i < fNbp; i++) {
c9a8628a	170	GenerateSlow(fCharge, fTemperatureB, fBetaSourceB, p);
642f15cf	171	PushTrack(fTrackIt, -1, kf, p, origin, polar,
c9a8628a	172	0., kPNoProcess, nt, 1.);
	173	KeepTrack(nt);
	174	}
	175	//
	176	// Black neutrons
	177	//
	178	fCharge = 0;
	179	kf = kNeutron;
1c22a81e	180	for(i = 0; i < fNbn; i++) {
c9a8628a	181	GenerateSlow(fCharge, fTemperatureB, fBetaSourceB, p);
642f15cf	182	PushTrack(fTrackIt, -1, kf, p, origin, polar,
c9a8628a	183	0., kPNoProcess, nt, 1.);
	184	KeepTrack(nt);
	185	}
	186	}
	187
	188
	189
	190
	191	void AliGenSlowNucleons::GenerateSlow(Int_t charge, Double_t T, Double_t beta, Float_t* q)
f687abfe	192
f687abfe	193	{
c9a8628a	194	/*
	195	Emit a slow nucleon with "temperature" T [GeV],
	196	from a source moving with velocity beta
	197	Three-momentum [GeV/c] is given back in q[3]
	198	*/
	199
c9a8628a	200	Double_t m, pmax, p, f, theta, phi;
c9a8628a	201	TDatabasePDG * pdg = TDatabasePDG::Instance();
	202	const Double_t kMassProton = pdg->GetParticle(kProton) ->Mass();
	203	const Double_t kMassNeutron = pdg->GetParticle(kNeutron)->Mass();
	204
	205	/* Select nucleon type */
	206	if(charge == 0) m = kMassNeutron;
	207	else m = kMassProton;
	208
	209	/* Momentum at maximum of Maxwell-distribution */
	210
	211	pmax = TMath::Sqrt(2T(T+sqrt(TT+mm)));
	212
	213	/* Try until proper momentum */
	214	/* for lack of primitive function of the Maxwell-distribution */
	215	/* a brute force trial-accept loop, normalized at pmax */
	216
	217	do
	218	{
	219	p = Rndm() * fPmax;
	220	f = Maxwell(m, p, T) / Maxwell(m , pmax, T);
	221	}
	222	while(f < Rndm());
	223
	224	/* Spherical symmetric emission */
	225	theta = TMath::ACos(2. * Rndm() - 1.);
	226	phi = 2. * TMath::Pi() * Rndm();
	227
	228	/* Determine momentum components in system of the moving source */
	229	q[0] = p * TMath::Sin(theta) * TMath::Cos(phi);
	230	q[1] = p * TMath::Sin(theta) * TMath::Sin(phi);
	231	q[2] = p * TMath::Cos(theta);
	232
	233	/* Transform to system of the target nucleus */
	234	/* beta is passed as negative, because the gray nucleons are slowed down */
	235	Lorentz(m, -beta, q);
	236
	237	/* Transform to laboratory system */
	238	Lorentz(m, fBeta, q);
	239	}
	240
	241	Double_t AliGenSlowNucleons::Maxwell(Double_t m, Double_t p, Double_t T)
	242	{
	243	/* Relativistic Maxwell-distribution */
	244	Double_t ekin;
	245	ekin = TMath::Sqrt(pp+mm)-m;
	246	return (pp exp(-ekin/T));
	247	}
	248
	249
	250	void AliGenSlowNucleons::Lorentz(Double_t m, Double_t beta, Float_t* q)
	251	{
	252	/* Lorentz transform in the direction of q[2] */
	253
	254	Double_t gamma = 1/sqrt(1-beta*beta);
	255	Double_t energy = sqrt(mm + q[0]q[0] + q[1]q[1] + q[2]q[2]);
	256	q[2] = gamma * (q[2] + beta*energy);
	257	}
	258
f687abfe	259
	260	AliGenSlowNucleons& AliGenSlowNucleons::operator=(const AliGenSlowNucleons& rhs)
	261	{
	262	// Assignment operator
	263	rhs.Copy(*this);
	264	return *this;
	265	}
	266
dc1d768c	267	void AliGenSlowNucleons::Copy(TObject&) const
f687abfe	268	{
	269	//
	270	// Copy
	271	//
	272	Fatal("Copy","Not implemented!\n");
	273	}
	274
c9a8628a	275
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