[u/mrichter/AliRoot.git] / EVGEN / AliGeVSimParticle.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.                  *
 **************************************************************************/

/* $Id$ */

//////////////////////////////////////////////////////////////////////////////
//
// AliGeVSimParticle is a helper class for GeVSim (AliGenGeVSim) event generator.
// An object of this class represents one particle type and contain 
// information about particle type thermal parameters.
//
//////////////////////////////////////////////////////////////////////////////
//
// For examples, parameters and testing macros refer to:
// http:/home.cern.ch/radomski
// 
// for more detailed description refer to ALICE NOTE
// "GeVSim Monte-Carlo Event Generator"
// S.Radosmki, P. Foka.
//  
// Author:
// Sylwester Radomski,
// GSI, March 2002
//  
// S.Radomski@gsi.de
//
////////////////////////////////////////////////////////////////////////////////
//
// Updated and revised: September 2002, S. Radomski, GSI
//
////////////////////////////////////////////////////////////////////////////////


#include "TMath.h"
#include "AliGeVSimParticle.h"

ClassImp(AliGeVSimParticle)


////////////////////////////////////////////////////////////////////////////////////////////////////
AliGeVSimParticle::AliGeVSimParticle():
    fPDG(0),
    fModel(0),
    fN(0),
    fMultTotal(kTRUE),
    fIsSetMult(kFALSE),
    fT(0.),
    fSigmaY(0.),
    fExpansion(0.),
    fIsDirectedSimple(kTRUE),
    fIsEllipticSimple(kTRUE),
    fIsEllipticOld(kFALSE)
{
    // Default constructor
}

AliGeVSimParticle::AliGeVSimParticle(Int_t pdg, Int_t model, Float_t multiplicity,
				     Float_t T, Float_t dY, Float_t exp):
    fPDG(pdg),
    fModel(model),
    fN(multiplicity),
    fMultTotal(kTRUE),
    fIsSetMult(kFALSE),
    fT(T),
    fSigmaY(dY),
    fExpansion(exp),
    fIsDirectedSimple(kTRUE),
    fIsEllipticSimple(kTRUE),
    fIsEllipticOld(kFALSE)
{
  //
  //  pdg          - Particle type code in PDG standard (see: http://pdg.lbl.gov)
  //  model        - momentum distribution model (1 - 7)
  //  multiplicity - multiplicity of particle type
  //  T            - Inverse slope parameter ("temperature")
  //  dY           - Raridity Width (only for model 1)
  //  exp          - expansion velocity (only for model 4) 
  fV1[0] = fV1[1] = fV1[2] = fV1[3] = 0.;
  fV2[0] = fV2[1] = fV2[2] = 0.;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

AliGeVSimParticle::AliGeVSimParticle(Int_t pdg, Int_t model, Float_t multiplicity):
    fPDG(pdg),
    fModel(model),
    fN(multiplicity),
    fMultTotal(kTRUE),
    fIsSetMult(kFALSE),
    fT(0.),
    fSigmaY(0.),
    fExpansion(0.),
    fIsDirectedSimple(kTRUE),
    fIsEllipticSimple(kTRUE),
    fIsEllipticOld(kFALSE)
 {
  //
  // pdg - Particle type code in PDG standard (see: http://pdg.lbl.gov)
  //  
  // Note that multiplicity can be interpreted by GeVSim 
  // either as Total multiplicity in the acceptance or dN/dY
  // 
  fV1[0] = fV1[1] = fV1[2] = fV1[3] = 0.;
  fV2[0] = fV2[1] = fV2[2] = 0.; 
}

////////////////////////////////////////////////////////////////////////////////////////////////////

void  AliGeVSimParticle::SetModel(Int_t model) {
  //
  // Set Model (1-7) 
  // For details about standard and custom models refer to ALICE NOTE
  //

  if (model < 1 || model > 7) 
    Error("SetModel","Model Id ( %d ) out of range [1..7]", model);

  fModel = model;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

void  AliGeVSimParticle::SetMultiplicity(Float_t mult) {
  //
  // Set multiplicity. The value is interpreted either as a total multiplciity
  // in the acceptance or as a multiplicity density - dN/dY at midrapidity
  //  

  fN = mult;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

void AliGeVSimParticle::SetMultTotal(Bool_t isTotal) {
  //
  // Switch between total multiplicity (kTRUE) and 
  // multiplciity density (kFALSE)
  //
  // If this method is used its overrides mode in AliGenGeVSim 
  //
  
  fMultTotal = isTotal;
  fIsSetMult = kTRUE;
}

////////////////////////////////////////////////////////////////////////////////////////////////////
 
void AliGeVSimParticle::SetDirectedSimple(Float_t v1) {
  //
  // Set directed flow coefficient to a value independent
  // of transverse momentum and rapidity
  //

  fV1[0] = v1;
  fIsDirectedSimple = kTRUE;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

void AliGeVSimParticle::SetEllipticSimple(Float_t v2) {
  //
  // Set elliptic flow coefficient to a value independent
  // of transverse momentum and rapidity
  //

  fV2[0] = v2;
  fIsEllipticSimple = kTRUE;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

Bool_t AliGeVSimParticle::IsFlowSimple() const
{
  //
  // Function used by AliGenGeVSim 
  //
  // Returns true if both Elliptic and Directed flow has a simple model.
  // If at least one is parametrised returns false. 
  // 

  return (fIsDirectedSimple && fIsEllipticSimple);
}

////////////////////////////////////////////////////////////////////////////////////////////////////

void AliGeVSimParticle::SetDirectedParam(Float_t v11, Float_t v12, Float_t v13, Float_t v14) {
  //
  // Set parameters for Directed Flow 
  // Actual flow coefficient is calculated as follows
  //
  // V1(Pt,Y) = (V11 + V12*Pt) * sign(Y) * (V13 + V14 * Y^3)
  //
  // where sign = 1 for Y > 0 and -1 for Y < 0
  // 
  // Defaults values
  // v12 = v14 = 0
  // v13 = 1
  // 

  fV1[0] = v11;
  fV1[1] = v12;
  fV1[2] = v13;
  fV1[3] = v14;
  
  fIsDirectedSimple = kFALSE;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

void AliGeVSimParticle::SetEllipticParam(Float_t v21, Float_t pTmax, Float_t v22) {
  //
  // Set parameters for Elliptic Flow
  // Actual flow coefficient is calculated as follows
  //
  // pTmax is in GeV 
  // v21 - flow value at saturation
  //
  //
  // V2 = v21 * (pT/pTMax ) * exp (-v22 * y^2)    where pT <= pTmax  
  //      v21 * exp (-v22 * y^2)                   where pT > pTmax  
  //
  // Default values:
  // v22 = 0
  //
  // The parametrisation is suitable for relativistic particles
  // eg. Pions (at RHIC energies)
  //


  fV2[0] = v21;
  fV2[1] = pTmax;
  fV2[2] = v22;

  fIsEllipticSimple = kFALSE;
  fIsEllipticOld = kFALSE;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

void AliGeVSimParticle::SetEllipticOld(Float_t v21, Float_t v22, Float_t v23) {
  //
  // Set parameters for Elliptic Flow
  // Actual flow coefficient is calculated as follows
  //
  // V2 = (V21 + V22 pT^2) * exp (-v22 * y^2)
  //
  // The parameterisation is suitable for heavy particles: proton, kaon
  //

  fV2[0] = v21;
  fV2[1] = v22;
  fV2[2] = v23;

  fIsEllipticSimple = kFALSE;
  fIsEllipticOld = kTRUE;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

Float_t AliGeVSimParticle::GetDirectedFlow(Float_t pt, Float_t y) {
  //
  // Return coefficient of a directed flow for a given pt and y.
  // For coefficient calculation method refer to SetDirectedParam()
  // 
  
  if (fIsDirectedSimple) return fV1[0];

  Float_t v;
  
  v = (fV1[0] + fV1[1]* pt) * TMath::Sign((Float_t)1.,y) *
    (fV1[2] + fV1[3] * TMath::Abs(y*y*y) );

  return v;
}

////////////////////////////////////////////////////////////////////////////////////////////////////

Float_t AliGeVSimParticle::GetEllipticFlow(Float_t pt, Float_t y) {
  //
  // Return coefficient of a elliptic flow for a given pt and y.
  // For coefficient calculation method refer to SetEllipticParam()
  // 

  if (fIsEllipticSimple) return fV2[0];

  if (fIsEllipticOld) {
    
    // old parametrisation
    return (fV2[0]+fV2[1]*pt*pt) * TMath::Exp(-fV2[2]*y*y);

  } else {

    // new "pionic" parameterisation
    if (pt < fV2[1]) return ( (pt / fV2[1]) * fV2[0] * TMath::Exp(-fV2[2]*y*y) ); 
    else  return ( fV2[0] * TMath::Exp(-fV2[2]*y*y) );
  }
}

////////////////////////////////////////////////////////////////////////////////////////////////////
Commit	Line	Data
	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
	16	/* $Id$ */
	17
	18	//////////////////////////////////////////////////////////////////////////////
	19	//
	20	// AliGeVSimParticle is a helper class for GeVSim (AliGenGeVSim) event generator.
	21	// An object of this class represents one particle type and contain
	22	// information about particle type thermal parameters.
	23	//
	24	//////////////////////////////////////////////////////////////////////////////
	25	//
	26	// For examples, parameters and testing macros refer to:
	27	// http:/home.cern.ch/radomski
	28	//
	29	// for more detailed description refer to ALICE NOTE
	30	// "GeVSim Monte-Carlo Event Generator"
	31	// S.Radosmki, P. Foka.
	32	//
	33	// Author:
	34	// Sylwester Radomski,
	35	// GSI, March 2002
	36	//
	37	// S.Radomski@gsi.de
	38	//
	39	////////////////////////////////////////////////////////////////////////////////
	40	//
	41	// Updated and revised: September 2002, S. Radomski, GSI
	42	//
	43	////////////////////////////////////////////////////////////////////////////////
	44
	45
	46	#include "TMath.h"
	47	#include "AliGeVSimParticle.h"
	48
	49	ClassImp(AliGeVSimParticle)
	50
	51
	52	////////////////////////////////////////////////////////////////////////////////////////////////////
	53	AliGeVSimParticle::AliGeVSimParticle():
	54	fPDG(0),
	55	fModel(0),
	56	fN(0),
	57	fMultTotal(kTRUE),
	58	fIsSetMult(kFALSE),
	59	fT(0.),
	60	fSigmaY(0.),
	61	fExpansion(0.),
	62	fIsDirectedSimple(kTRUE),
	63	fIsEllipticSimple(kTRUE),
	64	fIsEllipticOld(kFALSE)
	65	{
	66	// Default constructor
	67	}
	68
	69	AliGeVSimParticle::AliGeVSimParticle(Int_t pdg, Int_t model, Float_t multiplicity,
	70	Float_t T, Float_t dY, Float_t exp):
	71	fPDG(pdg),
	72	fModel(model),
	73	fN(multiplicity),
	74	fMultTotal(kTRUE),
	75	fIsSetMult(kFALSE),
	76	fT(T),
	77	fSigmaY(dY),
	78	fExpansion(exp),
	79	fIsDirectedSimple(kTRUE),
	80	fIsEllipticSimple(kTRUE),
	81	fIsEllipticOld(kFALSE)
	82	{
	83	//
	84	// pdg - Particle type code in PDG standard (see: http://pdg.lbl.gov)
	85	// model - momentum distribution model (1 - 7)
	86	// multiplicity - multiplicity of particle type
	87	// T - Inverse slope parameter ("temperature")
	88	// dY - Raridity Width (only for model 1)
	89	// exp - expansion velocity (only for model 4)
	90	fV1[0] = fV1[1] = fV1[2] = fV1[3] = 0.;
	91	fV2[0] = fV2[1] = fV2[2] = 0.;
	92	}
	93
	94	////////////////////////////////////////////////////////////////////////////////////////////////////
	95
	96	AliGeVSimParticle::AliGeVSimParticle(Int_t pdg, Int_t model, Float_t multiplicity):
	97	fPDG(pdg),
	98	fModel(model),
	99	fN(multiplicity),
	100	fMultTotal(kTRUE),
	101	fIsSetMult(kFALSE),
	102	fT(0.),
	103	fSigmaY(0.),
	104	fExpansion(0.),
	105	fIsDirectedSimple(kTRUE),
	106	fIsEllipticSimple(kTRUE),
	107	fIsEllipticOld(kFALSE)
	108	{
	109	//
	110	// pdg - Particle type code in PDG standard (see: http://pdg.lbl.gov)
	111	//
	112	// Note that multiplicity can be interpreted by GeVSim
	113	// either as Total multiplicity in the acceptance or dN/dY
	114	//
	115	fV1[0] = fV1[1] = fV1[2] = fV1[3] = 0.;
	116	fV2[0] = fV2[1] = fV2[2] = 0.;
	117	}
	118
	119	////////////////////////////////////////////////////////////////////////////////////////////////////
	120
	121	void AliGeVSimParticle::SetModel(Int_t model) {
	122	//
	123	// Set Model (1-7)
	124	// For details about standard and custom models refer to ALICE NOTE
	125	//
	126
	127	if (model < 1 \|\| model > 7)
	128	Error("SetModel","Model Id ( %d ) out of range [1..7]", model);
	129
	130	fModel = model;
	131	}
	132
	133	////////////////////////////////////////////////////////////////////////////////////////////////////
	134
	135	void AliGeVSimParticle::SetMultiplicity(Float_t mult) {
	136	//
	137	// Set multiplicity. The value is interpreted either as a total multiplciity
	138	// in the acceptance or as a multiplicity density - dN/dY at midrapidity
	139	//
	140
	141	fN = mult;
	142	}
	143
	144	////////////////////////////////////////////////////////////////////////////////////////////////////
	145
	146	void AliGeVSimParticle::SetMultTotal(Bool_t isTotal) {
	147	//
	148	// Switch between total multiplicity (kTRUE) and
	149	// multiplciity density (kFALSE)
	150	//
	151	// If this method is used its overrides mode in AliGenGeVSim
	152	//
	153
	154	fMultTotal = isTotal;
	155	fIsSetMult = kTRUE;
	156	}
	157
	158	////////////////////////////////////////////////////////////////////////////////////////////////////
	159
	160	void AliGeVSimParticle::SetDirectedSimple(Float_t v1) {
	161	//
	162	// Set directed flow coefficient to a value independent
	163	// of transverse momentum and rapidity
	164	//
	165
	166	fV1[0] = v1;
	167	fIsDirectedSimple = kTRUE;
	168	}
	169
	170	////////////////////////////////////////////////////////////////////////////////////////////////////
	171
	172	void AliGeVSimParticle::SetEllipticSimple(Float_t v2) {
	173	//
	174	// Set elliptic flow coefficient to a value independent
	175	// of transverse momentum and rapidity
	176	//
	177
	178	fV2[0] = v2;
	179	fIsEllipticSimple = kTRUE;
	180	}
	181
	182	////////////////////////////////////////////////////////////////////////////////////////////////////
	183
	184	Bool_t AliGeVSimParticle::IsFlowSimple() const
	185	{
	186	//
	187	// Function used by AliGenGeVSim
	188	//
	189	// Returns true if both Elliptic and Directed flow has a simple model.
	190	// If at least one is parametrised returns false.
	191	//
	192
	193	return (fIsDirectedSimple && fIsEllipticSimple);
	194	}
	195
	196	////////////////////////////////////////////////////////////////////////////////////////////////////
	197
	198	void AliGeVSimParticle::SetDirectedParam(Float_t v11, Float_t v12, Float_t v13, Float_t v14) {
	199	//
	200	// Set parameters for Directed Flow
	201	// Actual flow coefficient is calculated as follows
	202	//
	203	// V1(Pt,Y) = (V11 + V12Pt) sign(Y) * (V13 + V14 * Y^3)
	204	//
	205	// where sign = 1 for Y > 0 and -1 for Y < 0
	206	//
	207	// Defaults values
	208	// v12 = v14 = 0
	209	// v13 = 1
	210	//
	211
	212	fV1[0] = v11;
	213	fV1[1] = v12;
	214	fV1[2] = v13;
	215	fV1[3] = v14;
	216
	217	fIsDirectedSimple = kFALSE;
	218	}
	219
	220	////////////////////////////////////////////////////////////////////////////////////////////////////
	221
	222	void AliGeVSimParticle::SetEllipticParam(Float_t v21, Float_t pTmax, Float_t v22) {
	223	//
	224	// Set parameters for Elliptic Flow
	225	// Actual flow coefficient is calculated as follows
	226	//
	227	// pTmax is in GeV
	228	// v21 - flow value at saturation
	229	//
	230	//
	231	// V2 = v21 * (pT/pTMax ) * exp (-v22 * y^2) where pT <= pTmax
	232	// v21 * exp (-v22 * y^2) where pT > pTmax
	233	//
	234	// Default values:
	235	// v22 = 0
	236	//
	237	// The parametrisation is suitable for relativistic particles
	238	// eg. Pions (at RHIC energies)
	239	//
	240
	241
	242	fV2[0] = v21;
	243	fV2[1] = pTmax;
	244	fV2[2] = v22;
	245
	246	fIsEllipticSimple = kFALSE;
	247	fIsEllipticOld = kFALSE;
	248	}
	249
	250	////////////////////////////////////////////////////////////////////////////////////////////////////
	251
	252	void AliGeVSimParticle::SetEllipticOld(Float_t v21, Float_t v22, Float_t v23) {
	253	//
	254	// Set parameters for Elliptic Flow
	255	// Actual flow coefficient is calculated as follows
	256	//
	257	// V2 = (V21 + V22 pT^2) * exp (-v22 * y^2)
	258	//
	259	// The parameterisation is suitable for heavy particles: proton, kaon
	260	//
	261
	262	fV2[0] = v21;
	263	fV2[1] = v22;
	264	fV2[2] = v23;
	265
	266	fIsEllipticSimple = kFALSE;
	267	fIsEllipticOld = kTRUE;
	268	}
	269
	270	////////////////////////////////////////////////////////////////////////////////////////////////////
	271
	272	Float_t AliGeVSimParticle::GetDirectedFlow(Float_t pt, Float_t y) {
	273	//
	274	// Return coefficient of a directed flow for a given pt and y.
	275	// For coefficient calculation method refer to SetDirectedParam()
	276	//
	277
	278	if (fIsDirectedSimple) return fV1[0];
	279
	280	Float_t v;
	281
	282	v = (fV1[0] + fV1[1]* pt) * TMath::Sign((Float_t)1.,y) *
	283	(fV1[2] + fV1[3] * TMath::Abs(yyy) );
	284
	285	return v;
	286	}
	287
	288	////////////////////////////////////////////////////////////////////////////////////////////////////
	289
	290	Float_t AliGeVSimParticle::GetEllipticFlow(Float_t pt, Float_t y) {
	291	//
	292	// Return coefficient of a elliptic flow for a given pt and y.
	293	// For coefficient calculation method refer to SetEllipticParam()
	294	//
	295
	296	if (fIsEllipticSimple) return fV2[0];
	297
	298	if (fIsEllipticOld) {
	299
	300	// old parametrisation
	301	return (fV2[0]+fV2[1]ptpt) * TMath::Exp(-fV2[2]yy);
	302
	303	} else {
	304
	305	// new "pionic" parameterisation
	306	if (pt < fV2[1]) return ( (pt / fV2[1]) * fV2[0] * TMath::Exp(-fV2[2]yy) );
	307	else return ( fV2[0] * TMath::Exp(-fV2[2]yy) );
	308	}
	309	}
	310
	311	////////////////////////////////////////////////////////////////////////////////////////////////////
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