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

#ifndef ALIGEVSIMPARTICLE_H
#define ALIGEVSIMPARTICLE_H

////////////////////////////////////////////////////////////////////////////////
//
// 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 "TObject.h"

class AliGeVSimParticle : public TObject {

 public:
  
  ////////////////////////////////////////////////////////////////////////////
  
  AliGeVSimParticle() {}
  AliGeVSimParticle(Int_t pdg, Int_t model, Float_t multiplicity); 
  AliGeVSimParticle(Int_t pdg, Int_t model, Float_t multiplicity, 
		    Float_t T, Float_t dY = 1., Float_t exp=0.);
  
  ~AliGeVSimParticle() {}
  
  ////////////////////////////////////////////////////////////////////////////
  
  Int_t GetPdgCode() const {return fPDG;}
  Int_t GetModel() const {return fModel;}

  Float_t GetTemperature() const {return fT;}
  Float_t GetSigmaY() const {return fSigmaY;}
  Float_t GetExpansionVelocity() const {return fExpansion;}

  void SetModel(Int_t model);
  void SetTemperature(Float_t T) {fT = T;}
  void SetSigmaY(Float_t sigma) {fSigmaY = sigma;}
  void SetExpansionVelocity(Float_t vel) {fExpansion = vel;}
  

  // Multiplicity

  void    SetMultiplicity(Float_t mult);
  Float_t GetMultiplicity() {return fN;}

  void   SetMultTotal(Bool_t isTotal = kTRUE);

  Bool_t IsMultTotal() {return fMultTotal;}
  Bool_t IsMultForced() {return fIsSetMult;}
  
  // Flow
  
  void SetDirectedSimple(Float_t v1);
  void SetEllipticSimple(Float_t v2);

  void SetDirectedParam(Float_t v11, Float_t v12=0, Float_t v13=1, Float_t v14=0);
  void SetEllipticParam(Float_t v21, Float_t pTmax, Float_t v22=0.);
  void SetEllipticOld(Float_t v21, Float_t v22, Float_t v23);

  Bool_t IsFlowSimple();

  Float_t GetDirectedFlow(Float_t pt, Float_t y);
  Float_t GetEllipticFlow(Float_t pt, Float_t y);
  
  ////////////////////////////////////////////////////////////////////////////
  
 private:
  
  Int_t fPDG;            // Particle type code
  Int_t fModel;          // Transverse momentum model

  Float_t fN;            // Multiplicity (subject to scalling)
  Bool_t  fMultTotal;    // multiplicity mode: Total or dN/dY
  Bool_t  fIsSetMult;    // force multiplicity mode or use from AliGenGeVSim

  Float_t fT;            // Slope Parameter (subject to scalling)
  Float_t fSigmaY;       // Rapidity Width
  Float_t fExpansion;    // Expansion Velocity in c units (subject to scalling)
  
  Float_t fV1[4];        // Directed Flow coefficient parameters
  Float_t fV2[3];        // Elliptic Flow coefficient parameters
  
  Bool_t fIsDirectedSimple;  // indicate use constant value for directed (v1) 
  Bool_t fIsEllipticSimple;  // indicate use constant value for elliptic (v2)
  Bool_t fIsEllipticOld;     // linear / quadratical pT parametrisation

 public:
  
  ClassDef(AliGeVSimParticle, 3)
    
};

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

#endif
Commit	Line	Data
7816887f	1	#ifndef ALIGEVSIMPARTICLE_H
	2	#define ALIGEVSIMPARTICLE_H
	3
4966b266	4	////////////////////////////////////////////////////////////////////////////////
	5	//
	6	// AliGeVSimParticle is a helper class for GeVSim (AliGenGeVSim) event generator.
	7	// An object of this class represents one particle type and contain
	8	// information about particle type thermal parameters.
	9	//
7e4131fc	10	////////////////////////////////////////////////////////////////////////////////
7e4131fc	11	//
4966b266	12	// For examples, parameters and testing macros refer to:
4966b266	13	// http:/home.cern.ch/radomski
7e4131fc	14	//
	15	// for more detailed description refer to ALICE NOTE
	16	// "GeVSim Monte-Carlo Event Generator"
	17	// S.Radosmki, P. Foka.
	18	//
4966b266	19	// Author:
	20	// Sylwester Radomski,
	21	// GSI, March 2002
7e4131fc	22	//
4966b266	23	// S.Radomski@gsi.de
	24	//
	25	////////////////////////////////////////////////////////////////////////////////
7e4131fc	26	//
	27	// Updated and revised: September 2002, S. Radomski, GSI
	28	//
	29	////////////////////////////////////////////////////////////////////////////////
	30
7816887f	31
4966b266	32	#include "TObject.h"
7816887f	33
	34	class AliGeVSimParticle : public TObject {
	35
7816887f	36	public:
4966b266	37
7816887f	38	////////////////////////////////////////////////////////////////////////////
4966b266	39
7816887f	40	AliGeVSimParticle() {}
7e4131fc	41	AliGeVSimParticle(Int_t pdg, Int_t model, Float_t multiplicity);
7e4131fc	42	AliGeVSimParticle(Int_t pdg, Int_t model, Float_t multiplicity,
7816887f	43	Float_t T, Float_t dY = 1., Float_t exp=0.);
4966b266	44
7816887f	45	~AliGeVSimParticle() {}
4966b266	46
7816887f	47	////////////////////////////////////////////////////////////////////////////
4966b266	48
4966b266	49	Int_t GetPdgCode() const {return fPDG;}
7e4131fc	50	Int_t GetModel() const {return fModel;}
7e4131fc	51
4966b266	52	Float_t GetTemperature() const {return fT;}
	53	Float_t GetSigmaY() const {return fSigmaY;}
	54	Float_t GetExpansionVelocity() const {return fExpansion;}
7e4131fc	55
	56	void SetModel(Int_t model);
	57	void SetTemperature(Float_t T) {fT = T;}
	58	void SetSigmaY(Float_t sigma) {fSigmaY = sigma;}
7816887f	59	void SetExpansionVelocity(Float_t vel) {fExpansion = vel;}
4966b266	60
7e4131fc	61
	62	// Multiplicity
	63
	64	void SetMultiplicity(Float_t mult);
	65	Float_t GetMultiplicity() {return fN;}
	66
	67	void SetMultTotal(Bool_t isTotal = kTRUE);
	68
	69	Bool_t IsMultTotal() {return fMultTotal;}
	70	Bool_t IsMultForced() {return fIsSetMult;}
4966b266	71
7e4131fc	72	// Flow
4966b266	73
7e4131fc	74	void SetDirectedSimple(Float_t v1);
	75	void SetEllipticSimple(Float_t v2);
	76
	77	void SetDirectedParam(Float_t v11, Float_t v12=0, Float_t v13=1, Float_t v14=0);
	78	void SetEllipticParam(Float_t v21, Float_t pTmax, Float_t v22=0.);
	79	void SetEllipticOld(Float_t v21, Float_t v22, Float_t v23);
	80
	81	Bool_t IsFlowSimple();
	82
4966b266	83	Float_t GetDirectedFlow(Float_t pt, Float_t y);
	84	Float_t GetEllipticFlow(Float_t pt, Float_t y);
	85
7816887f	86	////////////////////////////////////////////////////////////////////////////
4966b266	87
	88	private:
	89
	90	Int_t fPDG; // Particle type code
7e4131fc	91	Int_t fModel; // Transverse momentum model
7e4131fc	92
4966b266	93	Float_t fN; // Multiplicity (subject to scalling)
7e4131fc	94	Bool_t fMultTotal; // multiplicity mode: Total or dN/dY
	95	Bool_t fIsSetMult; // force multiplicity mode or use from AliGenGeVSim
	96
4966b266	97	Float_t fT; // Slope Parameter (subject to scalling)
	98	Float_t fSigmaY; // Rapidity Width
	99	Float_t fExpansion; // Expansion Velocity in c units (subject to scalling)
	100
7e4131fc	101	Float_t fV1[4]; // Directed Flow coefficient parameters
7e4131fc	102	Float_t fV2[3]; // Elliptic Flow coefficient parameters
4966b266	103
7e4131fc	104	Bool_t fIsDirectedSimple; // indicate use constant value for directed (v1)
	105	Bool_t fIsEllipticSimple; // indicate use constant value for elliptic (v2)
	106	Bool_t fIsEllipticOld; // linear / quadratical pT parametrisation
	107
4966b266	108	public:
4966b266	109
7e4131fc	110	ClassDef(AliGeVSimParticle, 3)
4966b266	111
7816887f	112	};
7816887f	113
4966b266	114	////////////////////////////////////////////////////////////////////////////////
7816887f	115
7816887f	116	#endif