[u/mrichter/AliRoot.git] / HBTAN / AliHBTLLWeights.h

/* $Id$ */

// This class introduces the weight's calculation 
// according to the Lednicky's algorithm.
// The detailed description of the algorithm can be found 
// in comments to fortran code:
// fsiw.f, fsiini.f  

#ifndef ALIHBTLLWEIGHTS_H
#define ALIHBTLLWEIGHTS_H

#include <TObject.h>

class AliHBTPair;
class AliHBTLLWeights: public TObject
 {
   public:
     virtual ~AliHBTLLWeights(){;}
     static AliHBTLLWeights* Instance();
     
     Double_t GetWeight(const AliHBTPair* partpair); //get weight calculated by Lednicky's algorithm

     void Init(); //put the initial values in fortran commons fsiini, led_bldata
     void SetTest(Bool_t rtest = kTRUE);//Sets fTest member

     void SetColoumb(Bool_t col = kTRUE);//: (ICH in fortran code) Coulomb interaction between the two particles ON (OFF)
     void SetQuantumStatistics(Bool_t qss = kTRUE);//IQS: quantum statistics for the two particles ON (OFF) //if non-identical particles automatically off
     void SetStrongInterSwitch(Bool_t sis = kTRUE);//ISI: strong interaction between the two particles ON (OFF)
     void SetColWithResidNuclSwitch(Bool_t crn = kTRUE);//I3C: Coulomb interaction with residual nucleus ON (OFF)  
     void SetLambda(Double_t la){fOneMinusLambda=1.-la;}  //lambda=haoticity
     void SetApproxModel(Int_t ap);//sets  Model of Approximation (NS in Fortran code)
     void SetRandomPosition(Bool_t rp = kTRUE); //ON=kTRUE(OFF=kFALSE)
     void SetR1dw(Double_t R);   //spherical source model radii                                                                           		                                                                                                        
     void SetParticlesTypes(Int_t pid1, Int_t pid2); //set AliRoot particles types   
     void SetNucleusCharge(Double_t ch); // not used now  (see comments in fortran code)
     void SetNucleusMass(Double_t mass); // (see comments in fortran code)
     
   protected:
     
     Bool_t fTest;           //flag indicating if parameters listed below are to be calculated automatically (0)
                             //or 
     Bool_t fColoumbSwitch; 
     Bool_t fQuantStatSwitch; 
     Bool_t fStrongInterSwitch;//Switches strong interactions TRUE=ON
     Bool_t fColWithResidNuclSwitch;//Switches couloumb interaction 
                                    //with residual nucleus TRUE=ON          
     Double_t fNuclMass;   //mass of nucleus
     Double_t fNuclCharge; //charge of nucleus
     
     Bool_t   fRandomPosition;//flag indicating if positions of particles shuold be randomized according to parameters below
     Double_t fRadius;        //radius used for randomizing particle vertex position
     
     Double_t fOneMinusLambda; //1 - intercept parameter
     
     Int_t fApproximationModel; //approximation used to calculate Bethe-Salpeter amplitude see SetApproxModel for more comments

     Int_t fPID1;
     Int_t fPID2;
     Double_t fSigma; //constants for spherical source model in cm
     static const Double_t fgkWcons; //constant for fm->GeV conversion 1/0.1973

     static  AliHBTLLWeights *fgLLWeights;// pointer to wrapper of Fortran Lednicky code

     static Int_t GetPairCode(Int_t pid1,Int_t pid2);
     static Int_t GetPairCode(const AliHBTPair* partpair);//calculate automatically internal code 

   private:
     AliHBTLLWeights();
     AliHBTLLWeights(const AliHBTLLWeights &/*source*/);
     AliHBTLLWeights & operator=(const AliHBTLLWeights& /*source*/);
     
     ClassDef(AliHBTLLWeights,1)
 };

#endif
Commit	Line	Data
4fdf4eb3	1	/* $Id$ */
	2
	3	// This class introduces the weight's calculation
	4	// according to the Lednicky's algorithm.
	5	// The detailed description of the algorithm can be found
	6	// in comments to fortran code:
	7	// fsiw.f, fsiini.f
88cb7938	8
7f92929e	9	#ifndef ALIHBTLLWEIGHTS_H
	10	#define ALIHBTLLWEIGHTS_H
	11
	12	#include <TObject.h>
7f92929e	13
	14	class AliHBTPair;
	15	class AliHBTLLWeights: public TObject
88cb7938	16	{
	17	public:
	18	virtual ~AliHBTLLWeights(){;}
	19	static AliHBTLLWeights* Instance();
	20
	21	Double_t GetWeight(const AliHBTPair* partpair); //get weight calculated by Lednicky's algorithm
	22
	23	void Init(); //put the initial values in fortran commons fsiini, led_bldata
	24	void SetTest(Bool_t rtest = kTRUE);//Sets fTest member
4fdf4eb3	25
88cb7938	26	void SetColoumb(Bool_t col = kTRUE);//: (ICH in fortran code) Coulomb interaction between the two particles ON (OFF)
	27	void SetQuantumStatistics(Bool_t qss = kTRUE);//IQS: quantum statistics for the two particles ON (OFF) //if non-identical particles automatically off
	28	void SetStrongInterSwitch(Bool_t sis = kTRUE);//ISI: strong interaction between the two particles ON (OFF)
	29	void SetColWithResidNuclSwitch(Bool_t crn = kTRUE);//I3C: Coulomb interaction with residual nucleus ON (OFF)
526c2bd5	30	void SetLambda(Double_t la){fOneMinusLambda=1.-la;} //lambda=haoticity
88cb7938	31	void SetApproxModel(Int_t ap);//sets Model of Approximation (NS in Fortran code)
	32	void SetRandomPosition(Bool_t rp = kTRUE); //ON=kTRUE(OFF=kFALSE)
	33	void SetR1dw(Double_t R); //spherical source model radii
	34	void SetParticlesTypes(Int_t pid1, Int_t pid2); //set AliRoot particles types
	35	void SetNucleusCharge(Double_t ch); // not used now (see comments in fortran code)
	36	void SetNucleusMass(Double_t mass); // (see comments in fortran code)
526c2bd5	37
88cb7938	38	protected:
	39
	40	Bool_t fTest; //flag indicating if parameters listed below are to be calculated automatically (0)
	41	//or
	42	Bool_t fColoumbSwitch;
	43	Bool_t fQuantStatSwitch;
	44	Bool_t fStrongInterSwitch;//Switches strong interactions TRUE=ON
	45	Bool_t fColWithResidNuclSwitch;//Switches couloumb interaction
	46	//with residual nucleus TRUE=ON
	47	Double_t fNuclMass; //mass of nucleus
	48	Double_t fNuclCharge; //charge of nucleus
	49
	50	Bool_t fRandomPosition;//flag indicating if positions of particles shuold be randomized according to parameters below
	51	Double_t fRadius; //radius used for randomizing particle vertex position
526c2bd5	52
526c2bd5	53	Double_t fOneMinusLambda; //1 - intercept parameter
7f92929e	54
88cb7938	55	Int_t fApproximationModel; //approximation used to calculate Bethe-Salpeter amplitude see SetApproxModel for more comments
	56
	57	Int_t fPID1;
	58	Int_t fPID2;
	59	Double_t fSigma; //constants for spherical source model in cm
	60	static const Double_t fgkWcons; //constant for fm->GeV conversion 1/0.1973
	61
	62	static AliHBTLLWeights *fgLLWeights;// pointer to wrapper of Fortran Lednicky code
	63
	64	static Int_t GetPairCode(Int_t pid1,Int_t pid2);
	65	static Int_t GetPairCode(const AliHBTPair* partpair);//calculate automatically internal code
	66
	67	private:
	68	AliHBTLLWeights();
111e505b	69	AliHBTLLWeights(const AliHBTLLWeights &/source/);
	70	AliHBTLLWeights & operator=(const AliHBTLLWeights& /source/);
	71
88cb7938	72	ClassDef(AliHBTLLWeights,1)
7f92929e	73	};
	74
	75	#endif