[u/mrichter/AliRoot.git] / STEER / AliESDkink.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.                  *
 **************************************************************************/

/* $Id$ */

//-------------------------------------------------------------------------
//    Origin: Marian Ivanov marian.ivanov@cern.ch
//-------------------------------------------------------------------------

#include <Riostream.h>
#include <TMath.h>
#include <TPDGCode.h>
#include "AliESDkink.h"
#include "AliHelix.h"


ClassImp(AliESDkink)

//____________________________________________________________________
AliESDkink::AliESDkink() :
  TObject(),
  fID(0),
  fParamDaughter(),
  fParamMother(),
  fDist1(-1),
  fDist2(-1),
  fRr(-1),
  fShapeFactor(0),
  fRow0(-1)
{
  //
  //Dafault constructor
  //
  for (Int_t i=0;i<12;i++) fStatus[i]=0;
  for (Int_t i=0;i<2;i++)
    for (Int_t j=0;j<2;j++){
      fTPCdensity[i][j]=-1;
      fTPCdensity2[i][j]=-1;
    }
  fTPCncls[0]=0;
  fTPCncls[1]=0;
}

void AliESDkink::SetMother(const AliExternalTrackParam & pmother)  {
  //
  // set mother
  //
  fParamMother   = pmother;
}

void AliESDkink::SetDaughter(const AliExternalTrackParam & pdaughter){
  //
  //set daughter
  //
  fParamDaughter = pdaughter;

}
  
void  AliESDkink::Update()
{
  //
  // updates Kink Info
  //
  Float_t distance2=1000;
  //
  AliHelix dhelix1(fParamDaughter);
  AliHelix mhelix(fParamMother);    
  //
  //find intersection linear
  //
  Double_t phase[2][2],radius[2];
  Double_t delta1=10000,delta2=10000;  
  Int_t points=0;
  /*
    Float_t distance1=0;
  Int_t  points = dhelix1.GetRPHIintersections(mhelix, phase, radius,200);
  
  if (points>0){
    dhelix1.LinearDCA(mhelix,phase[0][0],phase[0][1],radius[0],delta1);
  }
  if (points==2){    
    dhelix1.LinearDCA(mhelix,phase[1][0],phase[1][1],radius[1],delta2);
  }
  distance1 = TMath::Min(delta1,delta2);
  */
  //
  //find intersection parabolic
  //
  points = dhelix1.GetRPHIintersections(mhelix, phase, radius,7);

  delta1=10000,delta2=10000;  
  Double_t d1=1000.,d2=10000.;
  if (points>0){
    dhelix1.ParabolicDCA(mhelix,phase[0][0],phase[0][1],radius[0],delta1,6);
    //    dhelix1.ParabolicDCA(mhelix,phase[0][0],phase[0][1],radius[0],delta1);
    Double_t xd[3],xm[3];
    dhelix1.Evaluate(phase[0][0],xd);
    mhelix.Evaluate(phase[0][1],xm);
    d1 = (xd[0]-xm[0])*(xd[0]-xm[0])+(xd[1]-xm[1])*(xd[1]-xm[1])+(xd[2]-xm[2])*(xd[2]-xm[2]);
  }
  if (points==2){    
    dhelix1.ParabolicDCA(mhelix,phase[1][0],phase[1][1],radius[1],delta2,6);
    //dhelix1.ParabolicDCA(mhelix,phase[1][0],phase[1][1],radius[1],delta2);
    Double_t xd[3],xm[3];
    dhelix1.Evaluate(phase[1][0],xd);
    mhelix.Evaluate(phase[1][1],xm);
    d2 = (xd[0]-xm[0])*(xd[0]-xm[0])+(xd[1]-xm[1])*(xd[1]-xm[1])+(xd[2]-xm[2])*(xd[2]-xm[2]);
  }
  //
  distance2 = TMath::Min(delta1,delta2);
  if (delta1<delta2){
    //get V0 info
    //    dhelix1.Evaluate(phase[0][0],fXr);
    Double_t xd[3],xm[3];
    dhelix1.Evaluate(phase[0][0],xd);
    mhelix.Evaluate(phase[0][1], xm);
    fXr[0] = 0.5*(xd[0]+xm[0]);
    fXr[1] = 0.5*(xd[1]+xm[1]);
    fXr[2] = 0.5*(xd[2]+xm[2]);
    //
    dhelix1.GetMomentum(phase[0][0],fPdr);
    mhelix.GetMomentum(phase[0][1],fPm);
    dhelix1.GetAngle(phase[0][0],mhelix,phase[0][1],fAngle);
    //fRr = TMath::Sqrt(radius[0]);
    fRr = TMath::Sqrt(fXr[0]*fXr[0]+fXr[1]*fXr[1]);
  }
  else{
    //dhelix1.Evaluate(phase[1][0],fXr);
    Double_t xd[3],xm[3];
    dhelix1.Evaluate(phase[1][0],xd);
    mhelix.Evaluate(phase[1][1], xm);
    fXr[0] = 0.5*(xd[0]+xm[0]);
    fXr[1] = 0.5*(xd[1]+xm[1]);
    fXr[2] = 0.5*(xd[2]+xm[2]);
    //
    dhelix1.GetMomentum(phase[1][0], fPdr);
    mhelix.GetMomentum(phase[1][1], fPm);
    dhelix1.GetAngle(phase[1][0],mhelix,phase[1][1],fAngle);
    //    fRr = TMath::Sqrt(radius[1]); 
    fRr = TMath::Sqrt(fXr[0]*fXr[0]+fXr[1]*fXr[1]);
  }
  fDist1 = TMath::Sqrt(TMath::Min(d1,d2));
  fDist2 = TMath::Sqrt(distance2);      
  //            
  //

}

 
Float_t AliESDkink::GetTPCDensityFactor() const
{
  //
  //
  return fTPCdensity[0][0]+fTPCdensity[1][1]-TMath::Max(fTPCdensity[0][1],Float_t(0.0))-TMath::Max(fTPCdensity[1][0],Float_t(0.0)); 
}

Float_t AliESDkink::GetQt() const
{
  Float_t dmomentum = TMath::Sqrt(fPdr[0]*fPdr[0]+fPdr[1]*fPdr[1]+fPdr[2]*fPdr[2]);
  return TMath::Sin(fAngle[2])*dmomentum;
}
Commit	Line	Data
51ad6848	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	// Origin: Marian Ivanov marian.ivanov@cern.ch
	20	//-------------------------------------------------------------------------
	21
	22	#include <Riostream.h>
	23	#include <TMath.h>
	24	#include <TPDGCode.h>
	25	#include "AliESDkink.h"
	26	#include "AliHelix.h"
	27
	28
	29	ClassImp(AliESDkink)
	30
90e48c0c	31	//____________________________________________________________________
	32	AliESDkink::AliESDkink() :
	33	TObject(),
	34	fID(0),
	35	fParamDaughter(),
	36	fParamMother(),
	37	fDist1(-1),
	38	fDist2(-1),
	39	fRr(-1),
	40	fShapeFactor(0),
	41	fRow0(-1)
	42	{
51ad6848	43	//
	44	//Dafault constructor
	45	//
7c97ee80	46	for (Int_t i=0;i<12;i++) fStatus[i]=0;
7c97ee80	47	for (Int_t i=0;i<2;i++)
	48	for (Int_t j=0;j<2;j++){
	49	fTPCdensity[i][j]=-1;
	50	fTPCdensity2[i][j]=-1;
	51	}
	52	fTPCncls[0]=0;
	53	fTPCncls[1]=0;
51ad6848	54	}
	55
	56	void AliESDkink::SetMother(const AliExternalTrackParam & pmother) {
	57	//
	58	// set mother
	59	//
	60	fParamMother = pmother;
	61	}
	62
	63	void AliESDkink::SetDaughter(const AliExternalTrackParam & pdaughter){
	64	//
	65	//set daughter
	66	//
	67	fParamDaughter = pdaughter;
	68
	69	}
	70
	71	void AliESDkink::Update()
	72	{
	73	//
	74	// updates Kink Info
	75	//
7c97ee80	76	Float_t distance2=1000;
51ad6848	77	//
	78	AliHelix dhelix1(fParamDaughter);
	79	AliHelix mhelix(fParamMother);
	80	//
	81	//find intersection linear
	82	//
	83	Double_t phase[2][2],radius[2];
51ad6848	84	Double_t delta1=10000,delta2=10000;
7c97ee80	85	Int_t points=0;
	86	/*
	87	Float_t distance1=0;
	88	Int_t points = dhelix1.GetRPHIintersections(mhelix, phase, radius,200);
51ad6848	89
	90	if (points>0){
	91	dhelix1.LinearDCA(mhelix,phase[0][0],phase[0][1],radius[0],delta1);
51ad6848	92	}
	93	if (points==2){
	94	dhelix1.LinearDCA(mhelix,phase[1][0],phase[1][1],radius[1],delta2);
51ad6848	95	}
51ad6848	96	distance1 = TMath::Min(delta1,delta2);
7c97ee80	97	*/
51ad6848	98	//
	99	//find intersection parabolic
	100	//
7c97ee80	101	points = dhelix1.GetRPHIintersections(mhelix, phase, radius,7);
7c97ee80	102
51ad6848	103	delta1=10000,delta2=10000;
	104	Double_t d1=1000.,d2=10000.;
	105	if (points>0){
7c97ee80	106	dhelix1.ParabolicDCA(mhelix,phase[0][0],phase[0][1],radius[0],delta1,6);
7c97ee80	107	// dhelix1.ParabolicDCA(mhelix,phase[0][0],phase[0][1],radius[0],delta1);
51ad6848	108	Double_t xd[3],xm[3];
	109	dhelix1.Evaluate(phase[0][0],xd);
	110	mhelix.Evaluate(phase[0][1],xm);
	111	d1 = (xd[0]-xm[0])(xd[0]-xm[0])+(xd[1]-xm[1])(xd[1]-xm[1])+(xd[2]-xm[2])*(xd[2]-xm[2]);
	112	}
	113	if (points==2){
7c97ee80	114	dhelix1.ParabolicDCA(mhelix,phase[1][0],phase[1][1],radius[1],delta2,6);
7c97ee80	115	//dhelix1.ParabolicDCA(mhelix,phase[1][0],phase[1][1],radius[1],delta2);
51ad6848	116	Double_t xd[3],xm[3];
	117	dhelix1.Evaluate(phase[1][0],xd);
	118	mhelix.Evaluate(phase[1][1],xm);
	119	d2 = (xd[0]-xm[0])(xd[0]-xm[0])+(xd[1]-xm[1])(xd[1]-xm[1])+(xd[2]-xm[2])*(xd[2]-xm[2]);
	120	}
	121	//
	122	distance2 = TMath::Min(delta1,delta2);
	123	if (delta1<delta2){
	124	//get V0 info
	125	// dhelix1.Evaluate(phase[0][0],fXr);
	126	Double_t xd[3],xm[3];
	127	dhelix1.Evaluate(phase[0][0],xd);
	128	mhelix.Evaluate(phase[0][1], xm);
	129	fXr[0] = 0.5*(xd[0]+xm[0]);
	130	fXr[1] = 0.5*(xd[1]+xm[1]);
	131	fXr[2] = 0.5*(xd[2]+xm[2]);
	132	//
	133	dhelix1.GetMomentum(phase[0][0],fPdr);
	134	mhelix.GetMomentum(phase[0][1],fPm);
	135	dhelix1.GetAngle(phase[0][0],mhelix,phase[0][1],fAngle);
	136	//fRr = TMath::Sqrt(radius[0]);
	137	fRr = TMath::Sqrt(fXr[0]fXr[0]+fXr[1]fXr[1]);
	138	}
	139	else{
	140	//dhelix1.Evaluate(phase[1][0],fXr);
	141	Double_t xd[3],xm[3];
	142	dhelix1.Evaluate(phase[1][0],xd);
	143	mhelix.Evaluate(phase[1][1], xm);
	144	fXr[0] = 0.5*(xd[0]+xm[0]);
	145	fXr[1] = 0.5*(xd[1]+xm[1]);
	146	fXr[2] = 0.5*(xd[2]+xm[2]);
	147	//
	148	dhelix1.GetMomentum(phase[1][0], fPdr);
	149	mhelix.GetMomentum(phase[1][1], fPm);
	150	dhelix1.GetAngle(phase[1][0],mhelix,phase[1][1],fAngle);
	151	// fRr = TMath::Sqrt(radius[1]);
	152	fRr = TMath::Sqrt(fXr[0]fXr[0]+fXr[1]fXr[1]);
	153	}
	154	fDist1 = TMath::Sqrt(TMath::Min(d1,d2));
	155	fDist2 = TMath::Sqrt(distance2);
	156	//
	157	//
	158
	159	}
	160
	161
	162	Float_t AliESDkink::GetTPCDensityFactor() const
	163	{
	164	//
	165	//
	166	return fTPCdensity[0][0]+fTPCdensity[1][1]-TMath::Max(fTPCdensity[0][1],Float_t(0.0))-TMath::Max(fTPCdensity[1][0],Float_t(0.0));
	167	}
	168
	169	Float_t AliESDkink::GetQt() const
	170	{
	171	Float_t dmomentum = TMath::Sqrt(fPdr[0]fPdr[0]+fPdr[1]fPdr[1]+fPdr[2]*fPdr[2]);
	172	return TMath::Sin(fAngle[2])*dmomentum;
	173	}