// set of classes and contains information about
// V0 kind vertexes generated by a neutral particle
// Origin: Iouri Belikov, IReS, Strasbourg, Jouri.Belikov@cern.ch
+// Modified by: Marian Ivanov, CERN, Marian.Ivanov@cern.ch
+// and Boris Hippolyte,IPHC, hippolyt@in2p3.fr
//-------------------------------------------------------------------------
-#include <Riostream.h>
#include <TMath.h>
-#include <TPDGCode.h>
+#include <TDatabasePDG.h>
+#include <TParticlePDG.h>
+#include <TVector3.h>
+#include "AliLog.h"
#include "AliESDv0.h"
+#include "AliESDV0Params.h"
ClassImp(AliESDv0)
-AliESDv0::AliESDv0() : TObject() {
+const AliESDV0Params AliESDv0::fgkParams;
+
+AliESDv0::AliESDv0() :
+ AliVParticle(),
+ fParamN(),
+ fParamP(),
+ fEffMass(TDatabasePDG::Instance()->GetParticle(kK0Short)->Mass()),
+ fDcaV0Daughters(0),
+ fChi2V0(0.),
+ fRr(0),
+ fDistSigma(0),
+ fChi2Before(0),
+ fChi2After(0),
+ fPointAngleFi(0),
+ fPointAngleTh(0),
+ fPointAngle(0),
+ fPdgCode(kK0Short),
+ fNidx(0),
+ fPidx(0),
+ fStatus(0),
+ fNBefore(0),
+ fNAfter(0),
+ fOnFlyStatus(kFALSE)
+{
//--------------------------------------------------------------------
// Default constructor (K0s)
//--------------------------------------------------------------------
- fPdgCode=kK0Short;
- fEffMass=0.497672;
- fChi2=1.e+33;
- fPos[0]=fPos[1]=fPos[2]=0.;
- fPosCov[0]=fPosCov[1]=fPosCov[2]=fPosCov[3]=fPosCov[4]=fPosCov[5]=0.;
+
+ for (Int_t i=0; i<3; i++) {
+ fPos[i] = 0.;
+ fNmom[i] = 0.;
+ fPmom[i] = 0.;
+ }
+
+ for (Int_t i=0; i<6; i++) {
+ fPosCov[i]= 0.;
+ }
+
+ for (Int_t i=0;i<6;i++){fClusters[0][i]=0; fClusters[1][i]=0;}
+ fNormDCAPrim[0]=fNormDCAPrim[1]=0;
+ for (Int_t i=0;i<3;i++){fAngle[i]=0;}
+ for (Int_t i=0;i<4;i++){fCausality[i]=0;}
+}
+
+AliESDv0::AliESDv0(const AliESDv0& v0) :
+ AliVParticle(v0),
+ fParamN(v0.fParamN),
+ fParamP(v0.fParamP),
+ fEffMass(v0.fEffMass),
+ fDcaV0Daughters(v0.fDcaV0Daughters),
+ fChi2V0(v0.fChi2V0),
+ fRr(v0.fRr),
+ fDistSigma(v0.fDistSigma),
+ fChi2Before(v0.fChi2Before),
+ fChi2After(v0.fChi2After),
+ fPointAngleFi(v0.fPointAngleFi),
+ fPointAngleTh(v0.fPointAngleTh),
+ fPointAngle(v0.fPointAngle),
+ fPdgCode(v0.fPdgCode),
+ fNidx(v0.fNidx),
+ fPidx(v0.fPidx),
+ fStatus(v0.fStatus),
+ fNBefore(v0.fNBefore),
+ fNAfter(v0.fNAfter),
+ fOnFlyStatus(v0.fOnFlyStatus)
+{
+ //--------------------------------------------------------------------
+ // The copy constructor
+ //--------------------------------------------------------------------
+
+ for (int i=0; i<3; i++) {
+ fPos[i] = v0.fPos[i];
+ fNmom[i] = v0.fNmom[i];
+ fPmom[i] = v0.fPmom[i];
+ }
+ for (int i=0; i<6; i++) {
+ fPosCov[i] = v0.fPosCov[i];
+ }
+
+ for (Int_t i=0; i<2; i++) {
+ fNormDCAPrim[i]=v0.fNormDCAPrim[i];
+ }
+ for (Int_t i=0;i<6;i++){
+ fClusters[0][i]=v0.fClusters[0][i];
+ fClusters[1][i]=v0.fClusters[1][i];
+ }
+ for (Int_t i=0;i<3;i++){
+ fAngle[i]=v0.fAngle[i];
+ }
+ for (Int_t i=0;i<4;i++){fCausality[i]=v0.fCausality[i];}
+}
+
+
+AliESDv0::AliESDv0(const AliExternalTrackParam &t1, Int_t i1,
+ const AliExternalTrackParam &t2, Int_t i2) :
+ AliVParticle(),
+ fParamN(t1),
+ fParamP(t2),
+ fEffMass(TDatabasePDG::Instance()->GetParticle(kK0Short)->Mass()),
+ fDcaV0Daughters(0),
+ fChi2V0(0.),
+ fRr(0),
+ fDistSigma(0),
+ fChi2Before(0),
+ fChi2After(0),
+ fPointAngleFi(0),
+ fPointAngleTh(0),
+ fPointAngle(0),
+ fPdgCode(kK0Short),
+ fNidx(i1),
+ fPidx(i2),
+ fStatus(0),
+ fNBefore(0),
+ fNAfter(0),
+ fOnFlyStatus(kFALSE)
+{
+ //--------------------------------------------------------------------
+ // Main constructor (K0s)
+ //--------------------------------------------------------------------
+
+ for (Int_t i=0; i<6; i++) {
+ fPosCov[i]= 0.;
+ }
+
+ //Trivial estimation of the vertex parameters
+ Double_t alpha=t1.GetAlpha(), cs=TMath::Cos(alpha), sn=TMath::Sin(alpha);
+ Double_t tmp[3];
+ t1.GetPxPyPz(tmp);
+ Double_t px1=tmp[0], py1=tmp[1], pz1=tmp[2];
+ t1.GetXYZ(tmp);
+ Double_t x1=tmp[0], y1=tmp[1], z1=tmp[2];
+ const Double_t ss=0.0005*0.0005;//a kind of a residual misalignment precision
+ Double_t sx1=sn*sn*t1.GetSigmaY2()+ss, sy1=cs*cs*t1.GetSigmaY2()+ss;
+
+
+ alpha=t2.GetAlpha(); cs=TMath::Cos(alpha); sn=TMath::Sin(alpha);
+ t2.GetPxPyPz(tmp);
+ Double_t px2=tmp[0], py2=tmp[1], pz2=tmp[2];
+ t2.GetXYZ(tmp);
+ Double_t x2=tmp[0], y2=tmp[1], z2=tmp[2];
+ Double_t sx2=sn*sn*t2.GetSigmaY2()+ss, sy2=cs*cs*t2.GetSigmaY2()+ss;
+
+ Double_t sz1=t1.GetSigmaZ2(), sz2=t2.GetSigmaZ2();
+ Double_t wx1=sx2/(sx1+sx2), wx2=1.- wx1;
+ Double_t wy1=sy2/(sy1+sy2), wy2=1.- wy1;
+ Double_t wz1=sz2/(sz1+sz2), wz2=1.- wz1;
+ fPos[0]=wx1*x1 + wx2*x2; fPos[1]=wy1*y1 + wy2*y2; fPos[2]=wz1*z1 + wz2*z2;
+
+ //fPos[0]=0.5*(x1+x2); fPos[1]=0.5*(y1+y2); fPos[2]=0.5*(z1+z2);
+ fNmom[0]=px1; fNmom[1]=py1; fNmom[2]=pz1;
+ fPmom[0]=px2; fPmom[1]=py2; fPmom[2]=pz2;
+
+ for (Int_t i=0;i<6;i++){fClusters[0][i]=0; fClusters[1][i]=0;}
+ fNormDCAPrim[0]=fNormDCAPrim[1]=0;
+ for (Int_t i=0;i<3;i++){fAngle[i]=0;}
+ for (Int_t i=0;i<4;i++){fCausality[i]=0;}
+}
+
+AliESDv0& AliESDv0::operator=(const AliESDv0 &v0)
+{
+ //--------------------------------------------------------------------
+ // The assignment operator
+ //--------------------------------------------------------------------
+
+ if(this==&v0)return *this;
+ AliVParticle::operator=(v0);
+ fParamN = v0.fParamN;
+ fParamP = v0.fParamP;
+ fEffMass = v0.fEffMass;
+ fDcaV0Daughters = v0.fDcaV0Daughters;
+ fChi2V0 = v0.fChi2V0;
+ fRr = v0.fRr;
+ fDistSigma = v0.fDistSigma;
+ fChi2Before = v0.fChi2Before;
+ fChi2After = v0.fChi2After;
+ fPointAngleFi = v0.fPointAngleFi;
+ fPointAngleTh = v0.fPointAngleTh;
+ fPointAngle = v0.fPointAngle;
+ fPdgCode = v0.fPdgCode;
+ fNidx = v0.fNidx;
+ fPidx = v0.fPidx;
+ fStatus = v0.fStatus;
+ fNBefore = v0.fNBefore;
+ fNAfter = v0.fNAfter;
+ fOnFlyStatus = v0.fOnFlyStatus;
+
+ for (int i=0; i<3; i++) {
+ fPos[i] = v0.fPos[i];
+ fNmom[i] = v0.fNmom[i];
+ fPmom[i] = v0.fPmom[i];
+ }
+ for (int i=0; i<6; i++) {
+ fPosCov[i] = v0.fPosCov[i];
+ }
+ for (Int_t i=0; i<2; i++) {
+ fNormDCAPrim[i]=v0.fNormDCAPrim[i];
+ }
+ for (Int_t i=0;i<6;i++){
+ fClusters[0][i]=v0.fClusters[0][i];
+ fClusters[1][i]=v0.fClusters[1][i];
+ }
+ for (Int_t i=0;i<3;i++){
+ fAngle[i]=v0.fAngle[i];
+ }
+ for (Int_t i=0;i<4;i++){fCausality[i]=v0.fCausality[i];}
+
+ return *this;
+}
+
+void AliESDv0::Copy(TObject& obj) const {
+
+ // this overwrites the virtual TOBject::Copy()
+ // to allow run time copying without casting
+ // in AliESDEvent
+
+ if(this==&obj)return;
+ AliESDv0 *robj = dynamic_cast<AliESDv0*>(&obj);
+ if(!robj)return; // not an aliesesv0
+ *robj = *this;
+}
+
+AliESDv0::~AliESDv0(){
+ //--------------------------------------------------------------------
+ // Empty destructor
+ //--------------------------------------------------------------------
+}
+
+// Start with AliVParticle functions
+Double_t AliESDv0::E() const {
+ //--------------------------------------------------------------------
+ // This gives the energy assuming the ChangeMassHypothesis was called
+ //--------------------------------------------------------------------
+ return E(fPdgCode);
+}
+
+Double_t AliESDv0::Y() const {
+ //--------------------------------------------------------------------
+ // This gives the energy assuming the ChangeMassHypothesis was called
+ //--------------------------------------------------------------------
+ return Y(fPdgCode);
+}
+
+// Then extend AliVParticle functions
+Double_t AliESDv0::E(Int_t pdg) const {
+ //--------------------------------------------------------------------
+ // This gives the energy with the particle hypothesis as argument
+ //--------------------------------------------------------------------
+ Double_t mass = TDatabasePDG::Instance()->GetParticle(pdg)->Mass();
+ return TMath::Sqrt(mass*mass+P()*P());
+}
+
+Double_t AliESDv0::Y(Int_t pdg) const {
+ //--------------------------------------------------------------------
+ // This gives the rapidity with the particle hypothesis as argument
+ //--------------------------------------------------------------------
+ return 0.5*TMath::Log((E(pdg)+Pz())/(E(pdg)-Pz()+1.e-13));
+}
+
+// Now the functions for analysis consistency
+Double_t AliESDv0::RapK0Short() const {
+ //--------------------------------------------------------------------
+ // This gives the pseudorapidity assuming a K0s particle
+ //--------------------------------------------------------------------
+ return Y(kK0Short);
+}
+
+Double_t AliESDv0::RapLambda() const {
+ //--------------------------------------------------------------------
+ // This gives the pseudorapidity assuming a (Anti) Lambda particle
+ //--------------------------------------------------------------------
+ return Y(kLambda0);
+}
+
+Double_t AliESDv0::AlphaV0() const {
+ //--------------------------------------------------------------------
+ // This gives the Armenteros-Podolanski alpha
+ //--------------------------------------------------------------------
+ TVector3 momNeg(fNmom[0],fNmom[1],fNmom[2]);
+ TVector3 momPos(fPmom[0],fPmom[1],fPmom[2]);
+ TVector3 momTot(Px(),Py(),Pz());
+
+ Double_t lQlNeg = momNeg.Dot(momTot)/momTot.Mag();
+ Double_t lQlPos = momPos.Dot(momTot)/momTot.Mag();
+
+ return 1.-2./(1.+lQlNeg/lQlPos);
+}
+
+Double_t AliESDv0::PtArmV0() const {
+ //--------------------------------------------------------------------
+ // This gives the Armenteros-Podolanski ptarm
+ //--------------------------------------------------------------------
+ TVector3 momNeg(fNmom[0],fNmom[1],fNmom[2]);
+ TVector3 momTot(Px(),Py(),Pz());
+
+ return momNeg.Perp(momTot);
}
+// Eventually the older functions
Double_t AliESDv0::ChangeMassHypothesis(Int_t code) {
//--------------------------------------------------------------------
// This function changes the mass hypothesis for this V0
// and returns the "kinematical quality" of this hypothesis
//--------------------------------------------------------------------
- Double_t nmass=0.13957, pmass=0.13957, mass=0.49767, ps=0.206;
+ static
+ Double_t piMass=TDatabasePDG::Instance()->GetParticle(kPiPlus)->Mass();
+ static
+ Double_t prMass=TDatabasePDG::Instance()->GetParticle(kProton)->Mass();
+ static
+ Double_t k0Mass=TDatabasePDG::Instance()->GetParticle(kK0Short)->Mass();
+ static
+ Double_t l0Mass=TDatabasePDG::Instance()->GetParticle(kLambda0)->Mass();
+
+ Double_t nmass=piMass, pmass=piMass, mass=k0Mass, ps=0.206;
fPdgCode=code;
switch (code) {
case kLambda0:
- nmass=0.13957; pmass=0.93827; mass=1.1157; ps=0.101; break;
+ nmass=piMass; pmass=prMass; mass=l0Mass; ps=0.101; break;
case kLambda0Bar:
- pmass=0.13957; nmass=0.93827; mass=1.1157; ps=0.101; break;
+ pmass=piMass; nmass=prMass; mass=l0Mass; ps=0.101; break;
case kK0Short:
break;
default:
- cerr<<"AliV0vertex::ChangeMassHypothesis: ";
- cerr<<"invalide PDG code ! Assuming K0s...\n";
+ AliError("invalide PDG code ! Assuming K0s...");
fPdgCode=kK0Short;
break;
}
z=fPos[2];
}
-Double_t AliESDv0::GetD(Double_t x0, Double_t y0, Double_t z0) const {
+Float_t AliESDv0::GetD(Double_t x0, Double_t y0, Double_t z0) const {
//--------------------------------------------------------------------
// This function returns V0's impact parameter
//--------------------------------------------------------------------
Double_t d=TMath::Sqrt((dx*dx+dy*dy+dz*dz)/(px*px+py*py+pz*pz));
return d;
}
+
+Float_t AliESDv0::GetV0CosineOfPointingAngle(Double_t refPointX, Double_t refPointY, Double_t refPointZ) const {
+ // calculates the pointing angle of the V0 wrt a reference point
+
+ Double_t momV0[3]; //momentum of the V0
+ GetPxPyPz(momV0[0],momV0[1],momV0[2]);
+
+ Double_t deltaPos[3]; //vector between the reference point and the V0 vertex
+ deltaPos[0] = fPos[0] - refPointX;
+ deltaPos[1] = fPos[1] - refPointY;
+ deltaPos[2] = fPos[2] - refPointZ;
+
+ Double_t momV02 = momV0[0]*momV0[0] + momV0[1]*momV0[1] + momV0[2]*momV0[2];
+ Double_t deltaPos2 = deltaPos[0]*deltaPos[0] + deltaPos[1]*deltaPos[1] + deltaPos[2]*deltaPos[2];
+
+ Double_t cosinePointingAngle = (deltaPos[0]*momV0[0] +
+ deltaPos[1]*momV0[1] +
+ deltaPos[2]*momV0[2] ) /
+ TMath::Sqrt(momV02 * deltaPos2);
+
+ return cosinePointingAngle;
+}
+
+
+// **** The following functions need to be revised
+
+void AliESDv0::GetPosCov(Double_t cov[6]) const {
+
+ for (Int_t i=0; i<6; ++i) cov[i] = fPosCov[i];
+
+}
+
+Double_t AliESDv0::GetSigmaY(){
+ //
+ // return sigmay in y at vertex position using covariance matrix
+ //
+ const Double_t * cp = fParamP.GetCovariance();
+ const Double_t * cm = fParamN.GetCovariance();
+ Double_t sigmay = cp[0]+cm[0]+ cp[5]*(fParamP.GetX()-fRr)*(fParamP.GetX()-fRr)+ cm[5]*(fParamN.GetX()-fRr)*(fParamN.GetX()-fRr);
+ return (sigmay>0) ? TMath::Sqrt(sigmay):100;
+}
+
+Double_t AliESDv0::GetSigmaZ(){
+ //
+ // return sigmay in y at vertex position using covariance matrix
+ //
+ const Double_t * cp = fParamP.GetCovariance();
+ const Double_t * cm = fParamN.GetCovariance();
+ Double_t sigmaz = cp[2]+cm[2]+ cp[9]*(fParamP.GetX()-fRr)*(fParamP.GetX()-fRr)+ cm[9]*(fParamN.GetX()-fRr)*(fParamN.GetX()-fRr);
+ return (sigmaz>0) ? TMath::Sqrt(sigmaz):100;
+}
+
+Double_t AliESDv0::GetSigmaD0(){
+ //
+ // Sigma parameterization using covariance matrix
+ //
+ // sigma of distance between two tracks in vertex position
+ // sigma of DCA is proportianal to sigmaD0
+ // factor 2 difference is explained by the fact that the DCA is calculated at the position
+ // where the tracks as closest together ( not exact position of the vertex)
+ //
+ const Double_t * cp = fParamP.GetCovariance();
+ const Double_t * cm = fParamN.GetCovariance();
+ Double_t sigmaD0 = cp[0]+cm[0]+cp[2]+cm[2]+fgkParams.fPSigmaOffsetD0*fgkParams.fPSigmaOffsetD0;
+ sigmaD0 += ((fParamP.GetX()-fRr)*(fParamP.GetX()-fRr))*(cp[5]+cp[9]);
+ sigmaD0 += ((fParamN.GetX()-fRr)*(fParamN.GetX()-fRr))*(cm[5]+cm[9]);
+ return (sigmaD0>0)? TMath::Sqrt(sigmaD0):100;
+}
+
+
+Double_t AliESDv0::GetSigmaAP0(){
+ //
+ //Sigma parameterization using covariance matrices
+ //
+ Double_t prec = TMath::Sqrt((fNmom[0]+fPmom[0])*(fNmom[0]+fPmom[0])
+ +(fNmom[1]+fPmom[1])*(fNmom[1]+fPmom[1])
+ +(fNmom[2]+fPmom[2])*(fNmom[2]+fPmom[2]));
+ Double_t normp = TMath::Sqrt(fPmom[0]*fPmom[0]+fPmom[1]*fPmom[1]+fPmom[2]*fPmom[2])/prec; // fraction of the momenta
+ Double_t normm = TMath::Sqrt(fNmom[0]*fNmom[0]+fNmom[1]*fNmom[1]+fNmom[2]*fNmom[2])/prec;
+ const Double_t * cp = fParamP.GetCovariance();
+ const Double_t * cm = fParamN.GetCovariance();
+ Double_t sigmaAP0 = fgkParams.fPSigmaOffsetAP0*fgkParams.fPSigmaOffsetAP0; // minimal part
+ sigmaAP0 += (cp[5]+cp[9])*(normp*normp)+(cm[5]+cm[9])*(normm*normm); // angular resolution part
+ Double_t sigmaAP1 = GetSigmaD0()/(TMath::Abs(fRr)+0.01); // vertex position part
+ sigmaAP0 += 0.5*sigmaAP1*sigmaAP1;
+ return (sigmaAP0>0)? TMath::Sqrt(sigmaAP0):100;
+}
+
+Double_t AliESDv0::GetEffectiveSigmaD0(){
+ //
+ // minimax - effective Sigma parameterization
+ // p12 effective curvature and v0 radius postion used as parameters
+ //
+ Double_t p12 = TMath::Sqrt(fParamP.GetParameter()[4]*fParamP.GetParameter()[4]+
+ fParamN.GetParameter()[4]*fParamN.GetParameter()[4]);
+ Double_t sigmaED0= TMath::Max(TMath::Sqrt(fRr)-fgkParams.fPSigmaRminDE,0.0)*fgkParams.fPSigmaCoefDE*p12*p12;
+ sigmaED0*= sigmaED0;
+ sigmaED0*= sigmaED0;
+ sigmaED0 = TMath::Sqrt(sigmaED0+fgkParams.fPSigmaOffsetDE*fgkParams.fPSigmaOffsetDE);
+ return (sigmaED0<fgkParams.fPSigmaMaxDE) ? sigmaED0: fgkParams.fPSigmaMaxDE;
+}
+
+
+Double_t AliESDv0::GetEffectiveSigmaAP0(){
+ //
+ // effective Sigma parameterization of point angle resolution
+ //
+ Double_t p12 = TMath::Sqrt(fParamP.GetParameter()[4]*fParamP.GetParameter()[4]+
+ fParamN.GetParameter()[4]*fParamN.GetParameter()[4]);
+ Double_t sigmaAPE= fgkParams.fPSigmaBase0APE;
+ sigmaAPE+= fgkParams.fPSigmaR0APE/(fgkParams.fPSigmaR1APE+fRr);
+ sigmaAPE*= (fgkParams.fPSigmaP0APE+fgkParams.fPSigmaP1APE*p12);
+ sigmaAPE = TMath::Min(sigmaAPE,fgkParams.fPSigmaMaxAPE);
+ return sigmaAPE;
+}
+
+
+Double_t AliESDv0::GetMinimaxSigmaAP0(){
+ //
+ // calculate mini-max effective sigma of point angle resolution
+ //
+ //compv0->fTree->SetAlias("SigmaAP2","max(min((SigmaAP0+SigmaAPE0)*0.5,1.5*SigmaAPE0),0.5*SigmaAPE0+0.003)");
+ Double_t effectiveSigma = GetEffectiveSigmaAP0();
+ Double_t sigmaMMAP = 0.5*(GetSigmaAP0()+effectiveSigma);
+ sigmaMMAP = TMath::Min(sigmaMMAP, fgkParams.fPMaxFractionAP0*effectiveSigma);
+ sigmaMMAP = TMath::Max(sigmaMMAP, fgkParams.fPMinFractionAP0*effectiveSigma+fgkParams.fPMinAP0);
+ return sigmaMMAP;
+}
+Double_t AliESDv0::GetMinimaxSigmaD0(){
+ //
+ // calculate mini-max sigma of dca resolution
+ //
+ //compv0->fTree->SetAlias("SigmaD2","max(min((SigmaD0+SigmaDE0)*0.5,1.5*SigmaDE0),0.5*SigmaDE0)");
+ Double_t effectiveSigma = GetEffectiveSigmaD0();
+ Double_t sigmaMMD0 = 0.5*(GetSigmaD0()+effectiveSigma);
+ sigmaMMD0 = TMath::Min(sigmaMMD0, fgkParams.fPMaxFractionD0*effectiveSigma);
+ sigmaMMD0 = TMath::Max(sigmaMMD0, fgkParams.fPMinFractionD0*effectiveSigma+fgkParams.fPMinD0);
+ return sigmaMMD0;
+}
+
+
+Double_t AliESDv0::GetLikelihoodAP(Int_t mode0, Int_t mode1){
+ //
+ // get likelihood for point angle
+ //
+ Double_t sigmaAP = 0.007; //default sigma
+ switch (mode0){
+ case 0:
+ sigmaAP = GetSigmaAP0(); // mode 0 - covariance matrix estimates used
+ break;
+ case 1:
+ sigmaAP = GetEffectiveSigmaAP0(); // mode 1 - effective sigma used
+ break;
+ case 2:
+ sigmaAP = GetMinimaxSigmaAP0(); // mode 2 - minimax sigma
+ break;
+ }
+ Double_t apNorm = TMath::Min(TMath::ACos(fPointAngle)/sigmaAP,50.);
+ //normalized point angle, restricted - because of overflow problems in Exp
+ Double_t likelihood = 0;
+ switch(mode1){
+ case 0:
+ likelihood = TMath::Exp(-0.5*apNorm*apNorm);
+ // one component
+ break;
+ case 1:
+ likelihood = (TMath::Exp(-0.5*apNorm*apNorm)+0.5* TMath::Exp(-0.25*apNorm*apNorm))/1.5;
+ // two components
+ break;
+ case 2:
+ likelihood = (TMath::Exp(-0.5*apNorm*apNorm)+0.5* TMath::Exp(-0.25*apNorm*apNorm)+0.25*TMath::Exp(-0.125*apNorm*apNorm))/1.75;
+ // three components
+ break;
+ }
+ return likelihood;
+}
+
+Double_t AliESDv0::GetLikelihoodD(Int_t mode0, Int_t mode1){
+ //
+ // get likelihood for DCA
+ //
+ Double_t sigmaD = 0.03; //default sigma
+ switch (mode0){
+ case 0:
+ sigmaD = GetSigmaD0(); // mode 0 - covariance matrix estimates used
+ break;
+ case 1:
+ sigmaD = GetEffectiveSigmaD0(); // mode 1 - effective sigma used
+ break;
+ case 2:
+ sigmaD = GetMinimaxSigmaD0(); // mode 2 - minimax sigma
+ break;
+ }
+
+ //Bo: Double_t dNorm = TMath::Min(fDist2/sigmaD,50.);
+ Double_t dNorm = TMath::Min(fDcaV0Daughters/sigmaD,50.);//Bo:
+ //normalized point angle, restricted - because of overflow problems in Exp
+ Double_t likelihood = 0;
+ switch(mode1){
+ case 0:
+ likelihood = TMath::Exp(-2.*dNorm);
+ // one component
+ break;
+ case 1:
+ likelihood = (TMath::Exp(-2.*dNorm)+0.5* TMath::Exp(-dNorm))/1.5;
+ // two components
+ break;
+ case 2:
+ likelihood = (TMath::Exp(-2.*dNorm)+0.5* TMath::Exp(-dNorm)+0.25*TMath::Exp(-0.5*dNorm))/1.75;
+ // three components
+ break;
+ }
+ return likelihood;
+
+}
+
+Double_t AliESDv0::GetLikelihoodC(Int_t mode0, Int_t /*mode1*/) const {
+ //
+ // get likelihood for Causality
+ // !!! Causality variables defined in AliITStrackerMI !!!
+ // when more information was available
+ //
+ Double_t likelihood = 0.5;
+ Double_t minCausal = TMath::Min(fCausality[0],fCausality[1]);
+ Double_t maxCausal = TMath::Max(fCausality[0],fCausality[1]);
+ // minCausal = TMath::Max(minCausal,0.5*maxCausal);
+ //compv0->fTree->SetAlias("LCausal","(1.05-(2*(0.8-exp(-max(RC.fV0rec.fCausality[0],RC.fV0rec.fCausality[1])))+2*(0.8-exp(-min(RC.fV0rec.fCausality[0],RC.fV0rec.fCausality[1]))))/2)**4");
+
+ switch(mode0){
+ case 0:
+ //normalization
+ likelihood = TMath::Power((1.05-2*(0.8-TMath::Exp(-maxCausal))),4.);
+ break;
+ case 1:
+ likelihood = TMath::Power(1.05-(2*(0.8-TMath::Exp(-maxCausal))+(2*(0.8-TMath::Exp(-minCausal))))*0.5,4.);
+ break;
+ }
+ return likelihood;
+
+}
+
+void AliESDv0::SetCausality(Float_t pb0, Float_t pb1, Float_t pa0, Float_t pa1)
+{
+ //
+ // set probabilities
+ //
+ fCausality[0] = pb0; // probability - track 0 exist before vertex
+ fCausality[1] = pb1; // probability - track 1 exist before vertex
+ fCausality[2] = pa0; // probability - track 0 exist close after vertex
+ fCausality[3] = pa1; // probability - track 1 exist close after vertex
+}
+void AliESDv0::SetClusters(const Int_t *clp, const Int_t *clm)
+{
+ //
+ // Set its clusters indexes
+ //
+ for (Int_t i=0;i<6;i++) fClusters[0][i] = clp[i];
+ for (Int_t i=0;i<6;i++) fClusters[1][i] = clm[i];
+}
+
+Double_t AliESDv0::GetEffMass(UInt_t p1, UInt_t p2) const{
+ //
+ // calculate effective mass
+ //
+ const Float_t kpmass[5] = {TDatabasePDG::Instance()->GetParticle(kElectron)->Mass(),
+ TDatabasePDG::Instance()->GetParticle(kMuonMinus)->Mass(),
+ TDatabasePDG::Instance()->GetParticle(kPiPlus)->Mass(),
+ TDatabasePDG::Instance()->GetParticle(kKPlus)->Mass(),
+ TDatabasePDG::Instance()->GetParticle(kProton)->Mass()};
+ if (p1>4) return -1;
+ if (p2>4) return -1;
+ Float_t mass1 = kpmass[p1];
+ Float_t mass2 = kpmass[p2];
+ const Double_t *m1 = fPmom;
+ const Double_t *m2 = fNmom;
+ //
+ //if (fRP[p1]+fRM[p2]<fRP[p2]+fRM[p1]){
+ // m1 = fPM;
+ // m2 = fPP;
+ //}
+ //
+ Float_t e1 = TMath::Sqrt(mass1*mass1+
+ m1[0]*m1[0]+
+ m1[1]*m1[1]+
+ m1[2]*m1[2]);
+ Float_t e2 = TMath::Sqrt(mass2*mass2+
+ m2[0]*m2[0]+
+ m2[1]*m2[1]+
+ m2[2]*m2[2]);
+ Float_t mass =
+ (m2[0]+m1[0])*(m2[0]+m1[0])+
+ (m2[1]+m1[1])*(m2[1]+m1[1])+
+ (m2[2]+m1[2])*(m2[2]+m1[2]);
+
+ mass = TMath::Sqrt((e1+e2)*(e1+e2)-mass);
+ return mass;
+}