/*************************************************************************** * * $Id: helensV0Cut.cxx,v 1.11 2003/09/02 17:58:21 perev Exp $ * * Authors: Helen Caines, Tom Humanic, Ohio State, humanic@mps.ohio-state.edu *************************************************************************** * * Description: part of STAR HBT Framework: StHbtMaker package * a V0 particle cut that selects on phasespace, particle type, etc.. * *************************************************************************** * * $Log: helensV0Cut.cxx,v $ * Revision 1.11 2003/09/02 17:58:21 perev * gcc 3.2 updates + WarnOff * * Revision 1.10 2001/09/28 20:41:19 lisa * fixes to V0 object and cut * * Revision 1.9 2000/10/09 21:56:16 laue * Helens new cuts * * Revision 1.7 2000/03/17 17:22:53 laue * Roberts new three particle correlations implemented. * * Revision 1.6 2000/03/16 01:57:17 laue * Copy constructor added to some cuts * * Revision 1.5 2000/02/11 18:02:26 laue * Debug output removed * * Revision 1.4 2000/02/01 00:31:27 laue * *** empty log message *** * * Revision 1.3 2000/01/25 17:35:02 laue * I. In order to run the stand alone version of the StHbtMaker the following * changes have been done: * a) all ClassDefs and ClassImps have been put into #ifdef __ROOT__ statements * b) unnecessary includes of StMaker.h have been removed * c) the subdirectory StHbtMaker/doc/Make has been created including everything * needed for the stand alone version * * II. To reduce the amount of compiler warning * a) some variables have been type casted * b) some destructors have been declared as virtual * * Revision 1.2 1999/10/05 11:37:38 lisa * Helens realistic V0Cut and Franks memory-sealed McReader * * Revision 1.1 1999/09/23 23:28:03 lisa * add helensV0Cut AND rename mikes and franks ParticleCuts to TrackCuts AND update documentation * * **************************************************************************/ #include "StHbtMaker/Cut/helensV0Cut.h" #include #ifdef __ROOT__ ClassImp(helensV0Cut) #endif helensV0Cut::helensV0Cut(){ mNV0sPassed = mNV0sFailed = 0; mV0MassRange[0] =0; mV0MassRange[1]=10000; mdcaV0daughters[0]=0; mdcaV0daughters[1]=1000; mdcaV0ToPrimVertex[0]=0; mdcaV0ToPrimVertex[1]=1000; mdecayLengthV0[0]=0; mdecayLengthV0[1]=10000; mtpcHitsPos[0]=0; mtpcHitsPos[1]=1000; mtpcHitsNeg[0]=0; mtpcHitsNeg[1]=1000; mdcaPosToPrimVertex[0]=0; mdcaPosToPrimVertex[1]=1000; mdcaNegToPrimVertex[0]=0; mdcaNegToPrimVertex[1]=10000; mptArmV0[0]=0; mptArmV0[1]=100; malphaV0[0]=-10; malphaV0[1]=10; mChargedEdx=0; mdEdx[0]=0; mdEdx[1]=-10; mdEdx[2]=0; mdEdx[3]=-10; mPt[0]=0; mPt[1]=100000; mRapidity[0]=-100000; mRapidity[1]=100000; V0Type = "K0Short"; mMass = 0.498; } //------------------------------ //helensV0Cut::~helensV0Cut(){ // /* noop */ //} //------------------------------ bool helensV0Cut::Pass(const StHbtV0* V0){ int inMassRange; #ifdef STHBTDEBUG cout << endl; cout << " * dcaV0Daughters " << V0->dcaV0Daughters(); cout << " * dcaV0ToPrimVertex " << V0->dcaV0ToPrimVertex(); cout << " * decayLengthV0 " << V0->decayLengthV0(); cout << " * tpcHitsPos " << V0->tpcHitsPos(); cout << " * tpcHitsNeg " << V0->tpcHitsNeg(); cout << " * dcaPosToPrimVertex " << V0->dcaPosToPrimVertex(); cout << " * dcaNegToPrimVertex " << V0->dcaNegToPrimVertex(); cout << " * ptArmV0 " << V0->ptArmV0(); cout << " * alphaV0 " << V0->alphaV0(); cout << " * dEdxPos " << V0->dedxPos(); cout << " * dEdxNeg " << V0->dedxNeg(); cout << endl; #endif inMassRange=0; // Find out what particle is desired if( strstr(V0Type,"k") || strstr(V0Type,"K")){ if( V0->massK0Short() < (mV0MassRange[1]) && V0->massK0Short() > (mV0MassRange[0]) ) inMassRange=1; } else if( (strstr(V0Type,"anti") || strstr(V0Type,"ANTI"))){ if( V0->massAntiLambda() < (mV0MassRange[1]) && V0->massAntiLambda() > (mV0MassRange[0]) ) inMassRange=1; } else if( (strstr(V0Type,"ambda") || strstr(V0Type,"AMBDA"))){ if( V0->massLambda() < (mV0MassRange[1]) && V0->massLambda() > (mV0MassRange[0]) ) inMassRange=1; } bool goodPID = ( inMassRange && (V0->dcaV0Daughters() > mdcaV0daughters[0]) && (V0->dcaV0Daughters() < mdcaV0daughters[1]) && (V0->dcaV0ToPrimVertex() > mdcaV0ToPrimVertex[0]) && (V0->dcaV0ToPrimVertex() < mdcaV0ToPrimVertex[1]) && (V0->decayLengthV0() > mdecayLengthV0[0]) && (V0->decayLengthV0() < mdecayLengthV0[1]) && (V0->tpcHitsPos() > mtpcHitsPos[0]) && (V0->tpcHitsPos() < mtpcHitsPos[1]) && (V0->tpcHitsNeg() > mtpcHitsNeg[0]) && (V0->tpcHitsNeg() < mtpcHitsNeg[1]) && (V0->dcaPosToPrimVertex() > mdcaPosToPrimVertex[0]) && (V0->dcaPosToPrimVertex() < mdcaPosToPrimVertex[1]) && (V0->dcaNegToPrimVertex() > mdcaNegToPrimVertex[0]) && (V0->dcaNegToPrimVertex() < mdcaNegToPrimVertex[1]) && (V0->ptArmV0() > mptArmV0[0]) && (V0->ptArmV0() < mptArmV0[1]) && (V0->alphaV0() > malphaV0[0]) && (V0->alphaV0() < malphaV0[1])); if(goodPID && mChargedEdx){ if( mChargedEdx <0){ goodPID = ( (V0->dedxNeg() > (mdEdx[0]*V0->ptNeg()+mdEdx[1])) && (V0->dedxNeg() > (mdEdx[2]*V0->ptNeg()+mdEdx[3]))); } if( mChargedEdx > 0){ goodPID = ( (V0->dedxPos() > (mdEdx[0]*V0->ptPos()+mdEdx[1])) && (V0->dedxPos() > (mdEdx[2]*V0->ptPos()+mdEdx[3]))); } } if (goodPID){ float TEnergy = ::sqrt((V0->ptotV0())*(V0->ptotV0())+mMass*mMass); float TRapidity = 0.5*::log((TEnergy+V0->momV0().z())/ (TEnergy-V0->momV0().z())); float Pt = V0->ptV0(); #ifdef STHBTDEBUG cout << " * Pt " << Pt; cout << " * mPt[0] " << mPt[0]; cout << " * mPt[1] " << mPt[1]; cout << " * TRapidity " << TRapidity; cout << " * mRapidity[0] " << mRapidity[0]; cout << " * mRapidity[1] " << mRapidity[1]; cout << " * Pt " << (Pt > mPt[0]) && (Pt < mPt[1]); cout << " * y " << (TRapidity > mRapidity[0]) && (TRapidity < mRapidity[1]); cout << endl; #endif bool goodV0= ((Pt > mPt[0]) && (Pt < mPt[1]) && (TRapidity > mRapidity[0]) && (TRapidity < mRapidity[1])); goodV0 ? mNV0sPassed++ : mNV0sFailed++; return (goodV0); } else{ mNV0sFailed++; return (goodPID); } } //------------------------------ StHbtString helensV0Cut::Report(){ string Stemp; char Ctemp[100]; sprintf(Ctemp,"--helensV0Cut--\n Particle mass:\t%E\n",this->Mass()); Stemp=Ctemp; sprintf(Ctemp,"V0 mass range:\t%E - %E\n",mV0MassRange[0], mV0MassRange[1]); Stemp+=Ctemp; sprintf(Ctemp,"dcaV0daughters:\t%E - %E\n",mdcaV0daughters[0], mdcaV0daughters[1]); Stemp+=Ctemp; sprintf(Ctemp,"dcaV0ToPrimVertex:\t%E - %E\n",mdcaV0ToPrimVertex[0], mdcaV0ToPrimVertex[1]); Stemp+=Ctemp; sprintf(Ctemp,"decayLengthV0:\t%E - %E\n",mdecayLengthV0[0], mdecayLengthV0[1]); Stemp+=Ctemp; sprintf(Ctemp,"tpcHitsPos:\t%d - %d\n",mtpcHitsPos[0],mtpcHitsPos[1]); Stemp+=Ctemp; sprintf(Ctemp,"tpcHitsNeg:\t%d - %d\n",mtpcHitsNeg[0],mtpcHitsNeg[1]); Stemp+=Ctemp; sprintf(Ctemp,"dcaPosToPrimVertex:\t%E - %E\n",mdcaPosToPrimVertex[0], mdcaPosToPrimVertex[1]); Stemp+=Ctemp; sprintf(Ctemp,"dcaNegToPrimVertex:\t%E - %E\n",mdcaNegToPrimVertex[0], mdcaNegToPrimVertex[1]); Stemp+=Ctemp; sprintf(Ctemp,"dedx>:\t%E pt+%E and \t%E pt+ %E for Charge %E\n ",mdEdx[0],mdEdx[1],mdEdx[2],mdEdx[3],mChargedEdx); Stemp+=Ctemp; sprintf(Ctemp,"ptArmV0:\t%E - %E\n",mptArmV0[0],mptArmV0[1]); Stemp+=Ctemp; sprintf(Ctemp,"alphaV0:\t%E - %E\n",malphaV0[0],malphaV0[1]); Stemp+=Ctemp; sprintf(Ctemp,"Particle pT:\t%E - %E\n",mPt[0],mPt[1]); Stemp+=Ctemp; sprintf(Ctemp,"Particle rapidity:\t%E - %E\n",mRapidity[0],mRapidity[1]); Stemp+=Ctemp; sprintf(Ctemp,"Number of V0s which passed:\t%ld Number which failed:\t%ld\n",mNV0sPassed,mNV0sFailed); Stemp += Ctemp; StHbtString returnThis = Stemp; return returnThis; }