// ************************************************************************** // * 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. * // ************************************************************************** #include "AliRICH.h" #include "AliRICHParam.h" #include "AliRICHChamber.h" #include "AliRICHClusterFinder.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include ClassImp(AliRICHhit) //__________________________________________________________________________________________________ void AliRICHhit::Print(Option_t*)const { ::Info("hit","Ch=%1i, TID=%6i, eloss=%9.3f eV, in-out dist=%9.4f, OUT(%7.2f,%7.2f,%7.2f)" ,fChamber,fTrack,fEloss*1e9,Length(),fOutX3.X(),fOutX3.Y(),fOutX3.Z()); } //__________________________________________________________________________________________________ ClassImp(AliRICHdigit) //__________________________________________________________________________________________________ void AliRICHdigit::Print(Option_t*)const { ::Info("digit","cfm=%9i, cs=%2i, x=%3i, y=%3i, q=%8.3f, TID1=%5i, TID2=%5i, TID3=%5i", fCFM,fChamber,fPadX,fPadY,fQdc,fTracks[0],fTracks[1],fTracks[2]); } //__________________________________________________________________________________________________ ClassImp(AliRICHcluster) //__________________________________________________________________________________________________ void AliRICHcluster::Print(Option_t*)const { char *status=0; switch(fStatus){ case kRaw: status="raw" ;break; case kResolved: status="resolved";break; case kEmpty: status="empty" ;break; } if(fDigits) ::Info("cluster","cfm=%10i, cs=%2i, SiMa=%6i, Shape=%5i, x=%7.3f, y=%7.3f, Q=%6i, %s with %i digits", fCFM,fChamber,fSize,fShape,fX,fY,fQdc,status,fDigits->GetEntriesFast()); else ::Info("cluster","cfm=%10i, cs=%2i, SiMa=%6i, Shape=%5i, x=%7.3f, y=%7.3f, Q=%6i, %s with %i digits", fCFM,fChamber,fSize,fShape,fX,fY,fQdc,status,0); } //__________________________________________________________________________________________________ ClassImp(AliRICH) //__________________________________________________________________________________________________ // RICH manager class //BEGIN_HTML /* */ //END_HTML //__________________________________________________________________________________________________ AliRICH::AliRICH():AliDetector(),fpParam(0), fSdigits(0),fNsdigits(0),fDigitsNew(0),fClusters(0) { //Default ctor should not contain any new operators //AliDetector ctor deals with Hits and Digits for(int i=0;iGetMCApp()->AddHitList(fHits); fCounters.ResizeTo(20); fCounters.Zero(); if(GetDebug())Info("named ctor","Stop."); }//AliRICH::AliRICH(const char *name, const char *title) //__________________________________________________________________________________________________ AliRICH::~AliRICH() { //dtor if(GetDebug()) Info("dtor","Start."); if(fpParam) delete fpParam; if(fHits) delete fHits; if(fSdigits) delete fSdigits; if(fDigits) delete fDigits; if(fDigitsNew) {fDigitsNew->Delete(); delete fDigitsNew;} if(fClusters) {fClusters->Delete(); delete fClusters;} if(GetDebug()) Info("dtor","Stop."); }//AliRICH::~AliRICH() //__________________________________________________________________________________________________ void AliRICH::Hits2SDigits() { // Create a list of sdigits corresponding to list of hits. Every hit generates one or more sdigits. if(GetDebug()) Info("Hit2SDigits","Start."); for(Int_t iEventN=0;iEventNGetRunLoader()->GetAliRun()->GetEventsPerRun();iEventN++){//events loop GetLoader()->GetRunLoader()->GetEvent(iEventN);//get next event if(!GetLoader()->TreeH()) GetLoader()->LoadHits(); GetLoader()->GetRunLoader()->LoadHeader(); GetLoader()->GetRunLoader()->LoadKinematics();//from if(!GetLoader()->TreeS()) GetLoader()->MakeTree("S"); MakeBranch("S");//to for(Int_t iPrimN=0;iPrimNTreeH()->GetEntries();iPrimN++){//prims loop GetLoader()->TreeH()->GetEntry(iPrimN); for(Int_t iHitN=0;iHitNGetEntries();iHitN++){//hits loop AliRICHhit *pHit=(AliRICHhit*)Hits()->At(iHitN);//get current hit TVector2 x2 = C(pHit->C())->Glob2Loc(pHit->OutX3());//hit position in the chamber local system Int_t iTotQdc=P()->TotQdc(x2,pHit->Eloss());//total charge produced by hit, 0 if hit in dead zone if(iTotQdc==0) continue; TVector area=P()->Loc2Area(x2);//determine affected pads, dead zones analysed inside if(GetDebug()) Info("Hits2SDigits","hit(%6.2f,%6.2f)->area(%3.0f,%3.0f)-(%3.0f,%3.0f) QDC=%4i",x2.X(),x2.Y(),area[0],area[1],area[2],area[3],iTotQdc); TVector pad(2); for(pad[1]=area[1];pad[1]<=area[3];pad[1]++)//affected pads loop for(pad[0]=area[0];pad[0]<=area[2];pad[0]++){ Double_t padQdc=iTotQdc*P()->FracQdc(x2,pad); if(GetDebug()) Info("Hits2SDigits","current pad(%3.0f,%3.0f) with QDC =%6.2f",pad[0],pad[1],padQdc); if(padQdc>0.1) AddSDigit(pHit->C(),pad,padQdc,GetLoader()->GetRunLoader()->Stack()->Particle(pHit->GetTrack())->GetPdgCode(),pHit->GetTrack()); }//affected pads loop }//hits loop }//prims loop GetLoader()->TreeS()->Fill(); GetLoader()->WriteSDigits("OVERWRITE"); ResetSDigits(); }//events loop GetLoader()->UnloadHits(); GetLoader()->GetRunLoader()->UnloadHeader(); GetLoader()->GetRunLoader()->UnloadKinematics(); GetLoader()->UnloadSDigits(); if(GetDebug()) Info("Hit2SDigits","Stop."); }//Hits2SDigits() //__________________________________________________________________________________________________ void AliRICH::BuildGeometry() { //Builds a TNode geometry for event display if(GetDebug())Info("BuildGeometry","Start."); TNode *node, *subnode, *top; top=gAlice->GetGeometry()->GetNode("alice"); new TBRIK("S_RICH","S_RICH","void",71.09999,11.5,73.15); Float_t wid=P()->SectorSizeX(); Float_t len=P()->SectorSizeY(); new TBRIK("PHOTO","PHOTO","void",wid/2,0.1,len/2); for(int i=1;i<=kNchambers;i++){ top->cd(); node = new TNode(Form("RICH%i",i),Form("RICH%i",i),"S_RICH",C(i)->X(),C(i)->Y(),C(i)->Z(),C(i)->RotMatrixName()); node->SetLineColor(kRed); node->cd(); subnode = new TNode("PHOTO1","PHOTO1","PHOTO",wid+P()->DeadZone(),5,len/2+P()->DeadZone()/2,""); subnode->SetLineColor(kGreen); fNodes->Add(subnode); subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,len/2+P()->DeadZone()/2,""); subnode->SetLineColor(kGreen); fNodes->Add(subnode); subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-wid-P()->DeadZone(),5,len/2+P()->DeadZone()/2,""); subnode->SetLineColor(kGreen); fNodes->Add(subnode); subnode = new TNode("PHOTO1","PHOTO1","PHOTO",wid+P()->DeadZone(),5,-len/2-P()->DeadZone()/2,""); subnode->SetLineColor(kGreen); fNodes->Add(subnode); subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,-len/2 -P()->DeadZone()/2,""); subnode->SetLineColor(kGreen); fNodes->Add(subnode); subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-wid-P()->DeadZone(),5,-len/2 - P()->DeadZone()/2,""); subnode->SetLineColor(kGreen); fNodes->Add(subnode); fNodes->Add(node); } if(GetDebug())Info("BuildGeometry","Stop."); }//void AliRICH::BuildGeometry() //______________________________________________________________________________ void AliRICH::CreateMaterials() { // Definition of available RICH materials #include "Opticals.h" Float_t a=0,z=0,den=0,radl=0,absl=0; Float_t tmaxfd=-10.0, deemax=-0.2, stemax=-0.1,epsil=0.001, stmin=-0.001; Int_t isxfld = gAlice->Field()->Integ(); Float_t sxmgmx = gAlice->Field()->Max(); Int_t material; AliMaterial(material=1, "Air $",a=14.61,z=7.3, den=0.001205,radl=30420.0,absl=67500);//(Air) AliMedium(1, "DEFAULT MEDIUM AIR$",material, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); AliMaterial( 6, "HON", a=12.01,z=6.0, den=0.1, radl=18.8, absl=0); //(C)-equivalent radl AliMedium(2, "HONEYCOMB$", 6, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); AliMaterial(16, "CSI", a=12.01,z=6.0, den=0.1, radl=18.8, absl=0); //CsI-radl equivalent AliMedium(kCSI, "CSI$", 16, 1, isxfld, sxmgmx,tmaxfd, stemax, deemax, epsil, stmin); AliMaterial(11, "GRI", a=63.54,z=29.0,den=8.96, radl=1.43, absl=0); //anode grid (Cu) AliMedium(7, "GRID$", 11, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); AliMaterial(50, "ALUM", a=26.98,z=13.0,den=2.699, radl=8.9, absl=0); //aluminium sheet (Al) AliMedium(10, "ALUMINUM$", 50, 1, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); AliMaterial(material=31, "COPPER$", a=63.54,z=29.0,den=8.96, radl=1.4, absl=0); //(Cu) AliMedium(12, "PCB_COPPER", material, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); Float_t aQuartz[2]={28.09,16.0}; Float_t zQuartz[2]={14.00, 8.0}; Float_t wmatQuartz[2]={1,2}; AliMixture (20, "QUA",aQuartz,zQuartz,den=2.64,-2, wmatQuartz);//Quarz (SiO2) - trasnparent AliMedium(3, "QUARTZ$", 20, 1, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); AliMixture (21, "QUAO",aQuartz, zQuartz, den=2.64, -2, wmatQuartz);//Quarz (SiO2) - opaque AliMedium(8, "QUARTZO$", 21, 1, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); Float_t aFreon[2]={12,19}; Float_t zFreon[2]={6,9}; Float_t wmatFreon[2]={6,14}; AliMixture (material=30, "C6F14",aFreon,zFreon,den=1.68,-2,wmatFreon);//Freon (C6F14) AliMedium(4, "C6F14$",material, 1, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); Float_t aMethane[2]={12.01,1}; Float_t zMethane[2]={6,1}; Float_t wmatMethane[2]={1,4}; AliMixture (material=40, "CH4", aMethane, zMethane, den=7.17e-4,-2, wmatMethane);//methane (CH4) AliMedium(kCH4, "CH4$" , material, 1, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); AliMedium(kGAP, "CH4GAP$", material, 1, isxfld, sxmgmx,tmaxfd, 0.1, -deemax, epsil, -stmin); if(P()->IsRadioSrc()){ AliMaterial(material=45, "STEEL$", a=63.54,z=29.0,den=8.96, radl=1.4, absl=0); //Steel AliMedium(kSteel, "STEEL", material, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); AliMaterial(material=46, "PERPEX$", a=63.54,z=29.0,den=8.96, radl=1.4, absl=0); //Perpex AliMedium(kPerpex, "PERPEX", material, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); AliMaterial(material=47, "STRONZIUM$", a=87.62,z=38.0,den=2.54, radl=4.24, absl=0); //Sr90 AliMedium(kSr90, "STRONZIUM", material, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); } Float_t aGlass[5]={12.01, 28.09, 16., 10.8, 23.}; Float_t zGlass[5]={ 6., 14., 8., 5., 11.}; Float_t wGlass[5]={ 0.5, 0.105, 0.355, 0.03, 0.01}; AliMixture(material=32, "GLASS",aGlass, zGlass, den=1.74, 5, wGlass);//Glass 50%C+10.5%Si+35.5%O+3% + 1% AliMedium(11, "GLASS", material, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin); Int_t *idtmed = fIdtmed->GetArray()-999; gMC->SetCerenkov(idtmed[1000], kNbins, aPckov, aAbsCH4, aQeAll, aIdxCH4); gMC->SetCerenkov(idtmed[1001], kNbins, aPckov, aAbsCH4, aQeAll, aIdxCH4); gMC->SetCerenkov(idtmed[1002], kNbins, aPckov, aAbsSiO2, aQeAll, aIdxSiO2); gMC->SetCerenkov(idtmed[1003], kNbins, aPckov, aAbsC6F14, aQeAll, aIdxC6F14); gMC->SetCerenkov(idtmed[1004], kNbins, aPckov, aAbsCH4, aQeAll, aIdxCH4); gMC->SetCerenkov(idtmed[1005], kNbins, aPckov, aAbsCsI, aQeCsI, aIdxCH4); gMC->SetCerenkov(idtmed[1006], kNbins, aPckov, aAbsGrid, aQeAll, aIdxGrid); gMC->SetCerenkov(idtmed[1007], kNbins, aPckov, aAbsOpSiO2, aQeAll, aIdxOpSiO2); gMC->SetCerenkov(idtmed[1008], kNbins, aPckov, aAbsCH4, aQeAll, aIdxCH4); gMC->SetCerenkov(idtmed[1009], kNbins, aPckov, aAbsGrid, aQeAll, aIdxGrid); gMC->SetCerenkov(idtmed[1010], kNbins, aPckov, aAbsOpSiO2, aQeAll, aIdxOpSiO2); }//void AliRICH::CreateMaterials() //__________________________________________________________________________________________________ Float_t AliRICH::Fresnel(Float_t ene,Float_t pdoti, Bool_t pola)const { //ENE(EV), PDOTI=COS(INC.ANG.), PDOTR=COS(POL.PLANE ROT.ANG.) Float_t en[36] = {5.0,5.1,5.2,5.3,5.4,5.5,5.6,5.7,5.8,5.9,6.0,6.1,6.2, 6.3,6.4,6.5,6.6,6.7,6.8,6.9,7.0,7.1,7.2,7.3,7.4,7.5,7.6,7.7, 7.8,7.9,8.0,8.1,8.2,8.3,8.4,8.5}; Float_t csin[36] = {2.14,2.21,2.33,2.48,2.76,2.97,2.99,2.59,2.81,3.05, 2.86,2.53,2.55,2.66,2.79,2.96,3.18,3.05,2.84,2.81,2.38,2.11, 2.01,2.13,2.39,2.73,3.08,3.15,2.95,2.73,2.56,2.41,2.12,1.95, 1.72,1.53}; Float_t csik[36] = {0.,0.,0.,0.,0.,0.196,0.408,0.208,0.118,0.49,0.784,0.543, 0.424,0.404,0.371,0.514,0.922,1.102,1.139,1.376,1.461,1.253,0.878, 0.69,0.612,0.649,0.824,1.347,1.571,1.678,1.763,1.857,1.824,1.824, 1.714,1.498}; Float_t xe=ene; Int_t j=Int_t(xe*10)-49; Float_t cn=csin[j]+((csin[j+1]-csin[j])/0.1)*(xe-en[j]); Float_t ck=csik[j]+((csik[j+1]-csik[j])/0.1)*(xe-en[j]); //FORMULAE FROM HANDBOOK OF OPTICS, 33.23 OR //W.R. HUNTER, J.O.S.A. 54 (1964),15 , J.O.S.A. 55(1965),1197 Float_t sinin=TMath::Sqrt(1-pdoti*pdoti); Float_t tanin=sinin/pdoti; Float_t c1=cn*cn-ck*ck-sinin*sinin; Float_t c2=4*cn*cn*ck*ck; Float_t aO=TMath::Sqrt(0.5*(TMath::Sqrt(c1*c1+c2)+c1)); Float_t b2=0.5*(TMath::Sqrt(c1*c1+c2)-c1); Float_t rs=((aO-pdoti)*(aO-pdoti)+b2)/((aO+pdoti)*(aO+pdoti)+b2); Float_t rp=rs*((aO-sinin*tanin)*(aO-sinin*tanin)+b2)/((aO+sinin*tanin)*(aO+sinin*tanin)+b2); //CORRECTION FACTOR FOR SURFACE ROUGHNESS //B.J. STAGG APPLIED OPTICS, 30(1991),4113 Float_t sigraf=18.; Float_t lamb=1240/ene; Float_t fresn; Float_t rO=TMath::Exp(-(4*TMath::Pi()*pdoti*sigraf/lamb)*(4*TMath::Pi()*pdoti*sigraf/lamb)); if(pola) { Float_t pdotr=0.8; //DEGREE OF POLARIZATION : 1->P , -1->S fresn=0.5*(rp*(1+pdotr)+rs*(1-pdotr)); } else fresn=0.5*(rp+rs); fresn = fresn*rO; return(fresn); }//Fresnel() //__________________________________________________________________________________________________ Float_t AliRICH::AbsoCH4(Float_t x)const { //Evaluate the absorbtion lenght of CH4 Float_t sch4[9] = {.12,.16,.23,.38,.86,2.8,7.9,28.,80.}; //MB X 10^22 Float_t em[9] = {8.1,8.158,8.212,8.267,8.322,8.378,8.435,8.493,8.55}; const Float_t kLoschmidt=2.686763e19; // LOSCHMIDT NUMBER IN CM-3 const Float_t kPressure=750.,kTemperature=283.; const Float_t kPn=kPressure/760.; const Float_t kTn=kTemperature/273.16; const Float_t kC0=-1.655279e-1; const Float_t kC1=6.307392e-2; const Float_t kC2=-8.011441e-3; const Float_t kC3=3.392126e-4; Float_t crossSection=0; if (x<7.75) crossSection=.06e-22; else if(x>=7.75 && x<=8.1){ //------ METHANE CROSS SECTION cm-2 ASTROPH. J. 214, L47 (1978) crossSection=(kC0+kC1*x+kC2*x*x+kC3*x*x*x)*1.e-18; }else if (x> 8.1){ Int_t j=0; while (x<=em[j] || x>=em[j+1]){ j++; Float_t a=(sch4[j+1]-sch4[j])/(em[j+1]-em[j]); crossSection=(sch4[j]+a*(x-em[j]))*1e-22; } }//if Float_t density=kLoschmidt*kPn/kTn; //CH4 molecular density 1/cm-3 return 1./(density*crossSection); }//AbsoCH4() //__________________________________________________________________________________________________ void AliRICH::MakeBranch(Option_t* option) { //Create Tree branches for the RICH. if(GetDebug())Info("MakeBranch","Start with option= %s.",option); const Int_t kBufferSize = 4000; const char *cH = strstr(option,"H"); const char *cD = strstr(option,"D"); const char *cR = strstr(option,"R"); const char *cS = strstr(option,"S"); if(cH&&TreeH()){//H CreateHits(); //branch will be created in AliDetector::MakeBranch }//H AliDetector::MakeBranch(option);//this is after cH because we need to guarantee that fHits array is created if(cS&&fLoader->TreeS()){//S CreateSDigits(); MakeBranchInTree(fLoader->TreeS(),"RICH",&fSdigits,kBufferSize,0) ; }//S if(cD&&fLoader->TreeD()){//D CreateDigits(); for(Int_t i=0;iTreeD(),Form("%s%d",GetName(),i+1),&((*fDigitsNew)[i]),kBufferSize,0); } }//D if(cR&&fLoader->TreeR()){//R CreateClusters(); for(Int_t i=0;iTreeR(),Form("%sClusters%d",GetName(),i+1), &((*fClusters)[i]), kBufferSize, 0); }//R if(GetDebug())Info("MakeBranch","Stop."); }//void AliRICH::MakeBranch(Option_t* option) //__________________________________________________________________________________________________ void AliRICH::SetTreeAddress() { //Set branch address for the Hits and Digits Tree. if(GetDebug())Info("SetTreeAddress","Start."); TBranch *branch; if(fLoader->TreeH()){//H if(GetDebug())Info("SetTreeAddress","tree H is requested."); CreateHits();//branch map will be in AliDetector::SetTreeAddress }//H AliDetector::SetTreeAddress();//this is after TreeH because we need to guarantee that fHits array is created if(fLoader->TreeS()){//S if(GetDebug())Info("SetTreeAddress","tree S is requested."); branch=fLoader->TreeS()->GetBranch(GetName()); if(branch){CreateSDigits(); branch->SetAddress(&fSdigits);} }//S if(fLoader->TreeD()){//D if(GetDebug())Info("SetTreeAddress","tree D is requested."); for(int i=0;iTreeD()->GetBranch(Form("%s%d",GetName(),i+1)); if(branch){CreateDigits(); branch->SetAddress(&((*fDigitsNew)[i]));} } }//D if(fLoader->TreeR()){//R if(GetDebug())Info("SetTreeAddress","tree R is requested."); for(int i=0;iTreeR()->GetBranch(Form("%sClusters%d" ,GetName(),i+1)); if(branch){CreateClusters(); branch->SetAddress(&((*fClusters)[i]));} } }//R if(GetDebug())Info("SetTreeAddress","Stop."); }//void AliRICH::SetTreeAddress() //__________________________________________________________________________________________________ void AliRICH::Print(Option_t *option)const { //Debug printout TObject::Print(option); P()->Print(); fCounters.Print(); }//void AliRICH::Print(Option_t *option)const //__________________________________________________________________________________________________ void AliRICH::CreateGeometry() { //Creates detailed geometry simulation (currently GEANT volumes tree) if(GetDebug())Info("CreateGeometry","Start main."); //Opaque quartz thickness Float_t oquaThickness = .5; //CsI dimensions Float_t pcX=P()->PcSizeX(); Float_t pcY=P()->PcSizeY(); Int_t *idtmed = fIdtmed->GetArray()-999; Int_t i; Float_t zs; Int_t idrotm[1099]; Float_t par[3]; par[0]=68.8;par[1]=13 ;par[2]=70.86; gMC->Gsvolu("RICH","BOX ",(*fIdtmed)[kAl], par,3);//External aluminium box par[0]=66.3;par[1]=13 ;par[2]=68.35; gMC->Gsvolu("SRIC","BOX ",(*fIdtmed)[kAir],par,3);//Air par[0]=66.3;par[1]=0.025;par[2]=68.35; gMC->Gsvolu("ALUM","BOX ",(*fIdtmed)[kAl], par,3);//Aluminium sheet //Air 2 (cutting the lower part of the box) // par[0]=1.25; par[1] = 3; par[2] = 70.86; gMC->Gsvolu("AIR2", "BOX ", idtmed[1000], par, 3); //Air 3 (cutting the lower part of the box) // par[0]=66.3; par[1] = 3; par[2] = 1.2505; gMC->Gsvolu("AIR3", "BOX ", idtmed[1000], par, 3); //Honeycomb par[0]=66.3;par[1]=0.188; par[2] = 68.35; gMC->Gsvolu("HONE", "BOX ", idtmed[1001], par, 3); //par[0] = 66.5; par[1] = .025; par[2] = 63.1; //Quartz par[0]=P()->QuartzWidth()/2;par[1]=P()->QuartzThickness()/2;par[2]=P()->QuartzLength()/2; gMC->Gsvolu("QUAR", "BOX ", idtmed[1002], par, 3); //Spacers (cylinders) par[0]=0.;par[1]=.5;par[2]=P()->FreonThickness()/2; gMC->Gsvolu("SPAC", "TUBE", idtmed[1002], par, 3); //Feet (freon slabs supports) par[0] = .7; par[1] = .3; par[2] = 1.9; gMC->Gsvolu("FOOT", "BOX", idtmed[1009], par, 3); //Opaque quartz par[0]=P()->QuartzWidth()/2;par[1]= .2;par[2]=P()->QuartzLength()/2; gMC->Gsvolu("OQUA", "BOX ", idtmed[1007], par, 3); //Frame of opaque quartz par[0]=P()->OuterFreonWidth()/2;par[1]=P()->FreonThickness()/2;par[2]=P()->OuterFreonLength()/2; gMC->Gsvolu("OQF1", "BOX ", idtmed[1007], par, 3); par[0]=P()->InnerFreonWidth()/2;par[1]=P()->FreonThickness()/2;par[2]=P()->InnerFreonLength()/2; gMC->Gsvolu("OQF2", "BOX ", idtmed[1007], par, 3); //Freon par[0]=P()->OuterFreonWidth()/2 - oquaThickness; par[1]=P()->FreonThickness()/2; par[2]=P()->OuterFreonLength()/2 - 2*oquaThickness; gMC->Gsvolu("FRE1", "BOX ", idtmed[1003], par, 3); par[0]=P()->InnerFreonWidth()/2 - oquaThickness; par[1]=P()->FreonThickness()/2; par[2]=P()->InnerFreonLength()/2 - 2*oquaThickness; gMC->Gsvolu("FRE2", "BOX ", idtmed[1003], par, 3); //Methane par[0]=pcX/2;par[1]=P()->GapThickness()/2;par[2]=pcY/2; gMC->Gsvolu("META","BOX ",idtmed[1004], par, 3); //Methane gap par[0]=pcX/2;par[1]=P()->GapAmp()/2;par[2]=pcY/2;gMC->Gsvolu("GAP ","BOX ",(*fIdtmed)[kGAP],par,3); //CsI PC par[0]=pcX/2;par[1]=.25;par[2]=pcY/2; gMC->Gsvolu("CSI ", "BOX ", (*fIdtmed)[kCSI], par, 3); //Anode grid par[0] = 0.;par[1] = .001;par[2] = 20.; gMC->Gsvolu("GRID", "TUBE", idtmed[1006], par, 3); //Wire supports //Bar of metal par[0]=pcX/2;par[1]=1.05;par[2]=1.05; gMC->Gsvolu("WSMe", "BOX ", idtmed[1009], par, 3); //Ceramic pick up (base) par[0]=pcX/2;par[1]= .25;par[2]=1.05; gMC->Gsvolu("WSG1", "BOX ", idtmed[1010], par, 3); //Ceramic pick up (head) par[0] = pcX/2;par[1] = .1;par[2] = .1; gMC->Gsvolu("WSG2", "BOX ", idtmed[1010], par, 3); //Aluminium supports for methane and CsI //Short bar par[0]=pcX/2;par[1]=P()->GapThickness()/2 + .25; par[2] = (68.35 - pcY/2)/2; gMC->Gsvolu("SMSH", "BOX", idtmed[1009], par, 3); //Long bar par[0]=(66.3 - pcX/2)/2;par[1]=P()->GapThickness()/2+.25;par[2]=pcY/2+68.35-pcY/2; gMC->Gsvolu("SMLG", "BOX", idtmed[1009], par, 3); //Aluminium supports for freon //Short bar par[0] = P()->QuartzWidth()/2; par[1] = .3; par[2] = (68.35 - P()->QuartzLength()/2)/2; gMC->Gsvolu("SFSH", "BOX", idtmed[1009], par, 3); //Long bar par[0] = (66.3 - P()->QuartzWidth()/2)/2; par[1] = .3; par[2] = P()->QuartzLength()/2 + 68.35 - P()->QuartzLength()/2; gMC->Gsvolu("SFLG", "BOX", idtmed[1009], par, 3); //PCB backplane par[0] = pcX/2;par[1] = .25; par[2] = pcY/4 -.5025; gMC->Gsvolu("PCB ", "BOX", idtmed[1011], par, 3); //Backplane supports //Aluminium slab par[0] = 33.15;par[1] = 2;par[2] = 21.65; gMC->Gsvolu("BACK", "BOX", idtmed[1009], par, 3); //Big hole par[0] = 9.05; par[1] = 2; par[2] = 4.4625; gMC->Gsvolu("BKHL", "BOX", idtmed[1000], par, 3); //Small hole par[0] = 5.7;par[1] = 2;par[2] = 4.4625; gMC->Gsvolu("BKHS", "BOX", idtmed[1000], par, 3); //Place holes inside backplane support gMC->Gspos("BKHS", 1, "BACK", .8 + 5.7,0., .6 + 4.4625, 0, "ONLY"); gMC->Gspos("BKHS", 2, "BACK", -.8 - 5.7,0., .6 + 4.4625, 0, "ONLY"); gMC->Gspos("BKHS", 3, "BACK", .8 + 5.7,0., -.6 - 4.4625, 0, "ONLY"); gMC->Gspos("BKHS", 4, "BACK", -.8 - 5.7,0., -.6 - 4.4625, 0, "ONLY"); gMC->Gspos("BKHS", 5, "BACK", .8 + 5.7,0., .6 + 8.925 + 1.2 + 4.4625, 0, "ONLY"); gMC->Gspos("BKHS", 6, "BACK", -.8 - 5.7,0., .6 + 8.925 + 1.2 + 4.4625, 0, "ONLY"); gMC->Gspos("BKHS", 7, "BACK", .8 + 5.7,0., -.6 - 8.925 - 1.2 - 4.4625, 0, "ONLY"); gMC->Gspos("BKHS", 8, "BACK", -.8 - 5.7,0., -.6 - 8.925 - 1.2 - 4.4625, 0, "ONLY"); gMC->Gspos("BKHL", 1, "BACK", .8 + 11.4 + 1.6 + 9.05, 0., .6 + 4.4625, 0, "ONLY"); gMC->Gspos("BKHL", 2, "BACK", -.8 - 11.4 - 1.6 - 9.05, 0., .6 + 4.4625, 0, "ONLY"); gMC->Gspos("BKHL", 3, "BACK", .8 + 11.4 + 1.6 + 9.05, 0., -.6 - 4.4625, 0, "ONLY"); gMC->Gspos("BKHL", 4, "BACK", -.8 - 11.4 - 1.6 - 9.05, 0., -.6 - 4.4625, 0, "ONLY"); gMC->Gspos("BKHL", 5, "BACK", .8 + 11.4+ 1.6 + 9.05, 0., .6 + 8.925 + 1.2 + 4.4625, 0, "ONLY"); gMC->Gspos("BKHL", 6, "BACK", -.8 - 11.4 - 1.6 - 9.05, 0., .6 + 8.925 + 1.2 + 4.4625, 0, "ONLY"); gMC->Gspos("BKHL", 7, "BACK", .8 + 11.4 + 1.6 + 9.05, 0., -.6 - 8.925 - 1.2 - 4.4625, 0, "ONLY"); gMC->Gspos("BKHL", 8, "BACK", -.8 - 11.4 - 1.6 - 9.05, 0., -.6 - 8.925 - 1.2 - 4.4625, 0, "ONLY"); //Place material inside RICH gMC->Gspos("SRIC", 1, "RICH", 0.,0., 0., 0, "ONLY"); // gMC->Gspos("AIR2", 1, "RICH", 66.3 + 1.2505, 1.276-P()->GapThickness()/2-P()->QuartzThickness()-P()->FreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.35, 0., 0, "ONLY"); // gMC->Gspos("AIR2", 2, "RICH", -66.3 - 1.2505,1.276-P()->GapThickness()/2-P()->QuartzThickness()-P()->FreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.35, 0., 0, "ONLY"); // gMC->Gspos("AIR3", 1, "RICH", 0., 1.276-P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.35, -68.35 - 1.25, 0, "ONLY"); // gMC->Gspos("AIR3", 2, "RICH", 0., 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.35, 68.35 + 1.25, 0, "ONLY"); gMC->Gspos("ALUM", 1, "SRIC", 0., 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .6 - .05 - .376 -.025, 0., 0, "ONLY"); gMC->Gspos("HONE", 1, "SRIC", 0., 1.276- P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .6 - .05 - .188, 0., 0, "ONLY"); gMC->Gspos("ALUM", 2, "SRIC", 0., 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .6 - .025, 0., 0, "ONLY"); gMC->Gspos("FOOT", 1, "SRIC", 64.95, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .3, 36.9, 0, "ONLY"); gMC->Gspos("FOOT", 2, "SRIC", 21.65, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .3 , 36.9, 0, "ONLY"); gMC->Gspos("FOOT", 3, "SRIC", -21.65, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .3, 36.9, 0, "ONLY"); gMC->Gspos("FOOT", 4, "SRIC", -64.95, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .3, 36.9, 0, "ONLY"); gMC->Gspos("FOOT", 5, "SRIC", 64.95, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .3, -36.9, 0, "ONLY"); gMC->Gspos("FOOT", 6, "SRIC", 21.65, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .3, -36.9, 0, "ONLY"); gMC->Gspos("FOOT", 7, "SRIC", -21.65, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .3, -36.9, 0, "ONLY"); gMC->Gspos("FOOT", 8, "SRIC", -64.95, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .4 - .3, -36.9, 0, "ONLY"); gMC->Gspos("OQUA", 1, "SRIC", 0., 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()- .2, 0., 0, "ONLY"); // Methane supports gMC->Gspos("SMLG", 1, "SRIC", pcX/2 + (66.3 - pcX/2)/2, 1.276 + .25, 0., 0, "ONLY"); gMC->Gspos("SMLG", 2, "SRIC", - pcX/2 - (66.3 - pcX/2)/2, 1.276 + .25, 0., 0, "ONLY"); gMC->Gspos("SMSH", 1, "SRIC", 0., 1.276 + .25, pcY/2 + (68.35 - pcY/2)/2, 0, "ONLY"); gMC->Gspos("SMSH", 2, "SRIC", 0., 1.276 + .25, - pcY/2 - (68.35 - pcY/2)/2, 0, "ONLY"); //Freon supports Float_t suppY = 1.276 - P()->GapThickness()/2- P()->QuartzThickness() -P()->FreonThickness() - .2 + .3; //y position of freon supports gMC->Gspos("SFLG", 1, "SRIC", P()->QuartzWidth()/2 + (66.3 - P()->QuartzWidth()/2)/2, suppY, 0., 0, "ONLY"); gMC->Gspos("SFLG", 2, "SRIC", - P()->QuartzWidth()/2 - (66.3 - P()->QuartzWidth()/2)/2, suppY, 0., 0, "ONLY"); gMC->Gspos("SFSH", 1, "SRIC", 0., suppY, P()->QuartzLength()/2 + (68.35 - P()->QuartzLength()/2)/2, 0, "ONLY"); gMC->Gspos("SFSH", 2, "SRIC", 0., suppY, - P()->QuartzLength()/2 - (68.35 - P()->QuartzLength()/2)/2, 0, "ONLY"); AliMatrix(idrotm[1019], 0., 0., 90., 0., 90., 90.); //Place spacers Int_t nspacers = 30; for (i = 0; i < nspacers/3; i++) { zs = -11.6/2 + (TMath::Abs(nspacers/6) - i) * 12.2; gMC->Gspos("SPAC", i, "FRE1", 10.5, 0., zs, idrotm[1019], "ONLY"); //Original settings } for (i = nspacers/3; i < (nspacers*2)/3; i++) { zs = -11.6/2 + (nspacers/3 + TMath::Abs(nspacers/6) - i) * 12.2; gMC->Gspos("SPAC", i, "FRE1", 0, 0., zs, idrotm[1019], "ONLY"); //Original settings } for (i = (nspacers*2)/3; i < nspacers; ++i) { zs = -11.6/2 + ((nspacers*2)/3 + TMath::Abs(nspacers/6) - i) * 12.2; gMC->Gspos("SPAC", i, "FRE1", -10.5, 0., zs, idrotm[1019], "ONLY"); //Original settings } for (i = 0; i < nspacers/3; i++) { zs = -11.6/2 + (TMath::Abs(nspacers/6) - i) * 12.2; gMC->Gspos("SPAC", i, "FRE2", 10.5, 0., zs, idrotm[1019], "ONLY"); //Original settings } for (i = nspacers/3; i < (nspacers*2)/3; i++) { zs = -11.6/2 + (nspacers/3 + TMath::Abs(nspacers/6) - i) * 12.2; gMC->Gspos("SPAC", i, "FRE2", 0, 0., zs, idrotm[1019], "ONLY"); //Original settings } for (i = (nspacers*2)/3; i < nspacers; ++i) { zs = -11.6/2 + ((nspacers*2)/3 + TMath::Abs(nspacers/6) - i) * 12.2; gMC->Gspos("SPAC", i, "FRE2", -10.5, 0., zs, idrotm[1019], "ONLY"); //Original settings } gMC->Gspos("FRE1", 1, "OQF1", 0., 0., 0., 0, "ONLY"); gMC->Gspos("FRE2", 1, "OQF2", 0., 0., 0., 0, "ONLY"); gMC->Gspos("OQF1", 1, "SRIC", P()->OuterFreonWidth()/2 + P()->InnerFreonWidth()/2 + 2, 1.276 - P()->GapThickness()/2- P()->QuartzThickness() -P()->FreonThickness()/2, 0., 0, "ONLY"); //Original settings (31.3) gMC->Gspos("OQF2", 2, "SRIC", 0., 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()/2, 0., 0, "ONLY"); //Original settings gMC->Gspos("OQF1", 3, "SRIC", - (P()->OuterFreonWidth()/2 + P()->InnerFreonWidth()/2) - 2, 1.276 - P()->GapThickness()/2 - P()->QuartzThickness() - P()->FreonThickness()/2, 0., 0, "ONLY"); //Original settings (-31.3) gMC->Gspos("QUAR", 1, "SRIC", 0., 1.276 - P()->GapThickness()/2 - P()->QuartzThickness()/2, 0., 0, "ONLY"); gMC->Gspos("GAP ", 1, "META", 0., P()->GapThickness()/2 - P()->GapAmp()/2 - 0.0001, 0., 0, "ONLY"); gMC->Gspos("META", 1, "SRIC", 0., 1.276, 0., 0, "ONLY"); gMC->Gspos("CSI ", 1, "SRIC", 0., 1.276 + P()->GapThickness()/2 + .25, 0., 0, "ONLY"); //Wire support placing gMC->Gspos("WSG2", 1, "GAP ", 0., P()->GapAmp()/2 - .1, 0., 0, "ONLY"); gMC->Gspos("WSG1", 1, "CSI ", 0., 0., 0., 0, "ONLY"); gMC->Gspos("WSMe", 1, "SRIC ", 0., 1.276 + P()->GapThickness()/2 + .5 + 1.05, 0., 0, "ONLY"); //Backplane placing gMC->Gspos("BACK", 1, "SRIC ", -33.15, 1.276 + P()->GapThickness()/2 + .5 + 2.1 + 2, 43.3, 0, "ONLY"); gMC->Gspos("BACK", 2, "SRIC ", 33.15, 1.276 + P()->GapThickness()/2 + .5 + 2.1 + 2 , 43.3, 0, "ONLY"); gMC->Gspos("BACK", 3, "SRIC ", -33.15, 1.276 + P()->GapThickness()/2 + .5 + 2.1 + 2, 0., 0, "ONLY"); gMC->Gspos("BACK", 4, "SRIC ", 33.15, 1.276 + P()->GapThickness()/2 + .5 + 2.1 + 2, 0., 0, "ONLY"); gMC->Gspos("BACK", 5, "SRIC ", 33.15, 1.276 + P()->GapThickness()/2 + .5 + 2.1 + 2, -43.3, 0, "ONLY"); gMC->Gspos("BACK", 6, "SRIC ", -33.15, 1.276 + P()->GapThickness()/2 + .5 + 2.1 + 2, -43.3, 0, "ONLY"); //PCB placing gMC->Gspos("PCB ", 1, "SRIC ", 0., 1.276 + P()->GapThickness()/2 + .5 + 1.05, pcX/4 + .5025 + 2.5, 0, "ONLY"); gMC->Gspos("PCB ", 2, "SRIC ", 0., 1.276 + P()->GapThickness()/2 + .5 + 1.05, -pcX/4 - .5025 - 2.5, 0, "ONLY"); //place chambers into mother volume ALIC for(int i=1;i<=kNchambers;i++){ AliMatrix(idrotm[1000+i],C(i)->ThetaXd(),C(i)->PhiXd(), C(i)->ThetaYd(),C(i)->PhiYd(), C(i)->ThetaZd(),C(i)->PhiZd()); gMC->Gspos("RICH",i,"ALIC",C(i)->X(),C(i)->Y(),C(i)->Z(),idrotm[1000+i], "ONLY"); } if(GetDebug())Info("CreateGeometry","Stop main."); }//void AliRICH::CreateGeometry() //__________________________________________________________________________________________________ void AliRICH::Reconstruct()const { AliRICHClusterFinder finder(const_cast(this)); finder.Exec(); } //__________________________________________________________________________________________________ void AliRICH::ControlPlots() { //Creates a set of hists to control the results of simulation TH1F *pHxD=0,*pHyD=0,*pNumClusH1=0, *pQdcH1=0, *pSizeH1=0, *pPureMipQdcH1=0,*pPureMipSizeH1=0, *pPureCerQdcH1=0,*pPureCerSizeH1=0, *pPureFeeQdcH1=0,*pPureFeeSizeH1=0, *pMipQdcH1=0, *pPhotQdcH1=0; TH2F *pMapH2=0,*pPureMipMapH2=0,*pPureCerMapH2=0,*pPureFeeMapH2=0; Bool_t isDig =!GetLoader()->LoadDigits(); Bool_t isClus=!GetLoader()->LoadRecPoints(); if(!isDig && !isClus){Error("ControlPlots","No digits and clusters! Nothing to do.");return;} TStopwatch sw;TDatime time; TFile *pFile = new TFile("$(HOME)/RCP.root","RECREATE"); if(isDig){ cout<<"Digits available\n"; pHxD=new TH1F("HitDigitDiffX","Hit-Digits diff X all chambers;diff [cm]",100,-10,10); pHyD=new TH1F("HitDigitDiffY","Hit-Digits diff Y all chambers;diff [cm]",100,-10,10); }//isDig if(isClus){ cout<<"Clusters available\n"; pNumClusH1=new TH1F("NumClusPerEvent","Number of clusters per event;number",50,0,49); pQdcH1 =new TH1F("ClusQdc", "Cluster Charge all chambers;q [QDC]",R()->P()->MaxQdc(),0,R()->P()->MaxQdc()); pSizeH1 =new TH1F("ClusSize", "Cluster size all chambers;size [number of pads in cluster]",100,0,100); pMapH2 =new TH2F("ClusMap", "Cluster map;x [cm];y [cm]",1000,0,R()->P()->PcSizeX(),1000,0,R()->P()->PcSizeY()); pMipQdcH1 =new TH1F("QdcMip" ,"MIP Cluster Charge all chambers;q [QDC]",R()->P()->MaxQdc(),0,R()->P()->MaxQdc()); pPhotQdcH1 =new TH1F("QdcPhot" ,"Cer+Fee Cluster Charge all chambers;q [QDC]",R()->P()->MaxQdc(),0,R()->P()->MaxQdc()); pPureMipQdcH1 =new TH1F("QdcPureMip" ,"MIP only Cluster Charge all chambers;q [QDC]",R()->P()->MaxQdc(),0,R()->P()->MaxQdc()); pPureMipSizeH1=new TH1F("SizePureMip" ,"MIP only Cluster size all chambers;size [number of pads in cluster]",100,0,100); pPureMipMapH2 =new TH2F("MapPureMip" ,"MIP only Cluster map;x [cm];y [cm]",1000,0,R()->P()->PcSizeX(),1000,0,R()->P()->PcSizeY()); pPureCerQdcH1 =new TH1F("QdcPureCer" ,"Cerenkov only Cluster Charge all chambers;q [QDC]",R()->P()->MaxQdc(),0,R()->P()->MaxQdc()); pPureCerSizeH1=new TH1F("SizePureCer" ,"Cernekov only Cluster size all chambers;size [number of pads in cluster]",100,0,100); pPureCerMapH2 =new TH2F("MapPureCer" ,"Cerenkov only Cluster map;x [cm];y [cm]",1000,0,R()->P()->PcSizeX(),1000,0,R()->P()->PcSizeY()); pPureFeeQdcH1 =new TH1F("QdcPureFee" ,"Feedback only Cluster Charge all chambers;q [QDC]",R()->P()->MaxQdc(),0,R()->P()->MaxQdc()); pPureFeeSizeH1=new TH1F("SizePureFee" ,"Feedback only Cluster size all chambers;size [number of pads in cluster]",100,0,100); pPureFeeMapH2 =new TH2F("MapPureFee" ,"Feedback only Cluster map;x [cm];y [cm]",1000,0,R()->P()->PcSizeX(),1000,0,R()->P()->PcSizeY()); }//isClus for(Int_t iEvtN=0;iEvtN < GetLoader()->GetRunLoader()->GetAliRun()->GetEventsPerRun();iEvtN++){//events loop GetLoader()->GetRunLoader()->GetEvent(iEvtN); //gets current event if(!GetLoader()->TreeH()) GetLoader()->LoadHits(); for(Int_t iPrimN=0;iPrimN < GetLoader()->TreeH()->GetEntries();iPrimN++){//prims loop GetLoader()->TreeH()->GetEntry(iPrimN); } if(isClus) GetLoader()->TreeR()->GetEntry(0); if(isDig) GetLoader()->TreeD()->GetEntry(0); for(Int_t iChamN=1;iChamN<=7;iChamN++){//chambers loop if(isClus){ Int_t iNclusCham=Clusters(iChamN)->GetEntries(); if(iNclusCham) pNumClusH1->Fill(iNclusCham);//number of clusters per event for(Int_t iClusN=0;iClusNAt(iClusN); pQdcH1 ->Fill(pClus->Q()); pSizeH1 ->Fill(pClus->Size()); pMapH2 ->Fill(pClus->X(),pClus->Y()); //common if(pClus->IsSingleMip()) {pPureMipQdcH1 ->Fill(pClus->Q()); pPureMipSizeH1->Fill(pClus->Size()); pPureMipMapH2 ->Fill(pClus->X(),pClus->Y());}//Pure Mips if(pClus->IsSingleCerenkov()){pPureCerQdcH1 ->Fill(pClus->Q()); pPureCerSizeH1->Fill(pClus->Size()); pPureCerMapH2 ->Fill(pClus->X(),pClus->Y());}//Pure Cerenkovs if(pClus->IsSingleFeedback()){pPureFeeQdcH1 ->Fill(pClus->Q()); pPureFeeSizeH1->Fill(pClus->Size()); pPureFeeMapH2 ->Fill(pClus->X(),pClus->Y());}//Pure Feedbacks if(pClus->IsMip()) {pMipQdcH1 ->Fill(pClus->Q());} //MIP+ other contributions if(!pClus->IsPureMip()) pPhotQdcH1->Fill(pClus->Q()); //not MIP }//clusters loop }//isClus if(isDig){ for(Int_t iDigN=0;iDigNDigits(iChamN)->GetEntries();iDigN++){//digits loop AliRICHdigit *pDig=(AliRICHdigit*)R()->Digits(iChamN)->At(iDigN); AliRICHhit *pHit=Hit(pDig->GetTrack(0)); TVector2 hitV2=R()->C(iChamN)->Glob2Loc(pHit->OutX3()); TVector2 digV2=R()->P()->Pad2Loc(pDig->Pad()); pHxD->Fill(hitV2.X()-digV2.X()); pHyD->Fill(hitV2.Y()-digV2.Y()); }//digits loop }//isDig }//chambers loop Info("ControlPlots","Event %i processed.",iEvtN); }//events loop if(isDig) GetLoader()->UnloadDigits(); if(isClus) GetLoader()->UnloadRecPoints(); pFile->Write(); delete pFile; sw.Print();time.Print(); }//ControlPlots() //__________________________________________________________________________________________________ AliRICHhit* AliRICH::Hit(Int_t tid) { //defines which hit provided by given tid for the currently loaded event R()->GetLoader()->LoadHits(); for(Int_t iPrimN=0;iPrimNGetLoader()->TreeH()->GetEntries();iPrimN++){//prims loop R()->GetLoader()->TreeH()->GetEntry(iPrimN); for(Int_t iHitN=0;iHitNHits()->GetEntries();iHitN++){ AliRICHhit *pHit=(AliRICHhit*)R()->Hits()->At(iHitN); if(tid==pHit->Track()) {R()->GetLoader()->UnloadHits();return pHit;} }//hits }//prims loop R()->GetLoader()->UnloadHits(); return 0; } //__________________________________________________________________________________________________ void AliRICH::PrintHits(Int_t iEvtN) { //Prints a list of RICH hits for a given event. Default is event number 0. Info("PrintHits","List of RICH hits for event %i",iEvtN); R()->GetLoader()->GetRunLoader()->GetEvent(iEvtN); if(R()->GetLoader()->LoadHits()) return; Int_t iTotalHits=0; for(Int_t iPrimN=0;iPrimNGetLoader()->TreeH()->GetEntries();iPrimN++){//prims loop R()->GetLoader()->TreeH()->GetEntry(iPrimN); R()->Hits()->Print(); iTotalHits+=R()->Hits()->GetEntries(); } R()->GetLoader()->UnloadHits(); Info("PrintHits","totally %i hits",iTotalHits); } //__________________________________________________________________________________________________ void AliRICH::PrintSDigits(Int_t iEvtN) { //prints a list of RICH sdigits for a given event Info("PrintSDigits","List of RICH sdigits for event %i",iEvtN); R()->GetLoader()->GetRunLoader()->GetEvent(iEvtN); if(R()->GetLoader()->LoadSDigits()) return; R()->GetLoader()->TreeS()->GetEntry(0); R()->SDigits()->Print(); R()->GetLoader()->UnloadSDigits(); Info("PrintSDigits","totally %i sdigits",R()->SDigits()->GetEntries()); } //__________________________________________________________________________________________________ void AliRICH::PrintDigits(Int_t iEvtN) { //prints a list of RICH digits for a given event Info("PrintDigits","List of RICH digits for event %i",iEvtN); R()->GetLoader()->GetRunLoader()->GetEvent(iEvtN); if(R()->GetLoader()->LoadDigits()) return; Int_t iTotalDigits=0; R()->GetLoader()->TreeD()->GetEntry(0); for(Int_t iChamber=1;iChamber<=kNchambers;iChamber++){ R()->Digits(iChamber)->Print(); iTotalDigits+=R()->Digits(iChamber)->GetEntries(); } R()->GetLoader()->UnloadDigits(); Info("PrintDigits","totally %i Digits",iTotalDigits); } //__________________________________________________________________________________________________ void AliRICH::PrintClusters(Int_t iEvtN) { //prints a list of RICH clusters for a given event Info("PrintClusters","List of RICH clusters for event %i",iEvtN); R()->GetLoader()->GetRunLoader()->GetEvent(iEvtN); if(R()->GetLoader()->LoadRecPoints()) return; Int_t iTotalClusters=0; R()->GetLoader()->TreeR()->GetEntry(0); for(Int_t iChamber=1;iChamber<=kNchambers;iChamber++){ R()->Clusters(iChamber)->Print(); iTotalClusters+=R()->Clusters(iChamber)->GetEntries(); } R()->GetLoader()->UnloadRecPoints(); Info("PrintClusters","totally %i clusters",iTotalClusters); } //__________________________________________________________________________________________________ void AliRICH::FillESD(AliESD *pESD)const { //This methode fills AliESDtrack with information from RICH Info("FillESD","Start with %i tracks",pESD->GetNumberOfTracks()); const Double_t masses[5]={0.000511,0.105658,0.139567,0.493677,0.93828};//electron,muon,pion,kaon,proton const Double_t refIndex = 1.29052; Double_t thetaExp = 0.7; Double_t thetaTh[5]; Double_t sinThetaThNorm; Double_t sigmaThetaTh[5]; Double_t height[5]; Double_t totalHeight=0; for(Int_t iTrackN=0;iTrackNGetNumberOfTracks();iTrackN++){//ESD tracks loop AliESDtrack *pTrack = pESD->GetTrack(iTrackN); pTrack->Print(""); // TVector2 x2=P()->HelixCross(pTrack);//returns cross point of track with RICH PC in LRS Double_t pmod = pTrack->GetP(); for(Int_t iPart=4;iPart>=0;iPart--){ Double_t cosThetaTh = TMath::Sqrt(masses[iPart]*masses[iPart]+pmod*pmod)/(refIndex*pmod); if(cosThetaTh>=1) {break;} thetaTh[iPart] = TMath::ACos(cosThetaTh); sinThetaThNorm = TMath::Sin(thetaTh[iPart])/TMath::Sqrt(1-1/(refIndex*refIndex)); sigmaThetaTh[iPart] = (0.014*(1/sinThetaThNorm-1) + 0.0043)*1.25; height[iPart] = TMath::Gaus(thetaExp,thetaTh[iPart],sigmaThetaTh[iPart]); totalHeight +=height[iPart]; } pTrack->SetRICHsignal(thetaExp); Double_t richPID[5]; for(Int_t iPart=0;iPart<5;iPart++) richPID[iPart] = height[iPart]/totalHeight; pTrack->SetRICHpid(richPID); }//ESD tracks loop }