/*
$Log$
+ Revision 1.57 2001/11/09 17:29:31 dibari
+ Setters fro models moved to header
+
+ Revision 1.56 2001/11/02 15:37:25 hristov
+ Digitizer class created. Code cleaning and bug fixes (J.Chudoba)
+
+ Revision 1.55 2001/10/23 13:03:35 hristov
+ The access to several data members was changed from public to protected. The digitisation was adapted to the multi-event case (J.Chudoba)
+
+ Revision 1.54 2001/09/07 08:38:10 hristov
+ Pointers initialised to 0 in the default constructors
+
+ Revision 1.53 2001/08/30 09:51:23 hristov
+ The operator[] is replaced by At() or AddAt() in case of TObjArray.
+
+ Revision 1.52 2001/05/16 14:57:20 alibrary
+ New files for folders and Stack
+
+ Revision 1.51 2001/05/14 10:18:55 hristov
+ Default arguments declared once
+
+ Revision 1.50 2001/05/10 14:44:16 jbarbosa
+ Corrected some overlaps (thanks I. Hrivnacovna).
+
+ Revision 1.49 2001/05/10 12:23:49 jbarbosa
+ Repositioned the RICH modules.
+ Eliminated magic numbers.
+ Incorporated diagnostics (from macros).
+
+ Revision 1.48 2001/03/15 10:35:00 jbarbosa
+ Corrected bug in MakeBranch (was using a different version of STEER)
+
+ Revision 1.47 2001/03/14 18:13:56 jbarbosa
+ Several changes to adapt to new IO.
+ Removed digitising function, using AliRICHMerger::Digitise from now on.
+
+ Revision 1.46 2001/03/12 17:46:33 hristov
+ Changes needed on Sun with CC 5.0
+
+ Revision 1.45 2001/02/27 22:11:46 jbarbosa
+ Testing TreeS, removing of output.
+
+ Revision 1.44 2001/02/27 15:19:12 jbarbosa
+ Transition to SDigits.
+
+ Revision 1.43 2001/02/23 17:19:06 jbarbosa
+ Corrected photocathode definition in BuildGeometry().
+
+ Revision 1.42 2001/02/13 20:07:23 jbarbosa
+ Parametrised definition of photcathode dimensions. New spacers. New data members in AliRICHHit to store particle momentum
+ when entering the freon. Corrected calls to particle stack.
+
+ Revision 1.41 2001/01/26 20:00:20 hristov
+ Major upgrade of AliRoot code
+
+ Revision 1.40 2001/01/24 20:58:03 jbarbosa
+ Enhanced BuildGeometry. Now the photocathodes are drawn.
+
+ Revision 1.39 2001/01/22 21:40:24 jbarbosa
+ Removing magic numbers
+
+ Revision 1.37 2000/12/20 14:07:25 jbarbosa
+ Removed dependencies on TGeant3 (thanks to F. Carminati and I. Hrivnacova)
+
+ Revision 1.36 2000/12/18 17:45:54 jbarbosa
+ Cleaned up PadHits object.
+
Revision 1.35 2000/12/15 16:49:40 jbarbosa
Geometry and materials updates (wire supports, pcbs, backplane supports, frame).
#include <TParticle.h>
#include <TGeometry.h>
#include <TTree.h>
+#include <TH1.h>
+#include <TH2.h>
+#include <TCanvas.h>
+//#include <TPad.h>
+#include <TF1.h>
#include <iostream.h>
#include <strings.h>
#include "AliRICH.h"
#include "AliSegmentation.h"
+#include "AliRICHSegmentationV0.h"
#include "AliRICHHit.h"
#include "AliRICHCerenkov.h"
-#include "AliRICHPadHit.h"
+#include "AliRICHSDigit.h"
#include "AliRICHDigit.h"
#include "AliRICHTransientDigit.h"
#include "AliRICHRawCluster.h"
#include "AliRICHRecHit3D.h"
#include "AliRICHHitMapA1.h"
#include "AliRICHClusterFinder.h"
+#include "AliRICHMerger.h"
#include "AliRun.h"
#include "AliMC.h"
#include "AliMagF.h"
#include "AliPDG.h"
#include "AliPoints.h"
#include "AliCallf77.h"
-#include "TGeant3.h"
-// Static variables for the pad-hit iterator routines
-static Int_t sMaxIterPad=0;
+
+static Int_t sMaxIterPad=0; // Static variables for the pad-hit iterator routines
static Int_t sCurIterPad=0;
-static TClonesArray *fClusters2;
-static TClonesArray *fHits2;
-static TTree *TrH1;
ClassImp(AliRICH)
//___________________________________________
+// RICH manager class
+//Begin_Html
+/*
+ <img src="gif/alirich.gif">
+*/
+//End_Html
+
AliRICH::AliRICH()
{
-// Default constructor for RICH manager class
+// Default ctor should not contain any new operators
+ cout<<ClassName()<<"::named ctor(sName,sTitle)>\n"; // no way to control it as ctor is called before call to SetDebugXXXX()
fIshunt = 0;
fHits = 0;
- fPadHits = 0;
- fNPadHits = 0;
+ fSDigits = 0;
+ fNSDigits = 0;
fNcerenkovs = 0;
fDchambers = 0;
fRecHits1D = 0;
fRawClusters = 0;
fChambers = 0;
fCerenkovs = 0;
- for (Int_t i=0; i<7; i++)
- {
+ for (Int_t i=0; i<7; i++){
fNdch[i] = 0;
fNrawch[i] = 0;
fNrechits1D[i] = 0;
fNrechits3D[i] = 0;
- }
+ }
fFileName = 0;
-}
+ fMerger = 0;
+}//AliRICH::AliRICH()
-//___________________________________________
AliRICH::AliRICH(const char *name, const char *title)
: AliDetector(name,title)
{
-//Begin_Html
-/*
- <img src="gif/alirich.gif">
-*/
-//End_Html
-
+// Named ctor
+ cout<<ClassName()<<"::named ctor(sName,sTitle)>\n"; // no way to control it as ctor is called before call to SetDebugXXXX()
+
fHits = new TClonesArray("AliRICHHit",1000 );
gAlice->AddHitList(fHits);
- fPadHits = new TClonesArray("AliRICHPadHit",100000);
+ fSDigits = new TClonesArray("AliRICHSDigit",100000);
fCerenkovs = new TClonesArray("AliRICHCerenkov",1000);
gAlice->AddHitList(fCerenkovs);
- //gAlice->AddHitList(fHits);
- fNPadHits = 0;
+ fNSDigits = 0;
fNcerenkovs = 0;
fIshunt = 0;
Int_t i;
for (i=0; i<kNCH ;i++) {
- (*fDchambers)[i] = new TClonesArray("AliRICHDigit",10000);
+ //PH (*fDchambers)[i] = new TClonesArray("AliRICHDigit",10000);
+ fDchambers->AddAt(new TClonesArray("AliRICHDigit",10000), i);
fNdch[i]=0;
}
//printf("Created fRwClusters with adress:%p",fRawClusters);
for (i=0; i<kNCH ;i++) {
- (*fRawClusters)[i] = new TClonesArray("AliRICHRawCluster",10000);
+ //PH (*fRawClusters)[i] = new TClonesArray("AliRICHRawCluster",10000);
+ fRawClusters->AddAt(new TClonesArray("AliRICHRawCluster",10000), i);
fNrawch[i]=0;
}
//fNrechits = new Int_t[kNCH];
for (i=0; i<kNCH ;i++) {
- (*fRecHits1D)[i] = new TClonesArray("AliRICHRecHit1D",1000);
+ //PH (*fRecHits1D)[i] = new TClonesArray("AliRICHRecHit1D",1000);
+ fRecHits1D->AddAt(new TClonesArray("AliRICHRecHit1D",1000), i);
}
for (i=0; i<kNCH ;i++) {
- (*fRecHits3D)[i] = new TClonesArray("AliRICHRecHit3D",1000);
+ //PH (*fRecHits3D)[i] = new TClonesArray("AliRICHRecHit3D",1000);
+ fRecHits3D->AddAt(new TClonesArray("AliRICHRecHit3D",1000), i);
}
//printf("Created fRecHits with adress:%p",fRecHits);
(*fChambers)[i] = new AliRICHChamber();*/
fFileName = 0;
-
+ fMerger = 0;
}
AliRICH::AliRICH(const AliRICH& RICH)
{
-// Copy Constructor
+// Copy ctor
}
-//___________________________________________
AliRICH::~AliRICH()
{
-
-// Destructor of RICH manager class
+// Dtor of RICH manager class
+ if(IsDebugStart()) cout<<ClassName()<<"::default dtor()>\n";
fIshunt = 0;
delete fHits;
- delete fPadHits;
+ delete fSDigits;
delete fCerenkovs;
+
+ //PH Delete TObjArrays
+ if (fChambers) {
+ fChambers->Delete();
+ delete fChambers;
+ }
+ if (fDchambers) {
+ fDchambers->Delete();
+ delete fDchambers;
+ }
+ if (fRawClusters) {
+ fRawClusters->Delete();
+ delete fRawClusters;
+ }
+ if (fRecHits1D) {
+ fRecHits1D->Delete();
+ delete fRecHits1D;
+ }
+ if (fRecHits3D) {
+ fRecHits3D->Delete();
+ delete fRecHits3D;
+ }
+
}
-//___________________________________________
-void AliRICH::AddHit(Int_t track, Int_t *vol, Float_t *hits)
+
+//_____________________________________________________________________________
+Int_t AliRICH::Hits2SDigits(Float_t xhit,Float_t yhit,Float_t eloss, Int_t idvol, ResponseType res)
{
+// Calls the charge disintegration method of the current chamber and adds
+// the simulated cluster to the root tree
+ if(IsDebugHit()||IsDebugDigit()) cout<<ClassName()<<"::Hits2SDigits(...)>\n";
+
+ Int_t clhits[5];
+ Float_t newclust[4][500];
+ Int_t nnew;
+
+//
+// Integrated pulse height on chamber
+
+ clhits[0]=fNhits+1;
-//
-// Adds a hit to the Hits list
+ ((AliRICHChamber*)fChambers->At(idvol))->DisIntegration(eloss, xhit, yhit, nnew, newclust, res);
+ Int_t ic=0;
+
//
+// Add new clusters
+ for (Int_t i=0; i<nnew; i++) {
+ if (Int_t(newclust[0][i]) > 0) {
+ ic++;
+// Cluster Charge
+ clhits[1] = Int_t(newclust[0][i]);
+// Pad: ix
+ clhits[2] = Int_t(newclust[1][i]);
+// Pad: iy
+ clhits[3] = Int_t(newclust[2][i]);
+// Pad: chamber sector
+ clhits[4] = Int_t(newclust[3][i]);
+
+ //printf(" %d %d %d %d %d\n", clhits[0], clhits[1], clhits[2], clhits[3], clhits[4]);
+
+ AddSDigit(clhits);
+ }
+ }
+
+ if (gAlice->TreeS()){
+ gAlice->TreeS()->Fill();
+ gAlice->TreeS()->Write(0,TObject::kOverwrite);
+ //printf("Filled SDigits...\n");
+ }
+
+ return nnew;
+}//Int_t AliRICH::Hits2SDigits(Float_t xhit,Float_t yhit,Float_t eloss, Int_t idvol, ResponseType res)
+
+void AliRICH::Hits2SDigits()
+{
+// Dummy: sdigits are created during transport.
+// Called from alirun.
+ if(IsDebugHit()||IsDebugDigit()) cout<<ClassName()<<"::Hits2SDigits()>\n";
+
+
+ int nparticles = gAlice->GetNtrack();
+ cout << "Particles (RICH):" <<nparticles<<endl;
+ if (nparticles > 0) printf("SDigits were already generated.\n");
+
+}
+
+//___________________________________________
+void AliRICH::SDigits2Digits(Int_t nev, Int_t flag)
+{
+// Generate digits.
+// Called from macro. Multiple events, more functionality.
+ if(IsDebugDigit()) cout<<ClassName()<<"::SDigits2Digits()>\n";
+
+ AliRICHChamber* iChamber;
+
+ printf("Generating tresholds...\n");
+
+ for(Int_t i=0;i<7;i++) {
+ iChamber = &(Chamber(i));
+ iChamber->GenerateTresholds();
+ }
+
+ int nparticles = gAlice->GetNtrack();
+ cout << "Particles (RICH):" <<nparticles<<endl;
+ if (nparticles <= 0) return;
+ if (!fMerger) {
+ fMerger = new AliRICHMerger();
+ }
+ fMerger->Init();
+ fMerger->Digitise(nev,flag);
+}
+//___________________________________________
+void AliRICH::SDigits2Digits()
+{
+ SDigits2Digits(0,0);
+}
+//___________________________________________
+void AliRICH::Digits2Reco()
+{
+// Generate clusters
+// Called from alirun, single event only.
+ if(IsDebugDigit()||IsDebugReco()) cout<<ClassName()<<"::Digits2Reco()>\n";
+
+
+ int nparticles = gAlice->GetNtrack();
+ cout << "Particles (RICH):" <<nparticles<<endl;
+ if (nparticles > 0) FindClusters(0,0);
+
+}
+
+void AliRICH::AddHit(Int_t track, Int_t *vol, Float_t *hits)
+{
+// Adds the current hit to the RICH hits list
+ if(IsDebugHit()) cout<<ClassName()<<"::AddHit(...)>\n";
TClonesArray &lhits = *fHits;
new(lhits[fNhits++]) AliRICHHit(fIshunt,track,vol,hits);
}
-//_____________________________________________________________________________
+
void AliRICH::AddCerenkov(Int_t track, Int_t *vol, Float_t *cerenkovs)
{
-
-//
-// Adds a RICH cerenkov hit to the Cerenkov Hits list
-//
+// Adds a RICH cerenkov hit to the Cerenkov Hits list
+ if(IsDebugHit()) cout<<ClassName()<<"::AddCerenkov()>\n";
TClonesArray &lcerenkovs = *fCerenkovs;
new(lcerenkovs[fNcerenkovs++]) AliRICHCerenkov(fIshunt,track,vol,cerenkovs);
- //printf ("Done for Cerenkov %d\n\n\n\n",fNcerenkovs);
}
-//___________________________________________
-void AliRICH::AddPadHit(Int_t *clhits)
-{
-//
-// Add a RICH pad hit to the list
-//
+void AliRICH::AddSDigit(Int_t *aSDigit)
+{
+// Adds the current S digit to the RICH list of S digits
+ if(IsDebugDigit()) cout<<ClassName()<<"::AddSDigit()>\n";
- TClonesArray &lPadHits = *fPadHits;
- new(lPadHits[fNPadHits++]) AliRICHPadHit(clhits);
+ TClonesArray &lSDigits = *fSDigits;
+ new(lSDigits[fNSDigits++]) AliRICHSDigit(aSDigit);
}
-//_____________________________________________________________________________
+
+
void AliRICH::AddDigits(Int_t id, Int_t *tracks, Int_t *charges, Int_t *digits)
{
+// Add a RICH digit to the list
+ if(IsDebugDigit()) cout<<ClassName()<<"::AddDigit()>\n";
- //
- // Add a RICH digit to the list
- //
-
- TClonesArray &ldigits = *((TClonesArray*)(*fDchambers)[id]);
- new(ldigits[fNdch[id]++]) AliRICHDigit(tracks,charges,digits);
+ TClonesArray &ldigits = *((TClonesArray*)fDchambers->At(id));
+ new(ldigits[fNdch[id]++]) AliRICHDigit(tracks,charges,digits);
}
-//_____________________________________________________________________________
void AliRICH::AddRawCluster(Int_t id, const AliRICHRawCluster& c)
{
- //
- // Add a RICH digit to the list
- //
+// Add a RICH digit to the list
+
+ if(IsDebugStart())
+ cout<<ClassName()<<"::AddRawCluster()>\n";
- TClonesArray &lrawcl = *((TClonesArray*)(*fRawClusters)[id]);
+ //PH TClonesArray &lrawcl = *((TClonesArray*)(*fRawClusters)[id]);
+ TClonesArray &lrawcl = *((TClonesArray*)fRawClusters->At(id));
new(lrawcl[fNrawch[id]++]) AliRICHRawCluster(c);
}
// Add a RICH reconstructed hit to the list
//
- TClonesArray &lrec1D = *((TClonesArray*)(*fRecHits1D)[id]);
+ //PH TClonesArray &lrec1D = *((TClonesArray*)(*fRecHits1D)[id]);
+ TClonesArray &lrec1D = *((TClonesArray*)fRecHits1D->At(id));
new(lrec1D[fNrechits1D[id]++]) AliRICHRecHit1D(id,rechit,photons,padsx,padsy);
}
//_____________________________________________________________________________
void AliRICH::AddRecHit3D(Int_t id, Float_t *rechit)
{
-
- //
- // Add a RICH reconstructed hit to the list
- //
+// Add a RICH reconstructed hit to the list
- TClonesArray &lrec3D = *((TClonesArray*)(*fRecHits3D)[id]);
+ TClonesArray &lrec3D = *((TClonesArray*)fRecHits3D->At(id));
new(lrec3D[fNrechits3D[id]++]) AliRICHRecHit3D(id,rechit);
}
//
// Builds a TNode geometry for event display
//
- TNode *node, *top;
+ TNode *node, *subnode, *top;
- const int kColorRICH = kGreen;
+ const int kColorRICH = kRed;
//
top=gAlice->GetGeometry()->GetNode("alice");
-
+
+ AliRICH *pRICH = (AliRICH *) gAlice->GetDetector("RICH");
+ AliRICHSegmentationV0* segmentation;
+ AliRICHChamber* iChamber;
+ AliRICHGeometry* geometry;
+
+ iChamber = &(pRICH->Chamber(0));
+ segmentation=(AliRICHSegmentationV0*) iChamber->GetSegmentationModel();
+ geometry=iChamber->GetGeometryModel();
new TBRIK("S_RICH","S_RICH","void",71.09999,11.5,73.15);
-
+
+ Float_t padplane_width = segmentation->GetPadPlaneWidth();
+ Float_t padplane_length = segmentation->GetPadPlaneLength();
+
+ //printf("\n\n\n\n\n In BuildGeometry() npx: %d, npy: %d, dpx: %f, dpy:%f\n\n\n\n\n\n",segmentation->Npx(),segmentation->Npy(),segmentation->Dpx(),segmentation->Dpy());
+
+ new TBRIK("PHOTO","PHOTO","void", padplane_width/2,.1,padplane_length/2);
+
+ //printf("\n\n\n\n\n Padplane w: %f l: %f \n\n\n\n\n", padplane_width/2,padplane_length/2);
+ //printf("\n\n\n\n\n Padplane w: %f l: %f \n\n\n\n\n", segmentation->GetPadPlaneWidth(), segmentation->GetPadPlaneLength());
+
+ Float_t offset = 490 + 1.276 - geometry->GetGapThickness()/2; //distance from center of mother volume to methane
+ Float_t deltaphi = 19.5; //phi angle between center of chambers - z direction
+ Float_t deltatheta = 20; //theta angle between center of chambers - x direction
+ Float_t cosphi = TMath::Cos(deltaphi*TMath::Pi()/180);
+ Float_t sinphi = TMath::Sin(deltaphi*TMath::Pi()/180);
+ Float_t costheta = TMath::Cos(deltatheta*TMath::Pi()/180);
+ Float_t sintheta = TMath::Sin(deltatheta*TMath::Pi()/180);
+
+ //printf("\n\n%f %f %f %f %f %f %f\n\n",offset,deltatheta,deltaphi,cosphi,costheta,sinphi,sintheta);
+
+ new TRotMatrix("rot993","rot993",90., 0. , 90. - deltaphi, 90. , deltaphi, -90. );
+ new TRotMatrix("rot994","rot994",90., -deltatheta , 90. , 90.- deltatheta , 0. , 0. );
+ new TRotMatrix("rot995","rot995",90., 0. , 90. , 90. , 0. , 0. );
+ new TRotMatrix("rot996","rot996",90., deltatheta , 90. , 90 + deltatheta , 0. , 0. );
+ new TRotMatrix("rot997","rot997",90., 360. - deltatheta, 108.2 , 90.- deltatheta ,18.2 , 90 - deltatheta);
+ new TRotMatrix("rot998","rot998",90., 0. , 90 + deltaphi , 90. , deltaphi, 90. );
+ new TRotMatrix("rot999","rot999",90., deltatheta , 108.2 , 90.+ deltatheta ,18.2 , 90 + deltatheta);
+
+ Float_t pos1[3]={0. , offset*cosphi , offset*sinphi};
+ Float_t pos2[3]={offset*sintheta , offset*costheta , 0. };
+ Float_t pos3[3]={0. , offset , 0.};
+ Float_t pos4[3]={-offset*sintheta , offset*costheta , 0.};
+ Float_t pos5[3]={offset*sinphi , offset*costheta*cosphi, -offset*sinphi};
+ Float_t pos6[3]={0. , offset*cosphi , -offset*sinphi};
+ Float_t pos7[3]={ -offset*sinphi , offset*costheta*cosphi, -offset*sinphi};
+
+
top->cd();
- Float_t pos1[3]={0,471.8999,165.2599};
+ //Float_t pos1[3]={0,471.8999,165.2599};
//Chamber(0).SetChamberTransform(pos1[0],pos1[1],pos1[2],
- new TRotMatrix("rot993","rot993",90,0,70.69,90,19.30999,-90);
+ //new TRotMatrix("rot993","rot993",90,0,70.69,90,19.30999,-90);
node = new TNode("RICH1","RICH1","S_RICH",pos1[0],pos1[1],pos1[2],"rot993");
-
-
node->SetLineColor(kColorRICH);
+ node->cd();
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
fNodes->Add(node);
- top->cd();
-
- Float_t pos2[3]={171,470,0};
+
+
+ top->cd();
+ //Float_t pos2[3]={171,470,0};
//Chamber(1).SetChamberTransform(pos2[0],pos2[1],pos2[2],
- new TRotMatrix("rot994","rot994",90,-20,90,70,0,0);
+ //new TRotMatrix("rot994","rot994",90,-20,90,70,0,0);
node = new TNode("RICH2","RICH2","S_RICH",pos2[0],pos2[1],pos2[2],"rot994");
-
-
node->SetLineColor(kColorRICH);
+ node->cd();
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
fNodes->Add(node);
+
+
top->cd();
- Float_t pos3[3]={0,500,0};
+ //Float_t pos3[3]={0,500,0};
//Chamber(2).SetChamberTransform(pos3[0],pos3[1],pos3[2],
- new TRotMatrix("rot995","rot995",90,0,90,90,0,0);
+ //new TRotMatrix("rot995","rot995",90,0,90,90,0,0);
node = new TNode("RICH3","RICH3","S_RICH",pos3[0],pos3[1],pos3[2],"rot995");
-
-
node->SetLineColor(kColorRICH);
+ node->cd();
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
fNodes->Add(node);
+
top->cd();
- Float_t pos4[3]={-171,470,0};
+ //Float_t pos4[3]={-171,470,0};
//Chamber(3).SetChamberTransform(pos4[0],pos4[1],pos4[2],
- new TRotMatrix("rot996","rot996",90,20,90,110,0,0);
+ //new TRotMatrix("rot996","rot996",90,20,90,110,0,0);
node = new TNode("RICH4","RICH4","S_RICH",pos4[0],pos4[1],pos4[2],"rot996");
-
-
node->SetLineColor(kColorRICH);
+ node->cd();
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
fNodes->Add(node);
+
+
top->cd();
- Float_t pos5[3]={161.3999,443.3999,-165.3};
+ //Float_t pos5[3]={161.3999,443.3999,-165.3};
//Chamber(4).SetChamberTransform(pos5[0],pos5[1],pos5[2],
- new TRotMatrix("rot997","rot997",90,340,108.1999,70,18.2,70);
+ //new TRotMatrix("rot997","rot997",90,340,108.1999,70,18.2,70);
node = new TNode("RICH5","RICH5","S_RICH",pos5[0],pos5[1],pos5[2],"rot997");
-
node->SetLineColor(kColorRICH);
+ node->cd();
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
fNodes->Add(node);
+
+
top->cd();
- Float_t pos6[3]={0., 471.9, -165.3,};
+ //Float_t pos6[3]={0., 471.9, -165.3,};
//Chamber(5).SetChamberTransform(pos6[0],pos6[1],pos6[2],
- new TRotMatrix("rot998","rot998",90,0,109.3099,90,19.30999,90);
+ //new TRotMatrix("rot998","rot998",90,0,109.3099,90,19.30999,90);
node = new TNode("RICH6","RICH6","S_RICH",pos6[0],pos6[1],pos6[2],"rot998");
-
-
node->SetLineColor(kColorRICH);
- fNodes->Add(node);
+ fNodes->Add(node);node->cd();
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+
+
top->cd();
- Float_t pos7[3]={-161.399,443.3999,-165.3};
+ //Float_t pos7[3]={-161.399,443.3999,-165.3};
//Chamber(6).SetChamberTransform(pos7[0],pos7[1],pos7[2],
- new TRotMatrix("rot999","rot999",90,20,108.1999,110,18.2,110);
+ //new TRotMatrix("rot999","rot999",90,20,108.1999,110,18.2,110);
node = new TNode("RICH7","RICH7","S_RICH",pos7[0],pos7[1],pos7[2],"rot999");
node->SetLineColor(kColorRICH);
+ node->cd();
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,padplane_length/2 + segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",padplane_width + segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",0,5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
+ subnode = new TNode("PHOTO1","PHOTO1","PHOTO",-padplane_width - segmentation->DeadZone(),5,-padplane_length/2 - segmentation->DeadZone()/2,"");
+ subnode->SetLineColor(kGreen);
+ fNodes->Add(subnode);
fNodes->Add(node);
}
//End_Html
AliRICH *pRICH = (AliRICH *) gAlice->GetDetector("RICH");
- AliSegmentation* segmentation;
+ AliRICHSegmentationV0* segmentation;
AliRICHGeometry* geometry;
AliRICHChamber* iChamber;
iChamber = &(pRICH->Chamber(0));
- segmentation=iChamber->GetSegmentationModel(0);
+ segmentation=(AliRICHSegmentationV0*) iChamber->GetSegmentationModel();
geometry=iChamber->GetGeometryModel();
Float_t distance;
Float_t oqua_thickness = .5;
//CsI dimensions
- Float_t csi_length = 160*.8 + 2.6;
- Float_t csi_width = 144*.84 + 2*2.6;
-
- Int_t *idtmed = fIdtmed->GetArray()-999;
+ //Float_t csi_length = 160*.8 + 2.6;
+ //Float_t csi_width = 144*.84 + 2*2.6;
+
+ Float_t csi_width = segmentation->Npx()*segmentation->Dpx() + segmentation->DeadZone();
+ Float_t csi_length = segmentation->Npy()*segmentation->Dpy() + 2*segmentation->DeadZone();
+
+ //printf("\n\n\n\n\n In CreateGeometry() npx: %d, npy: %d, dpx: %f, dpy:%f deadzone: %f \n\n\n\n\n\n",segmentation->Npx(),segmentation->Npy(),segmentation->Dpx(),segmentation->Dpy(),segmentation->DeadZone());
+
+ Int_t *idtmed = fIdtmed->GetArray()-999;
Int_t i;
Float_t zs;
// --- Places the detectors defined with GSVOLU
// 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 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.5, 0., 0, "ONLY");
- gMC->Gspos("AIR2", 2, "RICH", -66.3 - 1.2505, 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.5, 0., 0, "ONLY");
- gMC->Gspos("AIR3", 1, "RICH", 0., 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.5, -68.35 - 1.25, 0, "ONLY");
- gMC->Gspos("AIR3", 2, "RICH", 0., 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.5, 68.35 + 1.25, 0, "ONLY");
+ gMC->Gspos("AIR2", 1, "RICH", 66.3 + 1.2505, 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.35, 0., 0, "ONLY");
+ gMC->Gspos("AIR2", 2, "RICH", -66.3 - 1.2505, 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.35, 0., 0, "ONLY");
+ gMC->Gspos("AIR3", 1, "RICH", 0., 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.35, -68.35 - 1.25, 0, "ONLY");
+ gMC->Gspos("AIR3", 2, "RICH", 0., 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.5 - 3.35, 68.35 + 1.25, 0, "ONLY");
gMC->Gspos("ALUM", 1, "SRIC", 0., 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()- .4 - .6 - .05 - .376 -.025, 0., 0, "ONLY");
AliMatrix(idrotm[1019], 0., 0., 90., 0., 90., 90.);
- //Int_t nspacers = (Int_t)(TMath::Abs(geometry->GetInnerFreonLength()/14.4));
- Int_t nspacers = 9;
+ //Placing of the spacers inside the freon slabs
+
+ Int_t nspacers = 30;
//printf("\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n Spacers:%d\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n",nspacers);
//printf("Nspacers: %d", nspacers);
- //for (i = 1; i <= 9; ++i) {
- //zs = (5 - i) * 14.4; //Original settings
- for (i = 0; i < nspacers; i++) {
- zs = (TMath::Abs(nspacers/2) - i) * 14.4;
- gMC->Gspos("SPAC", i, "FRE1", 6.7, 0., zs, idrotm[1019], "ONLY"); //Original settings
- //gMC->Gspos("SPAC", i, "FRE1", zs, 0., 6.7, idrotm[1019], "ONLY");
+ 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 = 10; i <= 18; ++i) {
- //zs = (14 - i) * 14.4; //Original settings
- for (i = nspacers; i < nspacers*2; ++i) {
- zs = (nspacers + TMath::Abs(nspacers/2) - i) * 14.4;
- gMC->Gspos("SPAC", i, "FRE1", -6.7, 0., zs, idrotm[1019], "ONLY"); //Original settings
- //gMC->Gspos("SPAC", i, "FRE1", zs, 0., -6.7, idrotm[1019], "ONLY");
+
+ 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 = 1; i <= 9; ++i) {
- //zs = (5 - i) * 14.4; //Original settings
- for (i = 0; i < nspacers; i++) {
- zs = (TMath::Abs(nspacers/2) - i) * 14.4;
- gMC->Gspos("SPAC", i, "FRE2", 6.7, 0., zs, idrotm[1019], "ONLY"); //Original settings
- //gMC->Gspos("SPAC", i, "FRE2", zs, 0., 6.7, idrotm[1019], "ONLY");
+ 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 = 10; i <= 18; ++i) {
- //zs = (5 - i) * 14.4; //Original settings
- for (i = nspacers; i < nspacers*2; ++i) {
- zs = (nspacers + TMath::Abs(nspacers/2) - i) * 14.4;
- gMC->Gspos("SPAC", i, "FRE2", -6.7, 0., zs, idrotm[1019], "ONLY"); //Original settings
- //gMC->Gspos("SPAC", i, "FRE2", zs, 0., -6.7, idrotm[1019], "ONLY");
+
+ 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
}
- /*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", 31.3, -4.724, 41.3, 0, "ONLY");
- gMC->Gspos("OQF2", 2, "SRIC", 0., -4.724, 0., 0, "ONLY");
- gMC->Gspos("OQF1", 3, "SRIC", -31.3, -4.724, -41.3, 0, "ONLY");
- gMC->Gspos("BARR", 1, "QUAR", -21.65, 0., 0., 0, "ONLY"); //Original settings
- gMC->Gspos("BARR", 2, "QUAR", 21.65, 0., 0., 0, "ONLY"); //Original settings
- gMC->Gspos("QUAR", 1, "SRIC", 0., -3.974, 0., 0, "ONLY");
- gMC->Gspos("GAP ", 1, "META", 0., 4.8, 0., 0, "ONLY");
- gMC->Gspos("META", 1, "SRIC", 0., 1.276, 0., 0, "ONLY");
- gMC->Gspos("CSI ", 1, "SRIC", 0., 6.526, 0., 0, "ONLY");*/
-
+ 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", geometry->GetOuterFreonWidth()/2 + geometry->GetInnerFreonWidth()/2 + 2, 1.276 - geometry->GetGapThickness()/2- geometry->GetQuartzThickness() -geometry->GetFreonThickness()/2, 0., 0, "ONLY"); //Original settings (31.3)
+// printf("Opaque quartz in SRIC %f\n", 1.276 - geometry->GetGapThickness()/2- geometry->GetQuartzThickness() -geometry->GetFreonThickness()/2);
gMC->Gspos("OQF2", 2, "SRIC", 0., 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()/2, 0., 0, "ONLY"); //Original settings
gMC->Gspos("OQF1", 3, "SRIC", - (geometry->GetOuterFreonWidth()/2 + geometry->GetInnerFreonWidth()/2) - 2, 1.276 - geometry->GetGapThickness()/2 - geometry->GetQuartzThickness() - geometry->GetFreonThickness()/2, 0., 0, "ONLY"); //Original settings (-31.3)
//gMC->Gspos("BARR", 1, "QUAR", - geometry->GetInnerFreonWidth()/2 - oqua_thickness, 0., 0., 0, "ONLY"); //Original settings (-21.65)
gMC->Gspos("GAP ", 1, "META", 0., geometry->GetGapThickness()/2 - geometry->GetProximityGapThickness()/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 + geometry->GetGapThickness()/2 + .25, 0., 0, "ONLY");
+ printf("CSI pos: %f\n",1.276 + geometry->GetGapThickness()/2 + .25);
// Wire support placing
// PCB placing
- gMC->Gspos("PCB ", 1, "SRIC ", 0., 1.276 + geometry->GetGapThickness()/2 + .5 + 1.05, csi_width/4 + .5025 + 1.2, 0, "ONLY");
- gMC->Gspos("PCB ", 2, "SRIC ", 0., 1.276 + geometry->GetGapThickness()/2 + .5 + 1.05, -csi_width/4 - .5025 - 1.2, 0, "ONLY");
+ gMC->Gspos("PCB ", 1, "SRIC ", 0., 1.276 + geometry->GetGapThickness()/2 + .5 + 1.05, csi_width/4 + .5025 + 2.5, 0, "ONLY");
+ gMC->Gspos("PCB ", 2, "SRIC ", 0., 1.276 + geometry->GetGapThickness()/2 + .5 + 1.05, -csi_width/4 - .5025 - 2.5, 0, "ONLY");
//printf("Position of the gap: %f to %f\n", 1.276 + geometry->GetGapThickness()/2 - geometry->GetProximityGapThickness()/2 - .2, 1.276 + geometry->GetGapThickness()/2 - geometry->GetProximityGapThickness()/2 + .2);
// Place RICH inside ALICE apparatus
-
- AliMatrix(idrotm[1000], 90., 0., 70.69, 90., 19.31, -90.);
- AliMatrix(idrotm[1001], 90., -20., 90., 70., 0., 0.);
- AliMatrix(idrotm[1002], 90., 0., 90., 90., 0., 0.);
- AliMatrix(idrotm[1003], 90., 20., 90., 110., 0., 0.);
- AliMatrix(idrotm[1004], 90., 340., 108.2, 70., 18.2, 70.);
- AliMatrix(idrotm[1005], 90., 0., 109.31, 90., 19.31, 90.);
- AliMatrix(idrotm[1006], 90., 20., 108.2, 110., 18.2, 110.);
-
- gMC->Gspos("RICH", 1, "ALIC", 0., 471.9, 165.26, idrotm[1000], "ONLY");
- gMC->Gspos("RICH", 2, "ALIC", 171., 470., 0., idrotm[1001], "ONLY");
- gMC->Gspos("RICH", 3, "ALIC", 0., 500., 0., idrotm[1002], "ONLY");
- gMC->Gspos("RICH", 4, "ALIC", -171., 470., 0., idrotm[1003], "ONLY");
- gMC->Gspos("RICH", 5, "ALIC", 161.4, 443.4, -165.3, idrotm[1004], "ONLY");
- gMC->Gspos("RICH", 6, "ALIC", 0., 471.9, -165.3, idrotm[1005], "ONLY");
- gMC->Gspos("RICH", 7, "ALIC", -161.4, 443.4, -165.3, idrotm[1006], "ONLY");
+
+ /* old values
+
+ AliMatrix(idrotm[1000], 90., 0., 70.69, 90., 19.31, -90.);
+ AliMatrix(idrotm[1001], 90., -20., 90., 70., 0., 0.);
+ AliMatrix(idrotm[1002], 90., 0., 90., 90., 0., 0.);
+ AliMatrix(idrotm[1003], 90., 20., 90., 110., 0., 0.);
+ AliMatrix(idrotm[1004], 90., 340., 108.2, 70., 18.2, 70.);
+ AliMatrix(idrotm[1005], 90., 0., 109.31, 90., 19.31, 90.);
+ AliMatrix(idrotm[1006], 90., 20., 108.2, 110., 18.2, 110.);
+
+ gMC->Gspos("RICH", 1, "ALIC", 0., 471.9, 165.26, idrotm[1000], "ONLY");
+ gMC->Gspos("RICH", 2, "ALIC", 171., 470., 0., idrotm[1001], "ONLY");
+ gMC->Gspos("RICH", 3, "ALIC", 0., 500., 0., idrotm[1002], "ONLY");
+ gMC->Gspos("RICH", 4, "ALIC", -171., 470., 0., idrotm[1003], "ONLY");
+ gMC->Gspos("RICH", 5, "ALIC", 161.4, 443.4, -165.3, idrotm[1004], "ONLY");
+ gMC->Gspos("RICH", 6, "ALIC", 0., 471.9, -165.3, idrotm[1005], "ONLY");
+ gMC->Gspos("RICH", 7, "ALIC", -161.4, 443.4, -165.3, idrotm[1006], "ONLY");*/
+
+ // The placing of the chambers is measured from the vertex to the base of the methane vessel (490 cm)
+
+ Float_t offset = 490 + 1.276 - geometry->GetGapThickness()/2; //distance from center of mother volume to methane
+ Float_t deltaphi = 19.5; //phi angle between center of chambers - z direction
+ Float_t deltatheta = 20; //theta angle between center of chambers - x direction
+ Float_t cosphi = TMath::Cos(deltaphi*TMath::Pi()/180);
+ Float_t sinphi = TMath::Sin(deltaphi*TMath::Pi()/180);
+ Float_t costheta = TMath::Cos(deltatheta*TMath::Pi()/180);
+ Float_t sintheta = TMath::Sin(deltatheta*TMath::Pi()/180);
+
+ //printf("\n\n%f %f %f %f %f %f %f\n\n",offset,deltatheta,deltaphi,cosphi,costheta,sinphi,sintheta);
+
+ AliMatrix(idrotm[1000], 90., 0. , 90. - deltaphi, 90. , deltaphi, -90. );
+ AliMatrix(idrotm[1001], 90., -deltatheta , 90. , 90.- deltatheta , 0. , 0. );
+ AliMatrix(idrotm[1002], 90., 0. , 90. , 90. , 0. , 0. );
+ AliMatrix(idrotm[1003], 90., deltatheta , 90. , 90 + deltatheta , 0. , 0. );
+ AliMatrix(idrotm[1004], 90., 360. - deltatheta, 108.2 , 90.- deltatheta ,18.2 , 90 - deltatheta);
+ AliMatrix(idrotm[1005], 90., 0. , 90 + deltaphi , 90. , deltaphi, 90. );
+ AliMatrix(idrotm[1006], 90., deltatheta , 108.2 , 90.+ deltatheta ,18.2 , 90 + deltatheta);
+
+ gMC->Gspos("RICH", 1, "ALIC", 0. , offset*cosphi , offset*sinphi ,idrotm[1000], "ONLY");
+ gMC->Gspos("RICH", 2, "ALIC", (offset)*sintheta , offset*costheta , 0. ,idrotm[1001], "ONLY");
+ gMC->Gspos("RICH", 3, "ALIC", 0. , offset , 0. ,idrotm[1002], "ONLY");
+ gMC->Gspos("RICH", 4, "ALIC", -(offset)*sintheta, offset*costheta , 0. ,idrotm[1003], "ONLY");
+ gMC->Gspos("RICH", 5, "ALIC", (offset)*sinphi , offset*costheta*cosphi, -offset*sinphi,idrotm[1004], "ONLY");
+ gMC->Gspos("RICH", 6, "ALIC", 0. , offset*cosphi , -offset*sinphi,idrotm[1005], "ONLY");
+ gMC->Gspos("RICH", 7, "ALIC", -(offset)*sinphi , offset*costheta*cosphi, -offset*sinphi,idrotm[1006], "ONLY");
}
Int_t *idtmed = fIdtmed->GetArray()-999;
- TGeant3 *geant3 = (TGeant3*) gMC;
-
// --- Photon energy (GeV)
// --- Refraction indexes
for (i = 0; i < 26; ++i) {
AliMedium(12, "PCB_COPPER", 31, 0, isxfld, sxmgmx, tmaxfd, stemax, deemax, epsil, stmin);
- geant3->Gsckov(idtmed[1000], 26, ppckov, abscoMethane, efficAll, rIndexMethane);
- geant3->Gsckov(idtmed[1001], 26, ppckov, abscoMethane, efficAll, rIndexMethane);
- geant3->Gsckov(idtmed[1002], 26, ppckov, abscoQuarz, efficAll,rIndexQuarz);
- geant3->Gsckov(idtmed[1003], 26, ppckov, abscoFreon, efficAll,rIndexFreon);
- geant3->Gsckov(idtmed[1004], 26, ppckov, abscoMethane, efficAll, rIndexMethane);
- geant3->Gsckov(idtmed[1005], 26, ppckov, abscoCsI, efficCsI, rIndexMethane);
- geant3->Gsckov(idtmed[1006], 26, ppckov, abscoGrid, efficGrid, rIndexGrid);
- geant3->Gsckov(idtmed[1007], 26, ppckov, abscoOpaqueQuarz, efficAll, rIndexOpaqueQuarz);
- geant3->Gsckov(idtmed[1008], 26, ppckov, abscoMethane, efficAll, rIndexMethane);
- geant3->Gsckov(idtmed[1009], 26, ppckov, abscoGrid, efficGrid, rIndexGrid);
- geant3->Gsckov(idtmed[1010], 26, ppckov, abscoOpaqueQuarz, efficAll, rIndexOpaqueQuarz);
+ gMC->SetCerenkov(idtmed[1000], 26, ppckov, abscoMethane, efficAll, rIndexMethane);
+ gMC->SetCerenkov(idtmed[1001], 26, ppckov, abscoMethane, efficAll, rIndexMethane);
+ gMC->SetCerenkov(idtmed[1002], 26, ppckov, abscoQuarz, efficAll,rIndexQuarz);
+ gMC->SetCerenkov(idtmed[1003], 26, ppckov, abscoFreon, efficAll,rIndexFreon);
+ gMC->SetCerenkov(idtmed[1004], 26, ppckov, abscoMethane, efficAll, rIndexMethane);
+ gMC->SetCerenkov(idtmed[1005], 26, ppckov, abscoCsI, efficCsI, rIndexMethane);
+ gMC->SetCerenkov(idtmed[1006], 26, ppckov, abscoGrid, efficGrid, rIndexGrid);
+ gMC->SetCerenkov(idtmed[1007], 26, ppckov, abscoOpaqueQuarz, efficAll, rIndexOpaqueQuarz);
+ gMC->SetCerenkov(idtmed[1008], 26, ppckov, abscoMethane, efficAll, rIndexMethane);
+ gMC->SetCerenkov(idtmed[1009], 26, ppckov, abscoGrid, efficGrid, rIndexGrid);
+ gMC->SetCerenkov(idtmed[1010], 26, ppckov, abscoOpaqueQuarz, efficAll, rIndexOpaqueQuarz);
}
//___________________________________________
}
//___________________________________________
-void AliRICH::MakeBranch(Option_t* option)
+void AliRICH::MakeBranch(Option_t* option, const char *file)
{
// Create Tree branches for the RICH.
const Int_t kBufferSize = 4000;
char branchname[20];
-
-
- AliDetector::MakeBranch(option);
- sprintf(branchname,"%sCerenkov",GetName());
- if (fCerenkovs && gAlice->TreeH()) {
- gAlice->TreeH()->Branch(branchname,&fCerenkovs, kBufferSize);
- printf("Making Branch %s for Cerenkov Hits\n",branchname);
- }
-
- sprintf(branchname,"%sPadHits",GetName());
- if (fPadHits && gAlice->TreeH()) {
- gAlice->TreeH()->Branch(branchname,&fPadHits, kBufferSize);
- printf("Making Branch %s for PadHits\n",branchname);
+
+ AliDetector::MakeBranch(option,file);
+
+ 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) {
+ sprintf(branchname,"%sCerenkov",GetName());
+ if (fCerenkovs && gAlice->TreeH()) {
+ //TBranch* branch = MakeBranchInTree(gAlice->TreeH(),branchname, &fCerenkovs, kBufferSize, file) ;
+ MakeBranchInTree(gAlice->TreeH(),branchname, &fCerenkovs, kBufferSize, file) ;
+ //branch->SetAutoDelete(kFALSE);
+ }
+ sprintf(branchname,"%sSDigits",GetName());
+ if (fSDigits && gAlice->TreeH()) {
+ //TBranch* branch = MakeBranchInTree(gAlice->TreeH(),branchname, &fSDigits, kBufferSize, file) ;
+ MakeBranchInTree(gAlice->TreeH(),branchname, &fSDigits, kBufferSize, file) ;
+ //branch->SetAutoDelete(kFALSE);
+ //printf("Making branch %sSDigits in TreeH\n",GetName());
+ }
+ }
+
+ if (cS) {
+ sprintf(branchname,"%sSDigits",GetName());
+ if (fSDigits && gAlice->TreeS()) {
+ //TBranch* branch = MakeBranchInTree(gAlice->TreeS(),branchname, &fSDigits, kBufferSize, file) ;
+ MakeBranchInTree(gAlice->TreeS(),branchname, &fSDigits, kBufferSize, file) ;
+ //branch->SetAutoDelete(kFALSE);
+ //printf("Making branch %sSDigits in TreeS\n",GetName());
+ }
}
-// one branch for digits per chamber
- Int_t i;
+ if (cD) {
+ //
+ // one branch for digits per chamber
+ //
+ Int_t i;
- for (i=0; i<kNCH ;i++) {
- sprintf(branchname,"%sDigits%d",GetName(),i+1);
-
+ for (i=0; i<kNCH ;i++) {
+ sprintf(branchname,"%sDigits%d",GetName(),i+1);
if (fDchambers && gAlice->TreeD()) {
- gAlice->TreeD()->Branch(branchname,&((*fDchambers)[i]), kBufferSize);
- printf("Making Branch %s for digits in chamber %d\n",branchname,i+1);
+ //TBranch* branch = MakeBranchInTree(gAlice->TreeD(),branchname, &((*fDchambers)[i]), kBufferSize, file) ;
+ MakeBranchInTree(gAlice->TreeD(),branchname, &((*fDchambers)[i]), kBufferSize, file) ;
+ //branch->SetAutoDelete(kFALSE);
+ //printf("Making Branch %sDigits%d\n",GetName(),i+1);
}
+ }
}
-// one branch for raw clusters per chamber
- for (i=0; i<kNCH ;i++) {
- sprintf(branchname,"%sRawClusters%d",GetName(),i+1);
-
- if (fRawClusters && gAlice->TreeR()) {
- gAlice->TreeR()->Branch(branchname,&((*fRawClusters)[i]), kBufferSize);
- printf("Making Branch %s for raw clusters in chamber %d\n",branchname,i+1);
- }
- }
+ if (cR) {
+ //
+ // one branch for raw clusters per chamber
+ //
- // one branch for rec hits per chamber
- for (i=0; i<kNCH ;i++) {
- sprintf(branchname,"%sRecHits1D%d",GetName(),i+1);
-
- if (fRecHits1D && gAlice->TreeR()) {
- gAlice->TreeR()->Branch(branchname,&((*fRecHits1D)[i]), kBufferSize);
- printf("Making Branch %s for 1D rec. hits in chamber %d\n",branchname,i+1);
- }
- }
- for (i=0; i<kNCH ;i++) {
- sprintf(branchname,"%sRecHits3D%d",GetName(),i+1);
-
- if (fRecHits3D && gAlice->TreeR()) {
- gAlice->TreeR()->Branch(branchname,&((*fRecHits3D)[i]), kBufferSize);
- printf("Making Branch %s for 3D rec. hits in chamber %d\n",branchname,i+1);
- }
- }
-
+ //printf("Called MakeBranch for TreeR\n");
+
+ Int_t i;
+
+ for (i=0; i<kNCH ;i++) {
+ sprintf(branchname,"%sRawClusters%d",GetName(),i+1);
+ if (fRawClusters && gAlice->TreeR()) {
+ //TBranch* branch = MakeBranchInTree(gAlice->TreeR(),branchname, &((*fRawClusters)[i]), kBufferSize, file) ;
+ MakeBranchInTree(gAlice->TreeR(),branchname, &((*fRawClusters)[i]), kBufferSize, file) ;
+ //branch->SetAutoDelete(kFALSE);
+ }
+ }
+ //
+ // one branch for rec hits per chamber
+ //
+ for (i=0; i<kNCH ;i++) {
+ sprintf(branchname,"%sRecHits1D%d",GetName(),i+1);
+ if (fRecHits1D && gAlice->TreeR()) {
+ //TBranch* branch = MakeBranchInTree(gAlice->TreeR(),branchname, &((*fRecHits1D)[i]), kBufferSize, file) ;
+ MakeBranchInTree(gAlice->TreeR(),branchname, &((*fRecHits1D)[i]), kBufferSize, file) ;
+ //branch->SetAutoDelete(kFALSE);
+ }
+ }
+ for (i=0; i<kNCH ;i++) {
+ sprintf(branchname,"%sRecHits3D%d",GetName(),i+1);
+ if (fRecHits3D && gAlice->TreeR()) {
+ MakeBranchInTree(gAlice->TreeR(),branchname, &((*fRecHits3D)[i]), kBufferSize, file) ;
+ //branch->SetAutoDelete(kFALSE);
+ }
+ }
+ }
}
//___________________________________________
TTree *treeH = gAlice->TreeH();
TTree *treeD = gAlice->TreeD();
TTree *treeR = gAlice->TreeR();
+ TTree *treeS = gAlice->TreeS();
if (treeH) {
- if (fPadHits) {
- branch = treeH->GetBranch("RICHPadHits");
- if (branch) branch->SetAddress(&fPadHits);
- }
- if (fCerenkovs) {
+ if (fCerenkovs) {
branch = treeH->GetBranch("RICHCerenkov");
if (branch) branch->SetAddress(&fCerenkovs);
}
+ if (fSDigits) {
+ branch = treeH->GetBranch("RICHSDigits");
+ if (branch)
+ {
+ branch->SetAddress(&fSDigits);
+ //printf("Setting sdigits branch address at %p in TreeH\n",&fSDigits);
+ }
+ }
+ }
+
+ if (treeS) {
+ if (fSDigits) {
+ branch = treeS->GetBranch("RICHSDigits");
+ if (branch)
+ {
+ branch->SetAddress(&fSDigits);
+ //printf("Setting sdigits branch address at %p in TreeS\n",&fSDigits);
+ }
+ }
}
+
if (treeD) {
for (int i=0; i<kNCH; i++) {
sprintf(branchname,"%sDigits%d",GetName(),i+1);
if (fDchambers) {
- branch = treeD->GetBranch(branchname);
- if (branch) branch->SetAddress(&((*fDchambers)[i]));
+ branch = treeD->GetBranch(branchname);
+ if (branch) branch->SetAddress(&((*fDchambers)[i]));
}
}
}
{
// Reset number of clusters and the cluster array for this detector
AliDetector::ResetHits();
- fNPadHits = 0;
+ fNSDigits = 0;
fNcerenkovs = 0;
- if (fPadHits) fPadHits->Clear();
+ if (fSDigits) fSDigits->Clear();
if (fCerenkovs) fCerenkovs->Clear();
}
// Reset number of digits and the digits array for this detector
//
for ( int i=0;i<kNCH;i++ ) {
- if ((*fDchambers)[i]) (*fDchambers)[i]->Clear();
+ //PH if (fDchambers && (*fDchambers)[i]) (*fDchambers)[i]->Clear();
+ if (fDchambers && fDchambers->At(i)) fDchambers->At(i)->Clear();
if (fNdch) fNdch[i]=0;
}
}
// Reset number of raw clusters and the raw clust array for this detector
//
for ( int i=0;i<kNCH;i++ ) {
- if ((*fRawClusters)[i]) ((TClonesArray*)(*fRawClusters)[i])->Clear();
+ //PH if ((*fRawClusters)[i]) ((TClonesArray*)(*fRawClusters)[i])->Clear();
+ if (fRawClusters->At(i)) ((TClonesArray*)fRawClusters->At(i))->Clear();
if (fNrawch) fNrawch[i]=0;
}
}
//
for ( int i=0;i<kNCH;i++ ) {
- if ((*fRecHits1D)[i]) ((TClonesArray*)(*fRecHits1D)[i])->Clear();
+ //PH if ((*fRecHits1D)[i]) ((TClonesArray*)(*fRecHits1D)[i])->Clear();
+ if (fRecHits1D->At(i)) ((TClonesArray*)fRecHits1D->At(i))->Clear();
if (fNrechits1D) fNrechits1D[i]=0;
}
}
//
for ( int i=0;i<kNCH;i++ ) {
- if ((*fRecHits3D)[i]) ((TClonesArray*)(*fRecHits3D)[i])->Clear();
+ //PH if ((*fRecHits3D)[i]) ((TClonesArray*)(*fRecHits3D)[i])->Clear();
+ if (fRecHits3D->At(i)) ((TClonesArray*)fRecHits3D->At(i))->Clear();
if (fNrechits3D) fNrechits3D[i]=0;
}
}
-//___________________________________________
-void AliRICH::SetGeometryModel(Int_t id, AliRICHGeometry *geometry)
-{
-
-//
-// Setter for the RICH geometry model
-//
-
-
- ((AliRICHChamber*) (*fChambers)[id])->GeometryModel(geometry);
-}
-
-//___________________________________________
-void AliRICH::SetSegmentationModel(Int_t id, AliSegmentation *segmentation)
-{
-
-//
-// Setter for the RICH segmentation model
-//
-
- ((AliRICHChamber*) (*fChambers)[id])->SetSegmentationModel(segmentation);
-}
//___________________________________________
-void AliRICH::SetResponseModel(Int_t id, AliRICHResponse *response)
-{
-
-//
-// Setter for the RICH response model
-//
-
- ((AliRICHChamber*) (*fChambers)[id])->ResponseModel(response);
-}
-
-void AliRICH::SetReconstructionModel(Int_t id, AliRICHClusterFinder *reconst)
+void AliRICH::StepManager()
{
-
-//
-// Setter for the RICH reconstruction model (clusters)
-//
-
- ((AliRICHChamber*) (*fChambers)[id])->SetReconstructionModel(reconst);
-}
-
-void AliRICH::SetNsec(Int_t id, Int_t nsec)
-{
-
-//
-// Sets the number of padplanes
-//
-
- ((AliRICHChamber*) (*fChambers)[id])->SetNsec(nsec);
-}
-
-
-//___________________________________________
-void AliRICH::StepManager()
-{
-
-// Full Step Manager
+// Full Step Manager
Int_t copy, id;
static Int_t idvol;
static Int_t vol[2];
Int_t ipart;
- static Float_t hits[18];
+ static Float_t hits[22];
static Float_t ckovData[19];
TLorentzVector position;
TLorentzVector momentum;
const Float_t kBig=1.e10;
TClonesArray &lhits = *fHits;
- TGeant3 *geant3 = (TGeant3*) gMC;
TParticle *current = (TParticle*)(*gAlice->Particles())[gAlice->CurrentTrack()];
//if (current->Energy()>1)
//printf("Track entered (1)\n");
if (gMC->VolId("FRE1")==gMC->CurrentVolID(copy) || gMC->VolId("FRE2")==gMC->CurrentVolID(copy))
{ //is it in freo?
- if (geant3->Gctrak()->nstep<1){ //is it the first step?
+ if (gMC->IsNewTrack()){ //is it the first step?
//printf("I'm in!\n");
Int_t mother = current->GetFirstMother();
} //first step question
} //freo question
- if (geant3->Gctrak()->nstep<1){ //is it first step?
+ if (gMC->IsNewTrack()){ //is it first step?
if (gMC->VolId("QUAR")==gMC->CurrentVolID(copy)) //is it in quarz?
{
ckovData[12] = 2;
gMC->Rndm(ranf, 1);
//printf("grid calculation:%f\n",t);
if (ranf[0] > t) {
- geant3->StopTrack();
+ gMC->StopTrack();
ckovData[13] = 5;
AddCerenkov(gAlice->CurrentTrack(),vol,ckovData);
//printf("Added One (1)!\n");
Float_t t = Fresnel(ckovEnergy*1e9,cophi,1);
gMC->Rndm(ranf, 1);
if (ranf[0] < t) {
- geant3->StopTrack();
+ gMC->StopTrack();
ckovData[13] = 6;
AddCerenkov(gAlice->CurrentTrack(),vol,ckovData);
//printf("Added One (2)!\n");
/********************Evaluation of losses************************/
/******************still in the old fashion**********************/
- Int_t i1 = geant3->Gctrak()->nmec; //number of physics mechanisms acting on the particle
+ TArrayI procs;
+ Int_t i1 = gMC->StepProcesses(procs); //number of physics mechanisms acting on the particle
for (Int_t i = 0; i < i1; ++i) {
// Reflection loss
- if (geant3->Gctrak()->lmec[i] == 106) { //was it reflected
+ if (procs[i] == kPLightReflection) { //was it reflected
ckovData[13]=10;
if (gMC->VolId("FRE1")==gMC->CurrentVolID(copy) || gMC->VolId("FRE2")==gMC->CurrentVolID(copy))
ckovData[13]=1;
if (gMC->CurrentVolID(copy) == gMC->VolId("QUAR"))
ckovData[13]=2;
- //geant3->StopTrack();
+ //gMC->StopTrack();
//AddCerenkov(gAlice->CurrentTrack(),vol,ckovData);
} //reflection question
// Absorption loss
- else if (geant3->Gctrak()->lmec[i] == 101) { //was it absorbed?
+ else if (procs[i] == kPLightAbsorption) { //was it absorbed?
//printf("Got in absorption\n");
ckovData[13]=20;
if (gMC->VolId("FRE1")==gMC->CurrentVolID(copy) || gMC->VolId("FRE2")==gMC->CurrentVolID(copy))
if (gMC->CurrentVolID(copy) == gMC->VolId("CSI ")) {
ckovData[13]=16;
}
- geant3->StopTrack();
+ gMC->StopTrack();
AddCerenkov(gAlice->CurrentTrack(),vol,ckovData);
//printf("Added One (3)!\n");
//printf("Added cerenkov %d\n",fCkovNumber);
// Photon goes out of tracking scope
- else if (geant3->Gctrak()->lmec[i] == 30) { //is it below energy treshold?
+ else if (procs[i] == kPStop) { //is it below energy treshold?
ckovData[13]=21;
- geant3->StopTrack();
+ gMC->StopTrack();
AddCerenkov(gAlice->CurrentTrack(),vol,ckovData);
//printf("Added One (4)!\n");
} // energy treshold question
if (gMC->TrackPid() == 50000050 || gMC->TrackPid() == 50000051) {
//printf("Cerenkov\n");
- if (gMC->VolId("CSI ")==gMC->CurrentVolID(copy))
+
+ //if (gMC->TrackPid() == 50000051)
+ //printf("Tracking a feedback\n");
+
+ if (gMC->VolId("CSI ")==gMC->CurrentVolID(copy))
{
//printf("Current volume (should be CSI) (2): %s\n",gMC->CurrentVolName());
//printf("VolId: %d, CurrentVolID: %d\n",gMC->VolId("CSI "),gMC->CurrentVolID(copy));
//printf("Got in CSI\n");
+ //printf("Tracking a %d\n",gMC->TrackPid());
if (gMC->Edep() > 0.){
gMC->TrackPosition(position);
gMC->TrackMomentum(momentum);
printf("Feedbacks:%d\n",fFeedbacks);
}*/
- ((AliRICHChamber*) (*fChambers)[idvol])
+ //PH ((AliRICHChamber*) (*fChambers)[idvol])
+ ((AliRICHChamber*)fChambers->At(idvol))
->SigGenInit(localPos[0], localPos[2], localPos[1]);
if(idvol<kNCH) {
ckovData[0] = gMC->TrackPid(); // particle type
ckovData[3] = pos[2]; // Z-position for hit
ckovData[4] = theta; // theta angle of incidence
ckovData[5] = phi; // phi angle of incidence
- ckovData[8] = (Float_t) fNPadHits; // first padhit
+ ckovData[8] = (Float_t) fNSDigits; // first sdigit
ckovData[9] = -1; // last pad hit
ckovData[13] = 4; // photon was detected
ckovData[14] = mom[0];
cherenkovLoss += destep;
ckovData[7]=cherenkovLoss;
- nPads = MakePadHits(localPos[0],localPos[2],cherenkovLoss,idvol,kCerenkov);
- if (fNPadHits > (Int_t)ckovData[8]) {
+ nPads = Hits2SDigits(localPos[0],localPos[2],cherenkovLoss,idvol,kCerenkov);
+
+ if (fNSDigits > (Int_t)ckovData[8]) {
ckovData[8]= ckovData[8]+1;
- ckovData[9]= (Float_t) fNPadHits;
+ ckovData[9]= (Float_t) fNSDigits;
}
+ //printf("Cerenkov loss: %f\n", cherenkovLoss);
+
ckovData[17] = nPads;
//printf("nPads:%d",nPads);
mom[0] = current->Px();
mom[1] = current->Py();
mom[2] = current->Pz();
- Float_t mipPx = mipHit->fMomX;
- Float_t mipPy = mipHit->fMomY;
- Float_t mipPz = mipHit->fMomZ;
+ Float_t mipPx = mipHit->MomX();
+ Float_t mipPy = mipHit->MomY();
+ Float_t mipPz = mipHit->MomZ();
Float_t r = mom[0]*mom[0] + mom[1]*mom[1] + mom[2]*mom[2];
Float_t rt = TMath::Sqrt(r);
}*/
if (gMC->VolId("FRE1")==gMC->CurrentVolID(copy) || gMC->VolId("FRE2")==gMC->CurrentVolID(copy))
{
+ gMC->TrackMomentum(momentum);
+ mom[0]=momentum(0);
+ mom[1]=momentum(1);
+ mom[2]=momentum(2);
+ mom[3]=momentum(3);
+ hits [19] = mom[0];
+ hits [20] = mom[1];
+ hits [21] = mom[2];
fFreonProd=1;
}
hits[3] = localPos[2]; // Z-position for hit
hits[4] = localTheta; // theta angle of incidence
hits[5] = localPhi; // phi angle of incidence
- hits[8] = (Float_t) fNPadHits; // first padhit
+ hits[8] = (Float_t) fNSDigits; // first sdigit
hits[9] = -1; // last pad hit
hits[13] = fFreonProd; // did id hit the freon?
hits[14] = mom[0];
hits[15] = mom[1];
hits[16] = mom[2];
+ hits[18] = 0; // dummy cerenkov angle
tlength = 0;
eloss = 0;
if(idvol<kNCH) {
//
// Initialize hit position (cursor) in the segmentation model
- ((AliRICHChamber*) (*fChambers)[idvol])
+ //PH ((AliRICHChamber*) (*fChambers)[idvol])
+ ((AliRICHChamber*)fChambers->At(idvol))
->SigGenInit(localPos[0], localPos[2], localPos[1]);
}
}
{
if(gMC->TrackPid() == kNeutron)
printf("\n\n\n\n\n Neutron Making Pad Hit!!! \n\n\n\n");
- nPads = MakePadHits(xhit,yhit,eloss,idvol,kMip);
+ nPads = Hits2SDigits(xhit,yhit,eloss,idvol,kMip);
hits[17] = nPads;
//printf("nPads:%d",nPads);
}
hits[6]=tlength;
hits[7]=eloss;
- if (fNPadHits > (Int_t)hits[8]) {
+ if (fNSDigits > (Int_t)hits[8]) {
hits[8]= hits[8]+1;
- hits[9]= (Float_t) fNPadHits;
+ hits[9]= (Float_t) fNSDigits;
}
//if(sector !=-1)
// defined by the segmentation
// model (boundary crossing conditions)
} else if
- (((AliRICHChamber*) (*fChambers)[idvol])
+ //PH (((AliRICHChamber*) (*fChambers)[idvol])
+ (((AliRICHChamber*)fChambers->At(idvol))
->SigGenCond(localPos[0], localPos[2], localPos[1]))
{
- ((AliRICHChamber*) (*fChambers)[idvol])
+ //PH ((AliRICHChamber*) (*fChambers)[idvol])
+ ((AliRICHChamber*)fChambers->At(idvol))
->SigGenInit(localPos[0], localPos[2], localPos[1]);
if (eloss > 0)
{
if(gMC->TrackPid() == kNeutron)
printf("\n\n\n\n\n Neutron Making Pad Hit!!! \n\n\n\n");
- nPads = MakePadHits(xhit,yhit,eloss,idvol,kMip);
+ nPads = Hits2SDigits(xhit,yhit,eloss,idvol,kMip);
hits[17] = nPads;
//printf("Npads:%d",NPads);
}
}
/*************************************************End of MIP treatment**************************************/
//}
-}
+}//void AliRICH::StepManager()
void AliRICH::FindClusters(Int_t nev,Int_t lastEntry)
{
//
for (Int_t icat=1;icat<2;icat++) {
gAlice->ResetDigits();
- gAlice->TreeD()->GetEvent(1); // spurious +1 ...
+ gAlice->TreeD()->GetEvent(0);
for (Int_t ich=0;ich<kNCH;ich++) {
- AliRICHChamber* iChamber=(AliRICHChamber*) (*fChambers)[ich];
+ //PH AliRICHChamber* iChamber=(AliRICHChamber*) (*fChambers)[ich];
+ AliRICHChamber* iChamber=(AliRICHChamber*)fChambers->At(ich);
TClonesArray *pRICHdigits = this->DigitsAddress(ich);
if (pRICHdigits == 0)
continue;
//gObjectTable->Print();
}
-
-//______________________________________________________________________________
-void AliRICH::Streamer(TBuffer &R__b)
-{
- // Stream an object of class AliRICH.
- AliRICHChamber *iChamber;
- AliSegmentation *segmentation;
- AliRICHResponse *response;
- TClonesArray *digitsaddress;
- TClonesArray *rawcladdress;
- TClonesArray *rechitaddress1D;
- TClonesArray *rechitaddress3D;
-
- if (R__b.IsReading()) {
- Version_t R__v = R__b.ReadVersion(); if (R__v) { }
- AliDetector::Streamer(R__b);
- R__b >> fNPadHits;
- R__b >> fPadHits; // diff
- R__b >> fNcerenkovs;
- R__b >> fCerenkovs; // diff
- R__b >> fDchambers;
- R__b >> fRawClusters;
- R__b >> fRecHits1D; //diff
- R__b >> fRecHits3D; //diff
- R__b >> fDebugLevel; //diff
- R__b.ReadStaticArray(fNdch);
- R__b.ReadStaticArray(fNrawch);
- R__b.ReadStaticArray(fNrechits1D);
- R__b.ReadStaticArray(fNrechits3D);
-//
- R__b >> fChambers;
-// Stream chamber related information
- for (Int_t i =0; i<kNCH; i++) {
- iChamber=(AliRICHChamber*) (*fChambers)[i];
- iChamber->Streamer(R__b);
- segmentation=iChamber->GetSegmentationModel();
- segmentation->Streamer(R__b);
- response=iChamber->GetResponseModel();
- response->Streamer(R__b);
- rawcladdress=(TClonesArray*) (*fRawClusters)[i];
- rawcladdress->Streamer(R__b);
- rechitaddress1D=(TClonesArray*) (*fRecHits1D)[i];
- rechitaddress1D->Streamer(R__b);
- rechitaddress3D=(TClonesArray*) (*fRecHits3D)[i];
- rechitaddress3D->Streamer(R__b);
- digitsaddress=(TClonesArray*) (*fDchambers)[i];
- digitsaddress->Streamer(R__b);
- }
- R__b >> fDebugLevel;
- R__b >> fCkovNumber;
- R__b >> fCkovQuarz;
- R__b >> fCkovGap;
- R__b >> fCkovCsi;
- R__b >> fLostRfreo;
- R__b >> fLostRquar;
- R__b >> fLostAfreo;
- R__b >> fLostAquarz;
- R__b >> fLostAmeta;
- R__b >> fLostCsi;
- R__b >> fLostWires;
- R__b >> fFreonProd;
- R__b >> fMipx;
- R__b >> fMipy;
- R__b >> fFeedbacks;
- R__b >> fLostFresnel;
-
- } else {
- R__b.WriteVersion(AliRICH::IsA());
- AliDetector::Streamer(R__b);
- R__b << fNPadHits;
- R__b << fPadHits; // diff
- R__b << fNcerenkovs;
- R__b << fCerenkovs; // diff
- R__b << fDchambers;
- R__b << fRawClusters;
- R__b << fRecHits1D; //diff
- R__b << fRecHits3D; //diff
- R__b << fDebugLevel; //diff
- R__b.WriteArray(fNdch, kNCH);
- R__b.WriteArray(fNrawch, kNCH);
- R__b.WriteArray(fNrechits1D, kNCH);
- R__b.WriteArray(fNrechits3D, kNCH);
-//
- R__b << fChambers;
-// Stream chamber related information
- for (Int_t i =0; i<kNCH; i++) {
- iChamber=(AliRICHChamber*) (*fChambers)[i];
- iChamber->Streamer(R__b);
- segmentation=iChamber->GetSegmentationModel();
- segmentation->Streamer(R__b);
- response=iChamber->GetResponseModel();
- response->Streamer(R__b);
- rawcladdress=(TClonesArray*) (*fRawClusters)[i];
- rawcladdress->Streamer(R__b);
- rechitaddress1D=(TClonesArray*) (*fRecHits1D)[i];
- rechitaddress1D->Streamer(R__b);
- rechitaddress3D=(TClonesArray*) (*fRecHits3D)[i];
- rechitaddress3D->Streamer(R__b);
- digitsaddress=(TClonesArray*) (*fDchambers)[i];
- digitsaddress->Streamer(R__b);
- }
- R__b << fDebugLevel;
- R__b << fCkovNumber;
- R__b << fCkovQuarz;
- R__b << fCkovGap;
- R__b << fCkovCsi;
- R__b << fLostRfreo;
- R__b << fLostRquar;
- R__b << fLostAfreo;
- R__b << fLostAquarz;
- R__b << fLostAmeta;
- R__b << fLostCsi;
- R__b << fLostWires;
- R__b << fFreonProd;
- R__b << fMipx;
- R__b << fMipy;
- R__b << fFeedbacks;
- R__b << fLostFresnel;
- }
-}
-AliRICHPadHit* AliRICH::FirstPad(AliRICHHit* hit,TClonesArray *clusters )
+AliRICHSDigit* AliRICH::FirstPad(AliRICHHit* hit,TClonesArray *clusters )
{
//
// Initialise the pad iterator
- // Return the address of the first padhit for hit
+ // Return the address of the first sdigit for hit
TClonesArray *theClusters = clusters;
Int_t nclust = theClusters->GetEntriesFast();
- if (nclust && hit->fPHlast > 0) {
- sMaxIterPad=Int_t(hit->fPHlast);
- sCurIterPad=Int_t(hit->fPHfirst);
- return (AliRICHPadHit*) clusters->UncheckedAt(sCurIterPad-1);
+ if (nclust && hit->PHlast() > 0) {
+ sMaxIterPad=Int_t(hit->PHlast());
+ sCurIterPad=Int_t(hit->PHfirst());
+ return (AliRICHSDigit*) clusters->UncheckedAt(sCurIterPad-1);
} else {
return 0;
}
}
-AliRICHPadHit* AliRICH::NextPad(TClonesArray *clusters)
+AliRICHSDigit* AliRICH::NextPad(TClonesArray *clusters)
{
// Iterates over pads
sCurIterPad++;
if (sCurIterPad <= sMaxIterPad) {
- return (AliRICHPadHit*) clusters->UncheckedAt(sCurIterPad-1);
+ return (AliRICHSDigit*) clusters->UncheckedAt(sCurIterPad-1);
} else {
return 0;
}
}
+AliRICH& AliRICH::operator=(const AliRICH& rhs)
+{
+// Assignment operator
+ return *this;
+
+}
-void AliRICH::Digitise(Int_t nev, Int_t flag, Option_t *option,Text_t *filename)
+void AliRICH::DiagnosticsFE(Int_t evNumber1,Int_t evNumber2)
{
- // keep galice.root for signal and name differently the file for
- // background when add! otherwise the track info for signal will be lost !
+
+ Int_t NpadX = 162; // number of pads on X
+ Int_t NpadY = 162; // number of pads on Y
+
+ Int_t Pad[162][162];
+ for (Int_t i=0;i<NpadX;i++) {
+ for (Int_t j=0;j<NpadY;j++) {
+ Pad[i][j]=0;
+ }
+ }
+
+ // Create some histograms
+
+ TH1F *pionspectra1 = new TH1F("pionspectra1","Pion Spectra",200,-4,2);
+ TH1F *pionspectra2 = new TH1F("pionspectra2","Pion Spectra",200,-4,2);
+ TH1F *pionspectra3 = new TH1F("pionspectra3","Pion Spectra",200,-4,2);
+ TH1F *protonspectra1 = new TH1F("protonspectra1","Proton Spectra",200,-4,2);
+ TH1F *protonspectra2 = new TH1F("protonspectra2","Proton Spectra",200,-4,2);
+ TH1F *protonspectra3 = new TH1F("protonspectra3","Proton Spectra",200,-4,2);
+ TH1F *kaonspectra1 = new TH1F("kaonspectra1","Kaon Spectra",100,-4,2);
+ TH1F *kaonspectra2 = new TH1F("kaonspectra2","Kaon Spectra",100,-4,2);
+ TH1F *kaonspectra3 = new TH1F("kaonspectra3","Kaon Spectra",100,-4,2);
+ TH1F *electronspectra1 = new TH1F("electronspectra1","Electron Spectra",100,-4,2);
+ TH1F *electronspectra2 = new TH1F("electronspectra2","Electron Spectra",100,-4,2);
+ TH1F *electronspectra3 = new TH1F("electronspectra3","Electron Spectra",100,-4,2);
+ TH1F *muonspectra1 = new TH1F("muonspectra1","Muon Spectra",100,-4,2);
+ TH1F *muonspectra2 = new TH1F("muonspectra2","Muon Spectra",100,-4,2);
+ TH1F *muonspectra3 = new TH1F("muonspectra3","Muon Spectra",100,-4,2);
+ TH1F *neutronspectra1 = new TH1F("neutronspectra1","Neutron Spectra",100,-4,2);
+ TH1F *neutronspectra2 = new TH1F("neutronspectra2","Neutron Spectra",100,-4,2);
+ TH1F *neutronspectra3 = new TH1F("neutronspectra2","Neutron Spectra",100,-4,2);
+ TH1F *chargedspectra1 = new TH1F("chargedspectra1","Charged particles above 1 GeV Spectra",100,-1,3);
+ TH1F *chargedspectra2 = new TH1F("chargedspectra2","Charged particles above 1 GeV Spectra",100,-1,3);
+ TH1F *chargedspectra3 = new TH1F("chargedspectra2","Charged particles above 1 GeV Spectra",100,-1,3);
+ TH1F *pionptspectrafinal = new TH1F("pionptspectrafinal","Primary Pions Transverse Momenta at HMPID",20,0,5);
+ TH1F *pionptspectravertex = new TH1F("pionptspectravertex","Primary Pions Transverse Momenta at vertex",20,0,5);
+ TH1F *kaonptspectrafinal = new TH1F("kaonptspectrafinal","Primary Kaons Transverse Momenta at HMPID",20,0,5);
+ TH1F *kaonptspectravertex = new TH1F("kaonptspectravertex","Primary Kaons Transverse Momenta at vertex",20,0,5);
+ //TH1F *hitsPhi = new TH1F("hitsPhi","Distribution of phi angle of incidence",100,-180,180);
+ TH1F *hitsTheta = new TH1F("hitsTheta","Distribution of Theta angle of incidence, all tracks",100,0,50);
+ TH1F *hitsTheta500MeV = new TH1F("hitsTheta500MeV","Distribution of Theta angle of incidence, 0.5-1 GeV primary tracks",100,0,50);
+ TH1F *hitsTheta1GeV = new TH1F("hitsTheta1GeV","Distribution of Theta angle of incidence, 1-2 GeV primary tracks",100,0,50);
+ TH1F *hitsTheta2GeV = new TH1F("hitsTheta2GeV","Distribution of Theta angle of incidence, 2-3 GeV primary tracks",100,0,50);
+ TH1F *hitsTheta3GeV = new TH1F("hitsTheta3GeV","Distribution of Theta angle of incidence, >3 GeV primary tracks",100,0,50);
+ TH2F *production = new TH2F("production","Mother production vertices",100,-300,300,100,0,600);
+
+
+
- static Bool_t first=kTRUE;
- static TFile *pFile;
- char *addBackground = strstr(option,"Add");
- Int_t particle;
+// Start loop over events
- FILE* points; //these will be the digits...
+ Int_t pion=0, kaon=0, proton=0, electron=0, positron=0, neutron=0, highneutrons=0, muon=0;
+ Int_t chargedpions=0,primarypions=0,highprimarypions=0,chargedkaons=0,primarykaons=0,highprimarykaons=0;
+ Int_t photons=0, primaryphotons=0, highprimaryphotons=0;
+ TRandom* random=0;
- points=fopen("points.dat","w");
+ for (int nev=0; nev<= evNumber2; nev++) {
+ Int_t nparticles = gAlice->GetEvent(nev);
+
- AliRICHChamber* iChamber;
- AliSegmentation* segmentation;
-
- Int_t digitise=0;
- Int_t trk[50];
- Int_t chtrk[50];
- TObjArray *list=new TObjArray;
- static TClonesArray *pAddress=0;
- if(!pAddress) pAddress=new TClonesArray("TVector",1000);
- Int_t digits[5];
-
- AliRICH *pRICH = (AliRICH *) gAlice->GetDetector("RICH");
- AliHitMap* pHitMap[10];
- Int_t i;
- for (i=0; i<10; i++) {pHitMap[i]=0;}
- if (addBackground ) {
- if(first) {
- fFileName=filename;
- cout<<"filename"<<fFileName<<endl;
- pFile=new TFile(fFileName);
- cout<<"I have opened "<<fFileName<<" file "<<endl;
- fHits2 = new TClonesArray("AliRICHHit",1000 );
- fClusters2 = new TClonesArray("AliRICHPadHit",10000);
- first=kFALSE;
- }
- pFile->cd();
- // Get Hits Tree header from file
- if(fHits2) fHits2->Clear();
- if(fClusters2) fClusters2->Clear();
- if(TrH1) delete TrH1;
- TrH1=0;
-
- char treeName[20];
- sprintf(treeName,"TreeH%d",nev);
- TrH1 = (TTree*)gDirectory->Get(treeName);
- if (!TrH1) {
- printf("ERROR: cannot find Hits Tree for event:%d\n",nev);
- }
- // Set branch addresses
- TBranch *branch;
- char branchname[20];
- sprintf(branchname,"%s",GetName());
- if (TrH1 && fHits2) {
- branch = TrH1->GetBranch(branchname);
- if (branch) branch->SetAddress(&fHits2);
- }
- if (TrH1 && fClusters2) {
- branch = TrH1->GetBranch("RICHCluster");
- if (branch) branch->SetAddress(&fClusters2);
- }
- }
-
- AliHitMap* hm;
- Int_t countadr=0;
- Int_t counter=0;
- for (i =0; i<kNCH; i++) {
- iChamber=(AliRICHChamber*) (*fChambers)[i];
- segmentation=iChamber->GetSegmentationModel(1);
- pHitMap[i] = new AliRICHHitMapA1(segmentation, list);
- }
- //
- // Loop over tracks
- //
-
- TTree *treeH = gAlice->TreeH();
- Int_t ntracks =(Int_t) treeH->GetEntries();
- for (Int_t track=0; track<ntracks; track++) {
- gAlice->ResetHits();
- treeH->GetEvent(track);
- //
- // Loop over hits
- for(AliRICHHit* mHit=(AliRICHHit*)pRICH->FirstHit(-1);
- mHit;
- mHit=(AliRICHHit*)pRICH->NextHit())
- {
-
- Int_t nch = mHit->fChamber-1; // chamber number
- Int_t index = mHit->Track();
- if (nch >kNCH) continue;
- iChamber = &(pRICH->Chamber(nch));
-
- TParticle *current = (TParticle*)(*gAlice->Particles())[index];
-
- if (current->GetPdgCode() >= 50000050)
- {
- TParticle *motherofcurrent = (TParticle*)(*gAlice->Particles())[current->GetFirstMother()];
- particle = motherofcurrent->GetPdgCode();
- }
- else
- {
- particle = current->GetPdgCode();
- }
+ printf ("Event number : %d\n",nev);
+ printf ("Number of particles: %d\n",nparticles);
+ if (nev < evNumber1) continue;
+ if (nparticles <= 0) return;
+
+// Get pointers to RICH detector and Hits containers
+
+ AliRICH *pRICH = (AliRICH *) gAlice->GetDetector("RICH");
+
+ TTree *treeH = gAlice->TreeH();
+ Int_t ntracks =(Int_t) treeH->GetEntries();
+
+// Start loop on tracks in the hits containers
+
+ for (Int_t track=0; track<ntracks;track++) {
+ printf ("Processing Track: %d\n",track);
+ gAlice->ResetHits();
+ treeH->GetEvent(track);
+
+ for(AliRICHHit* mHit=(AliRICHHit*)pRICH->FirstHit(-1);
+ mHit;
+ mHit=(AliRICHHit*)pRICH->NextHit())
+ {
+ //Int_t nch = mHit->fChamber; // chamber number
+ //Float_t x = mHit->X(); // x-pos of hit
+ //Float_t y = mHit->Z(); // y-pos
+ //Float_t z = mHit->Y();
+ //Float_t phi = mHit->Phi(); //Phi angle of incidence
+ Float_t theta = mHit->Theta(); //Theta angle of incidence
+ Float_t px = mHit->MomX();
+ Float_t py = mHit->MomY();
+ Int_t index = mHit->Track();
+ Int_t particle = (Int_t)(mHit->Particle());
+ Float_t R;
+ Float_t PTfinal;
+ Float_t PTvertex;
+
+ TParticle *current = gAlice->Particle(index);
+
+ //Float_t energy=current->Energy();
-
- //printf("Flag:%d\n",flag);
- //printf("Track:%d\n",track);
- //printf("Particle:%d\n",particle);
-
- digitise=1;
-
- if (flag == 1)
- if(TMath::Abs(particle)==211 || TMath::Abs(particle)==111)
- digitise=0;
-
- if (flag == 2)
- if(TMath::Abs(particle)==321 || TMath::Abs(particle)==130 || TMath::Abs(particle)==310
- || TMath::Abs(particle)==311)
- digitise=0;
-
- if (flag == 3 && TMath::Abs(particle)==2212)
- digitise=0;
-
- if (flag == 4 && TMath::Abs(particle)==13)
- digitise=0;
-
- if (flag == 5 && TMath::Abs(particle)==11)
- digitise=0;
-
- if (flag == 6 && TMath::Abs(particle)==2112)
- digitise=0;
-
-
- //printf ("Particle: %d, Flag: %d, Digitise: %d\n",particle,flag,digitise);
-
-
- if (digitise)
- {
+ R=TMath::Sqrt(current->Vx()*current->Vx() + current->Vy()*current->Vy());
+ PTfinal=TMath::Sqrt(px*px + py*py);
+ PTvertex=TMath::Sqrt(current->Px()*current->Px() + current->Py()*current->Py());
- //
- // Loop over pad hits
- for (AliRICHPadHit* mPad=
- (AliRICHPadHit*)pRICH->FirstPad(mHit,fPadHits);
- mPad;
- mPad=(AliRICHPadHit*)pRICH->NextPad(fPadHits))
+
+
+ if (TMath::Abs(particle) < 10000000)
{
- Int_t ipx = mPad->fPadX; // pad number on X
- Int_t ipy = mPad->fPadY; // pad number on Y
- Int_t iqpad = mPad->fQpad; // charge per pad
- //
- //
- //printf("X:%d, Y:%d, Q:%d\n",ipx,ipy,iqpad);
-
- Float_t thex, they, thez;
- segmentation=iChamber->GetSegmentationModel(0);
- segmentation->GetPadC(ipx,ipy,thex,they,thez);
- new((*pAddress)[countadr++]) TVector(2);
- TVector &trinfo=*((TVector*) (*pAddress)[countadr-1]);
- trinfo(0)=(Float_t)track;
- trinfo(1)=(Float_t)iqpad;
-
- digits[0]=ipx;
- digits[1]=ipy;
- digits[2]=iqpad;
-
- AliRICHTransientDigit* pdigit;
- // build the list of fired pads and update the info
- if (!pHitMap[nch]->TestHit(ipx, ipy)) {
- list->AddAtAndExpand(new AliRICHTransientDigit(nch,digits),counter);
- pHitMap[nch]->SetHit(ipx, ipy, counter);
- counter++;
- pdigit=(AliRICHTransientDigit*)list->At(list->GetLast());
- // list of tracks
- TObjArray *trlist=(TObjArray*)pdigit->TrackList();
- trlist->Add(&trinfo);
- } else {
- pdigit=(AliRICHTransientDigit*) pHitMap[nch]->GetHit(ipx, ipy);
- // update charge
- (*pdigit).fSignal+=iqpad;
- // update list of tracks
- TObjArray* trlist=(TObjArray*)pdigit->TrackList();
- Int_t lastEntry=trlist->GetLast();
- TVector *ptrkP=(TVector*)trlist->At(lastEntry);
- TVector &ptrk=*ptrkP;
- Int_t lastTrack=Int_t(ptrk(0));
- Int_t lastCharge=Int_t(ptrk(1));
- if (lastTrack==track) {
- lastCharge+=iqpad;
- trlist->RemoveAt(lastEntry);
- trinfo(0)=lastTrack;
- trinfo(1)=lastCharge;
- trlist->AddAt(&trinfo,lastEntry);
- } else {
- trlist->Add(&trinfo);
+ hitsTheta->Fill(theta,(float) 1);
+ if (R<5)
+ {
+ if (PTvertex>.5 && PTvertex<=1)
+ {
+ hitsTheta500MeV->Fill(theta,(float) 1);
+ }
+ if (PTvertex>1 && PTvertex<=2)
+ {
+ hitsTheta1GeV->Fill(theta,(float) 1);
+ }
+ if (PTvertex>2 && PTvertex<=3)
+ {
+ hitsTheta2GeV->Fill(theta,(float) 1);
+ }
+ if (PTvertex>3)
+ {
+ hitsTheta3GeV->Fill(theta,(float) 1);
+ }
}
- // check the track list
- Int_t nptracks=trlist->GetEntriesFast();
- if (nptracks > 2) {
- printf("Attention - tracks: %d (>2)\n",nptracks);
- //printf("cat,nch,ix,iy %d %d %d %d \n",icat+1,nch,ipx,ipy);
- for (Int_t tr=0;tr<nptracks;tr++) {
- TVector *pptrkP=(TVector*)trlist->At(tr);
- TVector &pptrk=*pptrkP;
- trk[tr]=Int_t(pptrk(0));
- chtrk[tr]=Int_t(pptrk(1));
- }
- } // end if nptracks
- } // end if pdigit
- } //end loop over clusters
- }// track type condition
- } // hit loop
- } // track loop
-
- // open the file with background
-
- if (addBackground ) {
- ntracks =(Int_t)TrH1->GetEntries();
- //printf("background - icat,ntracks1 %d %d\n",icat,ntracks);
- //printf("background - Start loop over tracks \n");
- //
- // Loop over tracks
- //
- for (Int_t trak=0; trak<ntracks; trak++) {
- if (fHits2) fHits2->Clear();
- if (fClusters2) fClusters2->Clear();
- TrH1->GetEvent(trak);
- //
- // Loop over hits
- AliRICHHit* mHit;
- for(int j=0;j<fHits2->GetEntriesFast();++j)
- {
- mHit=(AliRICHHit*) (*fHits2)[j];
- Int_t nch = mHit->fChamber-1; // chamber number
- if (nch >6) continue;
- iChamber = &(pRICH->Chamber(nch));
- Int_t rmin = (Int_t)iChamber->RInner();
- Int_t rmax = (Int_t)iChamber->ROuter();
- //
- // Loop over pad hits
- for (AliRICHPadHit* mPad=
- (AliRICHPadHit*)pRICH->FirstPad(mHit,fClusters2);
- mPad;
- mPad=(AliRICHPadHit*)pRICH->NextPad(fClusters2))
- {
- Int_t ipx = mPad->fPadX; // pad number on X
- Int_t ipy = mPad->fPadY; // pad number on Y
- Int_t iqpad = mPad->fQpad; // charge per pad
-
- Float_t thex, they, thez;
- segmentation=iChamber->GetSegmentationModel(0);
- segmentation->GetPadC(ipx,ipy,thex,they,thez);
- Float_t rpad=TMath::Sqrt(thex*thex+they*they);
- if (rpad < rmin || iqpad ==0 || rpad > rmax) continue;
- new((*pAddress)[countadr++]) TVector(2);
- TVector &trinfo=*((TVector*) (*pAddress)[countadr-1]);
- trinfo(0)=-1; // tag background
- trinfo(1)=-1;
- digits[0]=ipx;
- digits[1]=ipy;
- digits[2]=iqpad;
- if (trak <4 && nch==0)
- printf("bgr - pHitMap[nch]->TestHit(ipx, ipy),trak %d %d\n",
- pHitMap[nch]->TestHit(ipx, ipy),trak);
- AliRICHTransientDigit* pdigit;
- // build the list of fired pads and update the info
- if (!pHitMap[nch]->TestHit(ipx, ipy)) {
- list->AddAtAndExpand(new AliRICHTransientDigit(nch,digits),counter);
-
- pHitMap[nch]->SetHit(ipx, ipy, counter);
- counter++;
- printf("bgr new elem in list - counter %d\n",counter);
- pdigit=(AliRICHTransientDigit*)list->At(list->GetLast());
- // list of tracks
- TObjArray *trlist=(TObjArray*)pdigit->TrackList();
- trlist->Add(&trinfo);
- } else {
- pdigit=(AliRICHTransientDigit*) pHitMap[nch]->GetHit(ipx, ipy);
- // update charge
- (*pdigit).fSignal+=iqpad;
- // update list of tracks
- TObjArray* trlist=(TObjArray*)pdigit->TrackList();
- Int_t lastEntry=trlist->GetLast();
- TVector *ptrkP=(TVector*)trlist->At(lastEntry);
- TVector &ptrk=*ptrkP;
- Int_t lastTrack=Int_t(ptrk(0));
- if (lastTrack==-1) {
- continue;
- } else {
- trlist->Add(&trinfo);
- }
- // check the track list
- Int_t nptracks=trlist->GetEntriesFast();
- if (nptracks > 0) {
- for (Int_t tr=0;tr<nptracks;tr++) {
- TVector *pptrkP=(TVector*)trlist->At(tr);
- TVector &pptrk=*pptrkP;
- trk[tr]=Int_t(pptrk(0));
- chtrk[tr]=Int_t(pptrk(1));
- }
- } // end if nptracks
- } // end if pdigit
- } //end loop over clusters
- } // hit loop
- } // track loop
- TTree *fAli=gAlice->TreeK();
- if (fAli) pFile =fAli->GetCurrentFile();
- pFile->cd();
- } // if Add
-
- Int_t tracks[10];
- Int_t charges[10];
- //cout<<"Start filling digits \n "<<endl;
- Int_t nentries=list->GetEntriesFast();
- //printf(" \n \n nentries %d \n",nentries);
-
- // start filling the digits
-
- for (Int_t nent=0;nent<nentries;nent++) {
- AliRICHTransientDigit *address=(AliRICHTransientDigit*)list->At(nent);
- if (address==0) continue;
-
- Int_t ich=address->fChamber;
- Int_t q=address->fSignal;
- iChamber=(AliRICHChamber*) (*fChambers)[ich];
- AliRICHResponse * response=iChamber->GetResponseModel();
- Int_t adcmax= (Int_t) response->MaxAdc();
-
-
- // add white noise and do zero-suppression and signal truncation (new electronics,old electronics gaus 1.2,0.2)
- //printf("Treshold: %d\n",iChamber->fTresh->GetHitIndex(address->fPadX,address->fPadY));
- Int_t pedestal = iChamber->fTresh->GetHitIndex(address->fPadX,address->fPadY);
+ }
- //printf("Pedestal:%d\n",pedestal);
- //Int_t pedestal=0;
- Float_t treshold = (pedestal + 4*2.2);
-
- Float_t meanNoise = gRandom->Gaus(2.2, 0.3);
- Float_t noise = gRandom->Gaus(0, meanNoise);
- q+=(Int_t)(noise + pedestal);
- //q+=(Int_t)(noise);
- // magic number to be parametrised !!!
- if ( q <= treshold)
- {
- q = q - pedestal;
- continue;
- }
- q = q - pedestal;
- if ( q >= adcmax) q=adcmax;
- digits[0]=address->fPadX;
- digits[1]=address->fPadY;
- digits[2]=q;
-
- TObjArray* trlist=(TObjArray*)address->TrackList();
- Int_t nptracks=trlist->GetEntriesFast();
-
- // this was changed to accomodate the real number of tracks
- if (nptracks > 10) {
- cout<<"Attention - tracks > 10 "<<nptracks<<endl;
- nptracks=10;
- }
- if (nptracks > 2) {
- printf("Attention - tracks > 2 %d \n",nptracks);
- //printf("cat,ich,ix,iy,q %d %d %d %d %d \n",
- //icat,ich,digits[0],digits[1],q);
- }
- for (Int_t tr=0;tr<nptracks;tr++) {
- TVector *ppP=(TVector*)trlist->At(tr);
- TVector &pp =*ppP;
- tracks[tr]=Int_t(pp(0));
- charges[tr]=Int_t(pp(1));
- } //end loop over list of tracks for one pad
- if (nptracks < 10 ) {
- for (Int_t t=nptracks; t<10; t++) {
- tracks[t]=0;
- charges[t]=0;
- }
- }
- //write file
- if (ich==2)
- fprintf(points,"%4d, %4d, %4d\n",digits[0],digits[1],digits[2]);
-
- // fill digits
- pRICH->AddDigits(ich,tracks,charges,digits);
- }
- gAlice->TreeD()->Fill();
-
- list->Delete();
- for(Int_t ii=0;ii<kNCH;++ii) {
- if (pHitMap[ii]) {
- hm=pHitMap[ii];
- delete hm;
- pHitMap[ii]=0;
- }
- }
+ //if (nch == 3)
+ //{
+
+ //printf("Particle type: %d\n",current->GetPdgCode());
+ if (TMath::Abs(particle) < 50000051)
+ {
+ //if (TMath::Abs(particle) == 50000050 || TMath::Abs(particle) == 2112)
+ if (TMath::Abs(particle) == 2112 || TMath::Abs(particle) == 50000050)
+ {
+ //gMC->Rndm(&random, 1);
+ if (random->Rndm() < .1)
+ production->Fill(current->Vz(),R,(float) 1);
+ if (TMath::Abs(particle) == 50000050)
+ //if (TMath::Abs(particle) > 50000000)
+ {
+ photons +=1;
+ if (R<5)
+ {
+ primaryphotons +=1;
+ if (current->Energy()>0.001)
+ highprimaryphotons +=1;
+ }
+ }
+ if (TMath::Abs(particle) == 2112)
+ {
+ neutron +=1;
+ if (current->Energy()>0.0001)
+ highneutrons +=1;
+ }
+ }
+ if (TMath::Abs(particle) < 50000000)
+ {
+ production->Fill(current->Vz(),R,(float) 1);
+ //printf("Adding %d at %f\n",particle,R);
+ }
+ //mip->Fill(x,y,(float) 1);
+ }
+
+ if (TMath::Abs(particle)==211 || TMath::Abs(particle)==111)
+ {
+ if (R<5)
+ {
+ pionptspectravertex->Fill(PTvertex,(float) 1);
+ pionptspectrafinal->Fill(PTfinal,(float) 1);
+ }
+ }
+
+ if (TMath::Abs(particle)==321 || TMath::Abs(particle)==130 || TMath::Abs(particle)==310
+ || TMath::Abs(particle)==311)
+ {
+ if (R<5)
+ {
+ kaonptspectravertex->Fill(PTvertex,(float) 1);
+ kaonptspectrafinal->Fill(PTfinal,(float) 1);
+ }
+ }
+
+
+ if (TMath::Abs(particle)==211 || TMath::Abs(particle)==111)
+ {
+ pionspectra1->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //printf ("fParticle: %d, PDG code:%d\n",particle,current->GetPdgCode());
+ if (current->Vx()>5 && current->Vy()>5 && current->Vz()>5)
+ pionspectra2->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ if (R>250 && R<450)
+ {
+ pionspectra3->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //printf("\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\R:%f\n\n\n\n\n\n\n\n\n",R);
+ }
+ //printf("Pion mass: %e\n",current->GetCalcMass());
+ pion +=1;
+ if (TMath::Abs(particle)==211)
+ {
+ chargedpions +=1;
+ if (R<5)
+ {
+ primarypions +=1;
+ if (current->Energy()>1)
+ highprimarypions +=1;
+ }
+ }
+ }
+ if (TMath::Abs(particle)==2212)
+ {
+ protonspectra1->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //ptspectra->Fill(Pt,(float) 1);
+ if (current->Vx()>5 && current->Vy()>5 && current->Vz()>5)
+ protonspectra2->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ if (R>250 && R<450)
+ protonspectra3->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //printf("\n\n\n\n\n\n\nProton mass: %e\n\n\n\n\n\n\n\n\n",current->GetCalcMass());
+ proton +=1;
+ }
+ if (TMath::Abs(particle)==321 || TMath::Abs(particle)==130 || TMath::Abs(particle)==310
+ || TMath::Abs(particle)==311)
+ {
+ kaonspectra1->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //ptspectra->Fill(Pt,(float) 1);
+ if (current->Vx()>5 && current->Vy()>5 && current->Vz()>5)
+ kaonspectra2->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ if (R>250 && R<450)
+ kaonspectra3->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //printf("Kaon mass: %e\n",current->GetCalcMass());
+ kaon +=1;
+ if (TMath::Abs(particle)==321)
+ {
+ chargedkaons +=1;
+ if (R<5)
+ {
+ primarykaons +=1;
+ if (current->Energy()>1)
+ highprimarykaons +=1;
+ }
+ }
+ }
+ if (TMath::Abs(particle)==11)
+ {
+ electronspectra1->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //ptspectra->Fill(Pt,(float) 1);
+ if (current->Vx()>5 && current->Vy()>5 && current->Vz()>5)
+ electronspectra2->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ if (R>250 && R<450)
+ electronspectra3->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //printf("Electron mass: %e\n",current->GetCalcMass());
+ if (particle == 11)
+ electron +=1;
+ if (particle == -11)
+ positron +=1;
+ }
+ if (TMath::Abs(particle)==13)
+ {
+ muonspectra1->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //ptspectra->Fill(Pt,(float) 1);
+ if (current->Vx()>5 && current->Vy()>5 && current->Vz()>5)
+ muonspectra2->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ if (R>250 && R<450)
+ muonspectra3->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //printf("Muon mass: %e\n",current->GetCalcMass());
+ muon +=1;
+ }
+ if (TMath::Abs(particle)==2112)
+ {
+ neutronspectra1->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //ptspectra->Fill(Pt,(float) 1);
+ if (current->Vx()>5 && current->Vy()>5 && current->Vz()>5)
+ neutronspectra2->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ if (R>250 && R<450)
+ {
+ neutronspectra3->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ //printf("\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\R:%f\n\n\n\n\n\n\n\n\n",R);
+ }
+ //printf("Neutron mass: %e\n",current->GetCalcMass());
+ neutron +=1;
+ }
+ if(TMath::Abs(particle)==211 || TMath::Abs(particle)==2212 || TMath::Abs(particle)==321)
+ {
+ if (current->Energy()-current->GetCalcMass()>1)
+ {
+ chargedspectra1->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ if (current->Vx()>5 && current->Vy()>5 && current->Vz()>5)
+ chargedspectra2->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ if (R>250 && R<450)
+ chargedspectra3->Fill(TMath::Log10(current->Energy() - current->GetCalcMass()),(float) 1);
+ }
+ }
+ //printf("Hits:%d\n",hit);
+ //printf ("Chamber number:%d x:%f y:%f\n",nch,x,y);
+ // Fill the histograms
+ //Nh1+=nhits;
+ //h->Fill(x,y,(float) 1);
+ //}
+ //}
+ }
+
+ }
+
+ }
+ // }
+
+ //Create canvases, set the view range, show histograms
+
+ TCanvas *c2 = new TCanvas("c2","Angles of incidence",150,150,100,150);
+ c2->Divide(2,2);
+ //c2->SetFillColor(42);
+
+ c2->cd(1);
+ hitsTheta500MeV->SetFillColor(5);
+ hitsTheta500MeV->Draw();
+ c2->cd(2);
+ hitsTheta1GeV->SetFillColor(5);
+ hitsTheta1GeV->Draw();
+ c2->cd(3);
+ hitsTheta2GeV->SetFillColor(5);
+ hitsTheta2GeV->Draw();
+ c2->cd(4);
+ hitsTheta3GeV->SetFillColor(5);
+ hitsTheta3GeV->Draw();
- //TTree *TD=gAlice->TreeD();
- //Stat_t ndig=TD->GetEntries();
- //cout<<"number of digits "<<ndig<<endl;
- TClonesArray *fDch;
- for (int k=0;k<kNCH;k++) {
- fDch= pRICH->DigitsAddress(k);
- int ndigit=fDch->GetEntriesFast();
- printf ("Chamber %d digits %d \n",k,ndigit);
- }
- pRICH->ResetDigits();
- char hname[30];
- sprintf(hname,"TreeD%d",nev);
- gAlice->TreeD()->Write(hname,kOverwrite,0);
-
- // reset tree
- // gAlice->TreeD()->Reset();
- delete list;
- pAddress->Clear();
- // gObjectTable->Print();
+
+
+ TCanvas *c15 = new TCanvas("c15","Mothers Production Vertices",50,50,600,600);
+ c15->cd();
+ production->SetFillColor(42);
+ production->SetXTitle("z (m)");
+ production->SetYTitle("R (m)");
+ production->Draw();
+
+ TCanvas *c10 = new TCanvas("c10","Pt Spectra",50,50,600,700);
+ c10->Divide(2,2);
+ c10->cd(1);
+ pionptspectravertex->SetFillColor(5);
+ pionptspectravertex->SetXTitle("Pt (GeV)");
+ pionptspectravertex->Draw();
+ c10->cd(2);
+ pionptspectrafinal->SetFillColor(5);
+ pionptspectrafinal->SetXTitle("Pt (GeV)");
+ pionptspectrafinal->Draw();
+ c10->cd(3);
+ kaonptspectravertex->SetFillColor(5);
+ kaonptspectravertex->SetXTitle("Pt (GeV)");
+ kaonptspectravertex->Draw();
+ c10->cd(4);
+ kaonptspectrafinal->SetFillColor(5);
+ kaonptspectrafinal->SetXTitle("Pt (GeV)");
+ kaonptspectrafinal->Draw();
+
+
+ TCanvas *c16 = new TCanvas("c16","Particles Spectra II",150,150,600,350);
+ c16->Divide(2,1);
+
+ c16->cd(1);
+ //TCanvas *c13 = new TCanvas("c13","Electron Spectra",400,10,600,700);
+ electronspectra1->SetFillColor(5);
+ electronspectra1->SetXTitle("log(GeV)");
+ electronspectra2->SetFillColor(46);
+ electronspectra2->SetXTitle("log(GeV)");
+ electronspectra3->SetFillColor(10);
+ electronspectra3->SetXTitle("log(GeV)");
+ //c13->SetLogx();
+ electronspectra1->Draw();
+ electronspectra2->Draw("same");
+ electronspectra3->Draw("same");
+
+ c16->cd(2);
+ //TCanvas *c14 = new TCanvas("c14","Muon Spectra",400,10,600,700);
+ muonspectra1->SetFillColor(5);
+ muonspectra1->SetXTitle("log(GeV)");
+ muonspectra2->SetFillColor(46);
+ muonspectra2->SetXTitle("log(GeV)");
+ muonspectra3->SetFillColor(10);
+ muonspectra3->SetXTitle("log(GeV)");
+ //c14->SetLogx();
+ muonspectra1->Draw();
+ muonspectra2->Draw("same");
+ muonspectra3->Draw("same");
+
+ //c16->cd(3);
+ //TCanvas *c16 = new TCanvas("c16","Neutron Spectra",400,10,600,700);
+ //neutronspectra1->SetFillColor(42);
+ //neutronspectra1->SetXTitle("log(GeV)");
+ //neutronspectra2->SetFillColor(46);
+ //neutronspectra2->SetXTitle("log(GeV)");
+ //neutronspectra3->SetFillColor(10);
+ //neutronspectra3->SetXTitle("log(GeV)");
+ //c16->SetLogx();
+ //neutronspectra1->Draw();
+ //neutronspectra2->Draw("same");
+ //neutronspectra3->Draw("same");
+
+ TCanvas *c9 = new TCanvas("c9","Particles Spectra",150,150,600,700);
+ //TCanvas *c9 = new TCanvas("c9","Pion Spectra",400,10,600,700);
+ c9->Divide(2,2);
+
+ c9->cd(1);
+ pionspectra1->SetFillColor(5);
+ pionspectra1->SetXTitle("log(GeV)");
+ pionspectra2->SetFillColor(46);
+ pionspectra2->SetXTitle("log(GeV)");
+ pionspectra3->SetFillColor(10);
+ pionspectra3->SetXTitle("log(GeV)");
+ //c9->SetLogx();
+ pionspectra1->Draw();
+ pionspectra2->Draw("same");
+ pionspectra3->Draw("same");
+
+ c9->cd(2);
+ //TCanvas *c10 = new TCanvas("c10","Proton Spectra",400,10,600,700);
+ protonspectra1->SetFillColor(5);
+ protonspectra1->SetXTitle("log(GeV)");
+ protonspectra2->SetFillColor(46);
+ protonspectra2->SetXTitle("log(GeV)");
+ protonspectra3->SetFillColor(10);
+ protonspectra3->SetXTitle("log(GeV)");
+ //c10->SetLogx();
+ protonspectra1->Draw();
+ protonspectra2->Draw("same");
+ protonspectra3->Draw("same");
+
+ c9->cd(3);
+ //TCanvas *c11 = new TCanvas("c11","Kaon Spectra",400,10,600,700);
+ kaonspectra1->SetFillColor(5);
+ kaonspectra1->SetXTitle("log(GeV)");
+ kaonspectra2->SetFillColor(46);
+ kaonspectra2->SetXTitle("log(GeV)");
+ kaonspectra3->SetFillColor(10);
+ kaonspectra3->SetXTitle("log(GeV)");
+ //c11->SetLogx();
+ kaonspectra1->Draw();
+ kaonspectra2->Draw("same");
+ kaonspectra3->Draw("same");
+
+ c9->cd(4);
+ //TCanvas *c12 = new TCanvas("c12","Charged Particles Spectra",400,10,600,700);
+ chargedspectra1->SetFillColor(5);
+ chargedspectra1->SetXTitle("log(GeV)");
+ chargedspectra2->SetFillColor(46);
+ chargedspectra2->SetXTitle("log(GeV)");
+ chargedspectra3->SetFillColor(10);
+ chargedspectra3->SetXTitle("log(GeV)");
+ //c12->SetLogx();
+ chargedspectra1->Draw();
+ chargedspectra2->Draw("same");
+ chargedspectra3->Draw("same");
+
+
+
+ printf("*****************************************\n");
+ printf("* Particle * Counts *\n");
+ printf("*****************************************\n");
+
+ printf("* Pions: * %4d *\n",pion);
+ printf("* Charged Pions: * %4d *\n",chargedpions);
+ printf("* Primary Pions: * %4d *\n",primarypions);
+ printf("* Primary Pions (p>1GeV/c): * %4d *\n",highprimarypions);
+ printf("* Kaons: * %4d *\n",kaon);
+ printf("* Charged Kaons: * %4d *\n",chargedkaons);
+ printf("* Primary Kaons: * %4d *\n",primarykaons);
+ printf("* Primary Kaons (p>1GeV/c): * %4d *\n",highprimarykaons);
+ printf("* Muons: * %4d *\n",muon);
+ printf("* Electrons: * %4d *\n",electron);
+ printf("* Positrons: * %4d *\n",positron);
+ printf("* Protons: * %4d *\n",proton);
+ printf("* All Charged: * %4d *\n",(chargedpions+chargedkaons+muon+electron+positron+proton));
+ printf("*****************************************\n");
+ //printf("* Photons: * %3.1f *\n",photons);
+ //printf("* Primary Photons: * %3.1f *\n",primaryphotons);
+ //printf("* Primary Photons (p>1MeV/c):* %3.1f *\n",highprimaryphotons);
+ //printf("*****************************************\n");
+ //printf("* Neutrons: * %3.1f *\n",neutron);
+ //printf("* Neutrons (p>100keV/c): * %3.1f *\n",highneutrons);
+ //printf("*****************************************\n");
+
+ if (gAlice->TreeD())
+ {
+ gAlice->TreeD()->GetEvent(0);
+
+ Float_t occ[7];
+ Float_t sum=0;
+ Float_t mean=0;
+ printf("\n*****************************************\n");
+ printf("* Chamber * Digits * Occupancy *\n");
+ printf("*****************************************\n");
+
+ for (Int_t ich=0;ich<7;ich++)
+ {
+ TClonesArray *Digits = DigitsAddress(ich); // Raw clusters branch
+ Int_t ndigits = Digits->GetEntriesFast();
+ occ[ich] = Float_t(ndigits)/(160*144);
+ sum += Float_t(ndigits)/(160*144);
+ printf("* %d * %d * %3.1f%% *\n",ich,ndigits,occ[ich]*100);
+ }
+ mean = sum/7;
+ printf("*****************************************\n");
+ printf("* Mean occupancy * %3.1f%% *\n",mean*100);
+ printf("*****************************************\n");
+ }
+
+ printf("\nEnd of analysis\n");
+
}
-AliRICH& AliRICH::operator=(const AliRICH& rhs)
+//_________________________________________________________________________________________________
+
+
+void AliRICH::DiagnosticsSE(Int_t diaglevel,Int_t evNumber1,Int_t evNumber2)
{
-// Assignment operator
- return *this;
+
+AliRICH *pRICH = (AliRICH*)gAlice->GetDetector("RICH");
+ AliRICHSegmentationV0* segmentation;
+ AliRICHChamber* chamber;
+
+ chamber = &(pRICH->Chamber(0));
+ segmentation=(AliRICHSegmentationV0*) chamber->GetSegmentationModel();
+
+ Int_t NpadX = segmentation->Npx(); // number of pads on X
+ Int_t NpadY = segmentation->Npy(); // number of pads on Y
-}
+ //Int_t Pad[144][160];
+ /*for (Int_t i=0;i<NpadX;i++) {
+ for (Int_t j=0;j<NpadY;j++) {
+ Pad[i][j]=0;
+ }
+ } */
-Int_t AliRICH::MakePadHits(Float_t xhit,Float_t yhit,Float_t eloss, Int_t idvol, ResponseType res)
-{
+
+ Int_t xmin= -NpadX/2;
+ Int_t xmax= NpadX/2;
+ Int_t ymin= -NpadY/2;
+ Int_t ymax= NpadY/2;
+
+ TH2F *feedback = 0;
+ TH2F *mip = 0;
+ TH2F *cerenkov = 0;
+ TH2F *h = 0;
+ TH1F *hitsX = 0;
+ TH1F *hitsY = 0;
+
+ TH2F *hc0 = new TH2F("hc0","Zoom on center of central chamber",150,-30,30,150,-50,10);
+
+ if (diaglevel == 1)
+ {
+ printf("Single Ring Hits\n");
+ feedback = new TH2F("feedback","Feedback hit distribution",150,-30,30,150,-50,10);
+ mip = new TH2F("mip","Mip hit distribution",150,-30,30,150,-50,10);
+ cerenkov = new TH2F("cerenkov","Cerenkov hit distribution",150,-30,30,150,-50,10);
+ h = new TH2F("h","Detector hit distribution",150,-30,30,150,-50,10);
+ hitsX = new TH1F("hitsX","Distribution of hits along x-axis",150,-30,30);
+ hitsY = new TH1F("hitsY","Distribution of hits along z-axis",150,-50,10);
+ }
+ else
+ {
+ printf("Full Event Hits\n");
+
+ feedback = new TH2F("feedback","Feedback hit distribution",150,-300,300,150,-300,300);
+ mip = new TH2F("mip","Mip hit distribution",150,-300,300,150,-300,300);
+ cerenkov = new TH2F("cerenkov","Cerenkov hit distribution",150,-300,300,150,-300,300);
+ h = new TH2F("h","Detector hit distribution",150,-300,300,150,-300,300);
+ hitsX = new TH1F("digitsX","Distribution of hits along x-axis",200,-300,300);
+ hitsY = new TH1F("digitsY","Distribution of hits along z-axis",200,-300,300);
+ }
+
+
+
+ TH2F *hc1 = new TH2F("hc1","Chamber 1 signal distribution",NpadX,xmin,xmax,NpadY,ymin,ymax);
+ TH2F *hc2 = new TH2F("hc2","Chamber 2 signal distribution",NpadX,xmin,xmax,NpadY,ymin,ymax);
+ TH2F *hc3 = new TH2F("hc3","Chamber 3 signal distribution",NpadX,xmin,xmax,NpadY,ymin,ymax);
+ TH2F *hc4 = new TH2F("hc4","Chamber 4 signal distribution",NpadX,xmin,xmax,NpadY,ymin,ymax);
+ TH2F *hc5 = new TH2F("hc5","Chamber 5 signal distribution",NpadX,xmin,xmax,NpadY,ymin,ymax);
+ TH2F *hc6 = new TH2F("hc6","Chamber 6 signal distribution",NpadX,xmin,xmax,NpadY,ymin,ymax);
+ TH2F *hc7 = new TH2F("hc7","Chamber 7 signal distribution",NpadX,xmin,xmax,NpadY,ymin,ymax);
+
+ TH1F *Clcharge = new TH1F("Clcharge","Cluster Charge Distribution",500,0.,500.);
+ TH1F *ckovangle = new TH1F("ckovangle","Cerenkov angle per photon",200,.3,1);
+ TH1F *hckphi = new TH1F("hckphi","Cerenkov phi angle per photon",620,-3.1,3.1);
+ TH1F *mother = new TH1F("mother","Cerenkovs per Mip",75,0.,75.);
+ TH1F *radius = new TH1F("radius","Mean distance to Mip",100,0.,20.);
+ TH1F *phspectra1 = new TH1F("phspectra1","Detected Photon Spectra",200,5.,10.);
+ TH1F *phspectra2 = new TH1F("phspectra2","Produced Photon Spectra",200,5.,10.);
+ TH1F *totalphotonstrack = new TH1F("totalphotonstrack","Produced Photons per Mip",100,200,700.);
+ TH1F *totalphotonsevent = new TH1F("totalphotonsevent","Produced Photons per Mip",100,200,700.);
+ //TH1F *feedbacks = new TH1F("feedbacks","Produced Feedbacks per Mip",50,0.5,50.);
+ TH1F *padnumber = new TH1F("padnumber","Number of pads per cluster",50,-0.5,50.);
+ TH1F *padsev = new TH1F("padsev","Number of pads hit per MIP",50,0.5,100.);
+ TH1F *clusev = new TH1F("clusev","Number of clusters per MIP",50,0.5,50.);
+ TH1F *photev = new TH1F("photev","Number of detected photons per MIP",50,0.5,50.);
+ TH1F *feedev = new TH1F("feedev","Number of feedbacks per MIP",50,0.5,50.);
+ TH1F *padsmip = new TH1F("padsmip","Number of pads per event inside MIP region",50,0.5,50.);
+ TH1F *padscl = new TH1F("padscl","Number of pads per event from cluster count",50,0.5,100.);
+ TH1F *pionspectra = new TH1F("pionspectra","Pion Spectra",200,.5,10.);
+ TH1F *protonspectra = new TH1F("protonspectra","Proton Spectra",200,.5,10.);
+ TH1F *kaonspectra = new TH1F("kaonspectra","Kaon Spectra",100,.5,10.);
+ TH1F *chargedspectra = new TH1F("chargedspectra","Charged particles above 1 GeV Spectra",100,.5,10.);
+ TH1F *hitsPhi = new TH1F("hitsPhi","Distribution of phi angle of incidence",100,0,360);
+ TH1F *hitsTheta = new TH1F("hitsTheta","Distribution of Theta angle of incidence",100,0,15);
+ TH1F *Omega1D = new TH1F("omega","Reconstructed Cerenkov angle per track",200,.5,1);
+ TH1F *Theta = new TH1F("theta","Reconstructed theta incidence angle per track",200,0,15);
+ TH1F *Phi = new TH1F("phi","Reconstructed phi incidence per track",200,0,360);
+ TH1F *Omega3D = new TH1F("omega","Reconstructed Cerenkov angle per track",200,.3,1);
+ TH1F *PhotonCer = new TH1F("photoncer","Reconstructed Cerenkov angle per photon",200,.3,1);
+ TH2F *PadsUsed = new TH2F("padsused","Pads Used for Reconstruction",100,-30,30,100,-30,30);
+ TH1F *MeanRadius = new TH1F("radius","Mean Radius for reconstructed track",100,0.,20.);
+
+// Start loop over events
+
+ Int_t Nh=0;
+ Int_t pads=0;
+ Int_t Nh1=0;
+ Int_t mothers[80000];
+ Int_t mothers2[80000];
+ Float_t mom[3];
+ Int_t nraw=0;
+ Int_t phot=0;
+ Int_t feed=0;
+ Int_t padmip=0;
+ Float_t x=0,y=0;
+
+ for (Int_t i=0;i<100;i++) mothers[i]=0;
+
+ for (int nev=0; nev<= evNumber2; nev++) {
+ Int_t nparticles = gAlice->GetEvent(nev);
+
+
+ //cout<<"nev "<<nev<<endl;
+ printf ("\n**********************************\nProcessing Event: %d\n",nev);
+ //cout<<"nparticles "<<nparticles<<endl;
+ printf ("Particles : %d\n\n",nparticles);
+ if (nev < evNumber1) continue;
+ if (nparticles <= 0) return;
+
+// Get pointers to RICH detector and Hits containers
+
+
+ TTree *TH = gAlice->TreeH();
+ Stat_t ntracks = TH->GetEntries();
+
+ // Start loop on tracks in the hits containers
+ //Int_t Nc=0;
+ for (Int_t track=0; track<ntracks;track++) {
+
+ printf ("\nProcessing Track: %d\n",track);
+ gAlice->ResetHits();
+ TH->GetEvent(track);
+ Int_t nhits = pRICH->Hits()->GetEntriesFast();
+ if (nhits) Nh+=nhits;
+ printf("Hits : %d\n",nhits);
+ for(AliRICHHit* mHit=(AliRICHHit*)pRICH->FirstHit(-1);
+ mHit;
+ mHit=(AliRICHHit*)pRICH->NextHit())
+ {
+ //Int_t nch = mHit->fChamber; // chamber number
+ x = mHit->X(); // x-pos of hit
+ y = mHit->Z(); // y-pos
+ Float_t phi = mHit->Phi(); //Phi angle of incidence
+ Float_t theta = mHit->Theta(); //Theta angle of incidence
+ Int_t index = mHit->Track();
+ Int_t particle = (Int_t)(mHit->Particle());
+ //Int_t freon = (Int_t)(mHit->fLoss);
+
+ hitsX->Fill(x,(float) 1);
+ hitsY->Fill(y,(float) 1);
+
+ //printf("Particle:%9d\n",particle);
+
+ TParticle *current = (TParticle*)gAlice->Particle(index);
+ //printf("Particle type: %d\n",sizeoff(Particles));
+
+ hitsTheta->Fill(theta,(float) 1);
+ //hitsPhi->Fill(phi,(float) 1);
+ //if (pRICH->GetDebugLevel() == -1)
+ //printf("Theta:%f, Phi:%f\n",theta,phi);
+
+ //printf("Debug Level:%d\n",pRICH->GetDebugLevel());
+
+ if (current->GetPdgCode() < 10000000)
+ {
+ mip->Fill(x,y,(float) 1);
+ //printf("adding mip\n");
+ //if (current->Energy() - current->GetCalcMass()>1 && freon==1)
+ //{
+ hitsPhi->Fill(TMath::Abs(phi),(float) 1);
+ //hitsTheta->Fill(theta,(float) 1);
+ //printf("Theta:%f, Phi:%f\n",theta,phi);
+ //}
+ }
+
+ if (TMath::Abs(particle)==211 || TMath::Abs(particle)==111)
+ {
+ pionspectra->Fill(current->Energy() - current->GetCalcMass(),(float) 1);
+ }
+ if (TMath::Abs(particle)==2212)
+ {
+ protonspectra->Fill(current->Energy() - current->GetCalcMass(),(float) 1);
+ }
+ if (TMath::Abs(particle)==321 || TMath::Abs(particle)==130 || TMath::Abs(particle)==310
+ || TMath::Abs(particle)==311)
+ {
+ kaonspectra->Fill(current->Energy() - current->GetCalcMass(),(float) 1);
+ }
+ if(TMath::Abs(particle)==211 || TMath::Abs(particle)==2212 || TMath::Abs(particle)==321)
+ {
+ if (current->Energy() - current->GetCalcMass()>1)
+ chargedspectra->Fill(current->Energy() - current->GetCalcMass(),(float) 1);
+ }
+ //printf("Hits:%d\n",hit);
+ //printf ("Chamber number:%d x:%f y:%f\n",nch,x,y);
+ // Fill the histograms
+ Nh1+=nhits;
+ h->Fill(x,y,(float) 1);
+ //}
+ //}
+ }
+
+ Int_t ncerenkovs = pRICH->Cerenkovs()->GetEntriesFast();
+ //if (current->GetPdgCode() < 50000051 && current->GetPdgCode() > 50000040)
+ //totalphotonsevent->Fill(ncerenkovs,(float) 1);
+
+ if (ncerenkovs) {
+ printf("Cerenkovs : %d\n",ncerenkovs);
+ totalphotonsevent->Fill(ncerenkovs,(float) 1);
+ for (Int_t hit=0;hit<ncerenkovs;hit++) {
+ AliRICHCerenkov* cHit = (AliRICHCerenkov*) pRICH->Cerenkovs()->UncheckedAt(hit);
+ //Int_t nchamber = cHit->fChamber; // chamber number
+ Int_t index = cHit->Track();
+ //Int_t pindex = (Int_t)(cHit->fIndex);
+ Float_t cx = cHit->X(); // x-position
+ Float_t cy = cHit->Z(); // y-position
+ Int_t cmother = cHit->fCMother; // Index of mother particle
+ Int_t closs = (Int_t)(cHit->fLoss); // How did the particle get lost?
+ Float_t cherenkov = cHit->fCerenkovAngle; //production cerenkov angle
+ //printf ("Cerenkov hit number %d/%d, X:%d, Y:%d\n",hit,ncerenkovs,cx,cy);
+
+ //printf("Particle:%9d\n",index);
+
+ TParticle *current = (TParticle*)gAlice->Particle(index);
+ Float_t energyckov = current->Energy();
+
+ if (current->GetPdgCode() == 50000051)
+ {
+ if (closs==4)
+ {
+ feedback->Fill(cx,cy,(float) 1);
+ feed++;
+ }
+ }
+ if (current->GetPdgCode() == 50000050)
+ {
+
+ if (closs !=4)
+ {
+ phspectra2->Fill(energyckov*1e9,(float) 1);
+ }
+
+ if (closs==4)
+ {
+ cerenkov->Fill(cx,cy,(float) 1);
+
+ //printf ("Cerenkov hit number %d/%d, X:%d, Y:%d\n",hit,ncerenkovs,cx,cy);
+
+ //TParticle *MIP = (TParticle*)gAlice->Particle(cmother);
+ AliRICHHit* mipHit = (AliRICHHit*) pRICH->Hits()->UncheckedAt(0);
+ mom[0] = current->Px();
+ mom[1] = current->Py();
+ mom[2] = current->Pz();
+ //mom[0] = cHit->fMomX;
+ // mom[1] = cHit->fMomZ;
+ //mom[2] = cHit->fMomY;
+ //Float_t energymip = MIP->Energy();
+ //Float_t Mip_px = mipHit->fMomFreoX;
+ //Float_t Mip_py = mipHit->fMomFreoY;
+ //Float_t Mip_pz = mipHit->fMomFreoZ;
+ //Float_t Mip_px = MIP->Px();
+ //Float_t Mip_py = MIP->Py();
+ //Float_t Mip_pz = MIP->Pz();
+
+
+
+ //Float_t r = mom[0]*mom[0] + mom[1]*mom[1] + mom[2]*mom[2];
+ //Float_t rt = TMath::Sqrt(r);
+ //Float_t Mip_r = Mip_px*Mip_px + Mip_py*Mip_py + Mip_pz*Mip_pz;
+ //Float_t Mip_rt = TMath::Sqrt(Mip_r);
+ //Float_t coscerenkov = (mom[0]*Mip_px + mom[1]*Mip_py + mom[2]*Mip_pz)/(rt*Mip_rt+0.0000001);
+ //Float_t cherenkov = TMath::ACos(coscerenkov);
+ ckovangle->Fill(cherenkov,(float) 1); //Cerenkov angle calculus
+ //printf("Cherenkov: %f\n",cherenkov);
+ Float_t ckphi=TMath::ATan2(mom[0], mom[2]);
+ hckphi->Fill(ckphi,(float) 1);
+
+
+ //Float_t mix = MIP->Vx();
+ //Float_t miy = MIP->Vy();
+ Float_t mx = mipHit->X();
+ Float_t my = mipHit->Z();
+ //printf("FX %e, FY %e, VX %e, VY %e\n",cx,cy,mx,my);
+ Float_t dx = cx - mx;
+ Float_t dy = cy - my;
+ //printf("Dx:%f, Dy:%f\n",dx,dy);
+ Float_t final_radius = TMath::Sqrt(dx*dx+dy*dy);
+ //printf("Final radius:%f\n",final_radius);
+ radius->Fill(final_radius,(float) 1);
+
+ phspectra1->Fill(energyckov*1e9,(float) 1);
+ phot++;
+ }
+ for (Int_t nmothers=0;nmothers<=ntracks;nmothers++){
+ if (cmother == nmothers){
+ if (closs == 4)
+ mothers2[cmother]++;
+ mothers[cmother]++;
+ }
+ }
+ }
+ }
+ }
+
+
+ if(gAlice->TreeR())
+ {
+ Int_t nent=(Int_t)gAlice->TreeR()->GetEntries();
+ gAlice->TreeR()->GetEvent(nent-1);
+ TClonesArray *Rawclusters = pRICH->RawClustAddress(2); // Raw clusters branch
+ //printf ("Rawclusters:%p",Rawclusters);
+ Int_t nrawclusters = Rawclusters->GetEntriesFast();
+
+ if (nrawclusters) {
+ printf("Raw Clusters : %d\n",nrawclusters);
+ for (Int_t hit=0;hit<nrawclusters;hit++) {
+ AliRICHRawCluster* rcHit = (AliRICHRawCluster*) pRICH->RawClustAddress(2)->UncheckedAt(hit);
+ //Int_t nchamber = rcHit->fChamber; // chamber number
+ //Int_t nhit = cHit->fHitNumber; // hit number
+ Int_t qtot = rcHit->fQ; // charge
+ Float_t fx = rcHit->fX; // x-position
+ Float_t fy = rcHit->fY; // y-position
+ //Int_t type = rcHit->fCtype; // cluster type ?
+ Int_t mult = rcHit->fMultiplicity; // How many pads form the cluster
+ pads += mult;
+ if (qtot > 0) {
+ //printf ("fx: %d, fy: %d\n",fx,fy);
+ if (fx>(x-4) && fx<(x+4) && fy>(y-4) && fy<(y+4)) {
+ //printf("There %d \n",mult);
+ padmip+=mult;
+ } else {
+ padnumber->Fill(mult,(float) 1);
+ nraw++;
+ if (mult<4) Clcharge->Fill(qtot,(float) 1);
+ }
+
+ }
+ }
+ }
+
+
+ TClonesArray *RecHits1D = pRICH->RecHitsAddress1D(2);
+ Int_t nrechits1D = RecHits1D->GetEntriesFast();
+ //printf (" nrechits:%d\n",nrechits);
+
+ if(nrechits1D)
+ {
+ for (Int_t hit=0;hit<nrechits1D;hit++) {
+ AliRICHRecHit1D* recHit1D = (AliRICHRecHit1D*) pRICH->RecHitsAddress1D(2)->UncheckedAt(hit);
+ Float_t r_omega = recHit1D->fOmega; // Cerenkov angle
+ Float_t *cer_pho = recHit1D->fCerPerPhoton; // Cerenkov angle per photon
+ Int_t *padsx = recHit1D->fPadsUsedX; // Pads Used fo reconstruction (x)
+ Int_t *padsy = recHit1D->fPadsUsedY; // Pads Used fo reconstruction (y)
+ Int_t goodPhotons = recHit1D->fGoodPhotons; // Number of pads used for reconstruction
+
+ Omega1D->Fill(r_omega,(float) 1);
+
+ for (Int_t i=0; i<goodPhotons; i++)
+ {
+ PhotonCer->Fill(cer_pho[i],(float) 1);
+ PadsUsed->Fill(padsx[i],padsy[i],1);
+ //printf("Angle:%f, pad: %d %d\n",cer_pho[i],padsx[i],padsy[i]);
+ }
+
+ //printf("Omega: %f, Theta: %f, Phi: %f\n",r_omega,r_theta,r_phi);
+ }
+ }
+
+
+ TClonesArray *RecHits3D = pRICH->RecHitsAddress3D(2);
+ Int_t nrechits3D = RecHits3D->GetEntriesFast();
+ //printf (" nrechits:%d\n",nrechits);
+
+ if(nrechits3D)
+ {
+ for (Int_t hit=0;hit<nrechits3D;hit++) {
+ AliRICHRecHit3D* recHit3D = (AliRICHRecHit3D*) pRICH->RecHitsAddress3D(2)->UncheckedAt(hit);
+ Float_t r_omega = recHit3D->fOmega; // Cerenkov angle
+ Float_t r_theta = recHit3D->fTheta; // Theta angle of incidence
+ Float_t r_phi = recHit3D->fPhi; // Phi angle if incidence
+ Float_t meanradius = recHit3D->fMeanRadius; // Mean radius for reconstructed point
+
+ //printf("rechit %f %f %f %f %f\n",recHit3D->fOmega,recHit3D->fTheta,recHit3D->fPhi, recHit3D->fX,recHit3D->fY);
+
+ Omega3D->Fill(r_omega,(float) 1);
+ Theta->Fill(r_theta*180/TMath::Pi(),(float) 1);
+ Phi->Fill(r_phi*180/TMath::Pi()-180,(float) 1);
+ MeanRadius->Fill(meanradius,(float) 1);
+ }
+ }
+ }
+ }
+
+ for (Int_t nmothers=0;nmothers<ntracks;nmothers++){
+ totalphotonstrack->Fill(mothers[nmothers],(float) 1);
+ mother->Fill(mothers2[nmothers],(float) 1);
+ //printf ("Entries in %d : %d\n",nmothers, mothers[nmothers]);
+ }
+
+ clusev->Fill(nraw,(float) 1);
+ photev->Fill(phot,(float) 1);
+ feedev->Fill(feed,(float) 1);
+ padsmip->Fill(padmip,(float) 1);
+ padscl->Fill(pads,(float) 1);
+ //printf("Photons:%d\n",phot);
+ phot = 0;
+ feed = 0;
+ pads = 0;
+ nraw=0;
+ padmip=0;
+
+
+
+ gAlice->ResetDigits();
+ //Int_t nent=(Int_t)gAlice->TreeD()->GetEntries();
+ gAlice->TreeD()->GetEvent(0);
+
+ if (diaglevel < 4)
+ {
+
+
+ TClonesArray *Digits = pRICH->DigitsAddress(2);
+ Int_t ndigits = Digits->GetEntriesFast();
+ printf("Digits : %d\n",ndigits);
+ padsev->Fill(ndigits,(float) 1);
+ for (Int_t hit=0;hit<ndigits;hit++) {
+ AliRICHDigit* dHit = (AliRICHDigit*) Digits->UncheckedAt(hit);
+ Int_t qtot = dHit->Signal(); // charge
+ Int_t ipx = dHit->PadX(); // pad number on X
+ Int_t ipy = dHit->PadY(); // pad number on Y
+ //printf("%d, %d\n",ipx,ipy);
+ if( ipx<=100 && ipy <=100) hc0->Fill(ipx,ipy,(float) qtot);
+ }
+ }
+
+ if (diaglevel == 5)
+ {
+ for (Int_t ich=0;ich<7;ich++)
+ {
+ TClonesArray *Digits = pRICH->DigitsAddress(ich); // Raw clusters branch
+ Int_t ndigits = Digits->GetEntriesFast();
+ //printf("Digits:%d\n",ndigits);
+ padsev->Fill(ndigits,(float) 1);
+ if (ndigits) {
+ for (Int_t hit=0;hit<ndigits;hit++) {
+ AliRICHDigit* dHit = (AliRICHDigit*) Digits->UncheckedAt(hit);
+ //Int_t nchamber = dHit->GetChamber(); // chamber number
+ //Int_t nhit = dHit->fHitNumber; // hit number
+ Int_t qtot = dHit->Signal(); // charge
+ Int_t ipx = dHit->PadX(); // pad number on X
+ Int_t ipy = dHit->PadY(); // pad number on Y
+ //Int_t iqpad = dHit->fQpad; // charge per pad
+ //Int_t rpad = dHit->fRSec; // R-position of pad
+ //printf ("Pad hit, PadX:%d, PadY:%d\n",ipx,ipy);
+ if( ipx<=100 && ipy <=100 && ich==2) hc0->Fill(ipx,ipy,(float) qtot);
+ if( ipx<=162 && ipy <=162 && ich==0) hc1->Fill(ipx,ipy,(float) qtot);
+ if( ipx<=162 && ipy <=162 && ich==1) hc2->Fill(ipx,ipy,(float) qtot);
+ if( ipx<=162 && ipy <=162 && ich==2) hc3->Fill(ipx,ipy,(float) qtot);
+ if( ipx<=162 && ipy <=162 && ich==3) hc4->Fill(ipx,ipy,(float) qtot);
+ if( ipx<=162 && ipy <=162 && ich==4) hc5->Fill(ipx,ipy,(float) qtot);
+ if( ipx<=162 && ipy <=162 && ich==5) hc6->Fill(ipx,ipy,(float) qtot);
+ if( ipx<=162 && ipy <=162 && ich==6) hc7->Fill(ipx,ipy,(float) qtot);
+ }
+ }
+ }
+ }
+ }
+
+
+ //Create canvases, set the view range, show histograms
+
+ TCanvas *c1 = 0;
+ TCanvas *c2 = 0;
+ TCanvas *c3 = 0;
+ TCanvas *c4 = 0;
+ TCanvas *c5 = 0;
+ TCanvas *c6 = 0;
+ TCanvas *c7 = 0;
+ TCanvas *c8 = 0;
+ TCanvas *c9 = 0;
+ TCanvas *c10 = 0;
+ TCanvas *c11 = 0;
+ TCanvas *c12 = 0;
+ //TF1* expo = 0;
+ //TF1* gaus = 0;
+
+
+ TClonesArray *RecHits3D = pRICH->RecHitsAddress3D(2);
+ Int_t nrechits3D = RecHits3D->GetEntriesFast();
+ TClonesArray *RecHits1D = pRICH->RecHitsAddress1D(2);
+ Int_t nrechits1D = RecHits1D->GetEntriesFast();
+
+ switch(diaglevel)
+ {
+ case 1:
+
+ c1 = new TCanvas("c1","Alice RICH digits",50,50,300,350);
+ hc0->SetXTitle("ix (npads)");
+ hc0->Draw("box");
+
//
-// Calls the charge disintegration method of the current chamber and adds
-// the simulated cluster to the root treee
+ c2 = new TCanvas("c2","Hits per type",100,100,600,700);
+ c2->Divide(2,2);
+ //c4->SetFillColor(42);
+
+ c2->cd(1);
+ feedback->SetXTitle("x (cm)");
+ feedback->SetYTitle("y (cm)");
+ feedback->Draw();
+
+ c2->cd(2);
+ //mip->SetFillColor(5);
+ mip->SetXTitle("x (cm)");
+ mip->SetYTitle("y (cm)");
+ mip->Draw();
+
+ c2->cd(3);
+ //cerenkov->SetFillColor(5);
+ cerenkov->SetXTitle("x (cm)");
+ cerenkov->SetYTitle("y (cm)");
+ cerenkov->Draw();
+
+ c2->cd(4);
+ //h->SetFillColor(5);
+ h->SetXTitle("x (cm)");
+ h->SetYTitle("y (cm)");
+ h->Draw();
+
+ c3 = new TCanvas("c3","Hits distribution",150,150,600,350);
+ c3->Divide(2,1);
+ //c10->SetFillColor(42);
+
+ c3->cd(1);
+ hitsX->SetFillColor(5);
+ hitsX->SetXTitle("(cm)");
+ hitsX->Draw();
+
+ c3->cd(2);
+ hitsY->SetFillColor(5);
+ hitsY->SetXTitle("(cm)");
+ hitsY->Draw();
+
+
+ break;
//
- Int_t clhits[5];
- Float_t newclust[4][500];
- Int_t nnew;
-
+ case 2:
+
+ c4 = new TCanvas("c4","Photon Spectra",50,50,600,350);
+ c4->Divide(2,1);
+ //c6->SetFillColor(42);
+
+ c4->cd(1);
+ phspectra2->SetFillColor(5);
+ phspectra2->SetXTitle("energy (eV)");
+ phspectra2->Draw();
+ c4->cd(2);
+ phspectra1->SetFillColor(5);
+ phspectra1->SetXTitle("energy (eV)");
+ phspectra1->Draw();
+
+ c5 = new TCanvas("c5","Particles Spectra",100,100,600,700);
+ c5->Divide(2,2);
+ //c9->SetFillColor(42);
+
+ c5->cd(1);
+ pionspectra->SetFillColor(5);
+ pionspectra->SetXTitle("(GeV)");
+ pionspectra->Draw();
+
+ c5->cd(2);
+ protonspectra->SetFillColor(5);
+ protonspectra->SetXTitle("(GeV)");
+ protonspectra->Draw();
+
+ c5->cd(3);
+ kaonspectra->SetFillColor(5);
+ kaonspectra->SetXTitle("(GeV)");
+ kaonspectra->Draw();
+
+ c5->cd(4);
+ chargedspectra->SetFillColor(5);
+ chargedspectra->SetXTitle("(GeV)");
+ chargedspectra->Draw();
+
+ break;
+
+ case 3:
+
+
+ if(gAlice->TreeR())
+ {
+ c6=new TCanvas("c6","Clusters Statistics",50,50,600,700);
+ c6->Divide(2,2);
+ //c3->SetFillColor(42);
+
+ c6->cd(1);
+ //TPad* c6_1;
+ //c6_1->SetLogy();
+ Clcharge->SetFillColor(5);
+ Clcharge->SetXTitle("ADC counts");
+ if (evNumber2>10)
+ {
+ Clcharge->Fit("expo");
+ //expo->SetLineColor(2);
+ //expo->SetLineWidth(3);
+ }
+ Clcharge->Draw();
+
+ c6->cd(2);
+ padnumber->SetFillColor(5);
+ padnumber->SetXTitle("(counts)");
+ padnumber->Draw();
+
+ c6->cd(3);
+ clusev->SetFillColor(5);
+ clusev->SetXTitle("(counts)");
+ if (evNumber2>10)
+ {
+ clusev->Fit("gaus");
+ //gaus->SetLineColor(2);
+ //gaus->SetLineWidth(3);
+ }
+ clusev->Draw();
+
+ c6->cd(4);
+ padsmip->SetFillColor(5);
+ padsmip->SetXTitle("(counts)");
+ padsmip->Draw();
+ }
+
+ if(evNumber2<1)
+ {
+ c11 = new TCanvas("c11","Cherenkov per Mip",400,10,600,700);
+ mother->SetFillColor(5);
+ mother->SetXTitle("counts");
+ mother->Draw();
+ }
+
+ c7 = new TCanvas("c7","Production Statistics",100,100,600,700);
+ c7->Divide(2,2);
+ //c7->SetFillColor(42);
+
+ c7->cd(1);
+ totalphotonsevent->SetFillColor(5);
+ totalphotonsevent->SetXTitle("Photons (counts)");
+ if (evNumber2>10)
+ {
+ totalphotonsevent->Fit("gaus");
+ //gaus->SetLineColor(2);
+ //gaus->SetLineWidth(3);
+ }
+ totalphotonsevent->Draw();
+
+ c7->cd(2);
+ photev->SetFillColor(5);
+ photev->SetXTitle("(counts)");
+ if (evNumber2>10)
+ {
+ photev->Fit("gaus");
+ //gaus->SetLineColor(2);
+ //gaus->SetLineWidth(3);
+ }
+ photev->Draw();
+
+ c7->cd(3);
+ feedev->SetFillColor(5);
+ feedev->SetXTitle("(counts)");
+ if (evNumber2>10)
+ {
+ feedev->Fit("gaus");
+ //gaus->SetLineColor(2);
+ //gaus->SetLineWidth(3);
+ }
+ feedev->Draw();
+
+ c7->cd(4);
+ padsev->SetFillColor(5);
+ padsev->SetXTitle("(counts)");
+ if (evNumber2>10)
+ {
+ padsev->Fit("gaus");
+ //gaus->SetLineColor(2);
+ //gaus->SetLineWidth(3);
+ }
+ padsev->Draw();
+
+ break;
+
+ case 4:
+
+
+ if(nrechits3D)
+ {
+ c8 = new TCanvas("c8","3D reconstruction",50,50,1100,700);
+ c8->Divide(4,2);
+ //c2->SetFillColor(42);
+
+ c8->cd(1);
+ hitsPhi->SetFillColor(5);
+ hitsPhi->Draw();
+ c8->cd(2);
+ hitsTheta->SetFillColor(5);
+ hitsTheta->Draw();
+ c8->cd(3);
+ ckovangle->SetFillColor(5);
+ ckovangle->SetXTitle("angle (radians)");
+ ckovangle->Draw();
+ c8->cd(4);
+ radius->SetFillColor(5);
+ radius->SetXTitle("radius (cm)");
+ radius->Draw();
+ c8->cd(5);
+ Phi->SetFillColor(5);
+ Phi->Draw();
+ c8->cd(6);
+ Theta->SetFillColor(5);
+ Theta->Draw();
+ c8->cd(7);
+ Omega3D->SetFillColor(5);
+ Omega3D->SetXTitle("angle (radians)");
+ Omega3D->Draw();
+ c8->cd(8);
+ MeanRadius->SetFillColor(5);
+ MeanRadius->SetXTitle("radius (cm)");
+ MeanRadius->Draw();
+
+ }
+
+ if(nrechits1D)
+ {
+ c9 = new TCanvas("c9","1D Reconstruction",100,100,1100,700);
+ c9->Divide(3,2);
+ //c5->SetFillColor(42);
+
+ c9->cd(1);
+ ckovangle->SetFillColor(5);
+ ckovangle->SetXTitle("angle (radians)");
+ ckovangle->Draw();
+
+ c9->cd(2);
+ radius->SetFillColor(5);
+ radius->SetXTitle("radius (cm)");
+ radius->Draw();
+
+ c9->cd(3);
+ hc0->SetXTitle("pads");
+ hc0->Draw("box");
+
+ c9->cd(5);
+ Omega1D->SetFillColor(5);
+ Omega1D->SetXTitle("angle (radians)");
+ Omega1D->Draw();
+
+ c9->cd(4);
+ PhotonCer->SetFillColor(5);
+ PhotonCer->SetXTitle("angle (radians)");
+ PhotonCer->Draw();
+
+ c9->cd(6);
+ PadsUsed->SetXTitle("pads");
+ PadsUsed->Draw("box");
+ }
+
+ break;
+
+ case 5:
+
+ printf("Drawing histograms.../n");
+
+ //if (ndigits)
+ //{
+ c10 = new TCanvas("c10","Alice RICH digits",50,50,1200,700);
+ c1->Divide(4,2);
+ //c1->SetFillColor(42);
+
+ c10->cd(1);
+ hc1->SetXTitle("ix (npads)");
+ hc1->Draw("box");
+ c10->cd(2);
+ hc2->SetXTitle("ix (npads)");
+ hc2->Draw("box");
+ c10->cd(3);
+ hc3->SetXTitle("ix (npads)");
+ hc3->Draw("box");
+ c10->cd(4);
+ hc4->SetXTitle("ix (npads)");
+ hc4->Draw("box");
+ c10->cd(5);
+ hc5->SetXTitle("ix (npads)");
+ hc5->Draw("box");
+ c10->cd(6);
+ hc6->SetXTitle("ix (npads)");
+ hc6->Draw("box");
+ c10->cd(7);
+ hc7->SetXTitle("ix (npads)");
+ hc7->Draw("box");
+ c10->cd(8);
+ hc0->SetXTitle("ix (npads)");
+ hc0->Draw("box");
+ //}
//
-// Integrated pulse height on chamber
-
- clhits[0]=fNhits+1;
-
- ((AliRICHChamber*) (*fChambers)[idvol])->DisIntegration(eloss, xhit, yhit, nnew, newclust, res);
- Int_t ic=0;
+ c11 = new TCanvas("c11","Hits per type",100,100,600,700);
+ c11->Divide(2,2);
+ //c4->SetFillColor(42);
+
+ c11->cd(1);
+ feedback->SetXTitle("x (cm)");
+ feedback->SetYTitle("y (cm)");
+ feedback->Draw();
+
+ c11->cd(2);
+ //mip->SetFillColor(5);
+ mip->SetXTitle("x (cm)");
+ mip->SetYTitle("y (cm)");
+ mip->Draw();
+
+ c11->cd(3);
+ //cerenkov->SetFillColor(5);
+ cerenkov->SetXTitle("x (cm)");
+ cerenkov->SetYTitle("y (cm)");
+ cerenkov->Draw();
+
+ c11->cd(4);
+ //h->SetFillColor(5);
+ h->SetXTitle("x (cm)");
+ h->SetYTitle("y (cm)");
+ h->Draw();
+
+ c12 = new TCanvas("c12","Hits distribution",150,150,600,350);
+ c12->Divide(2,1);
+ //c10->SetFillColor(42);
+
+ c12->cd(1);
+ hitsX->SetFillColor(5);
+ hitsX->SetXTitle("(cm)");
+ hitsX->Draw();
+
+ c12->cd(2);
+ hitsY->SetFillColor(5);
+ hitsY->SetXTitle("(cm)");
+ hitsY->Draw();
+
+ break;
+
+ }
+
+
+ // calculate the number of pads which give a signal
+
+
+ //Int_t Np=0;
+ /*for (Int_t i=0;i< NpadX;i++) {
+ for (Int_t j=0;j< NpadY;j++) {
+ if (Pad[i][j]>=6){
+ Np+=1;
+ }
+ }
+ }*/
+ //printf("The total number of pads which give a signal: %d %d\n",Nh,Nh1);
+ printf("\nEnd of analysis\n");
+ printf("**********************************\n");
+}
+
+////////////////////////////////////////////////////////////////////////
+void AliRICH::MakeBranchInTreeD(TTree *treeD, const char *file)
+{
+ //
+ // Create TreeD branches for the RICH.
+ //
+
+ const Int_t kBufferSize = 4000;
+ char branchname[30];
-//
-// Add new clusters
- for (Int_t i=0; i<nnew; i++) {
- if (Int_t(newclust[0][i]) > 0) {
- ic++;
-// Cluster Charge
- clhits[1] = Int_t(newclust[0][i]);
-// Pad: ix
- clhits[2] = Int_t(newclust[1][i]);
-// Pad: iy
- clhits[3] = Int_t(newclust[2][i]);
-// Pad: chamber sector
- clhits[4] = Int_t(newclust[3][i]);
-
- AddPadHit(clhits);
- }
+ //
+ // one branch for digits per chamber
+ //
+ for (Int_t i=0; i<kNCH ;i++) {
+ sprintf(branchname,"%sDigits%d",GetName(),i+1);
+ if (fDchambers && treeD) {
+ MakeBranchInTree(treeD,
+ branchname, &((*fDchambers)[i]), kBufferSize, file);
+// printf("Making Branch %s for digits in chamber %d\n",branchname,i+1);
}
-return nnew;
+ }
}
-
+////////////////////////////////////////////////////////////////////////
git://git.uio.no / u / mrichter / AliRoot.git / blobdiff