#include "AliGenHijingEventHeader.h"
#include "AliRunDigitizer.h"
#include "AliRunLoader.h"
-#include "AliCDBStorage.h"
+#include "AliLoader.h"
+#include "AliGRPObject.h"
+#include "AliCDBManager.h"
#include "AliCDBEntry.h"
#include "AliZDCSDigit.h"
#include "AliZDCDigit.h"
#include "AliZDCFragment.h"
+#include "AliZDCv3.h"
#include "AliZDCDigitizer.h"
-#include "AliZDCCalibData.h"
+
+class AliCDBStorage;
+class AliZDCPedestals;
ClassImp(AliZDCDigitizer)
//____________________________________________________________________________
-AliZDCDigitizer::AliZDCDigitizer()
+AliZDCDigitizer::AliZDCDigitizer() :
+ fIsCalibration(0),
+ fIsSignalInADCGate(kFALSE),
+ fFracLostSignal(0.),
+ fPedData(0),
+ fSpectators2Track(kFALSE),
+ fBeamEnergy(0.)
{
-// Default constructor
-
+ // Default constructor
+ for(Int_t i=0; i<2; i++) fADCRes[i]=0.;
}
//____________________________________________________________________________
AliZDCDigitizer::AliZDCDigitizer(AliRunDigitizer* manager):
- AliDigitizer(manager)
+ AliDigitizer(manager),
+ fIsCalibration(0), //By default the simulation doesn't create calib. data
+ fIsSignalInADCGate(kFALSE),
+ fFracLostSignal(0.),
+ fPedData(GetPedData()),
+ fSpectators2Track(kFALSE),
+ fBeamEnergy(0.)
{
- // Constructor
- // if(!fStorage) fStorage = AliCDBManager::Instance()->GetStorage("local://DBlocal");
+ // Get calibration data
+ if(fIsCalibration!=0) printf("\n\t AliZDCDigitizer -> Creating calibration data (pedestals)\n");
+ for(Int_t i=0; i<5; i++){
+ for(Int_t j=0; j<5; j++)
+ fPMGain[i][j] = 0.;
+ }
}
//____________________________________________________________________________
AliZDCDigitizer::~AliZDCDigitizer()
{
// Destructor
-
+// Not implemented
}
+//____________________________________________________________________________
+AliZDCDigitizer::AliZDCDigitizer(const AliZDCDigitizer &digitizer):
+ AliDigitizer(),
+ fIsCalibration(digitizer.fIsCalibration),
+ fIsSignalInADCGate(digitizer.fIsSignalInADCGate),
+ fFracLostSignal(digitizer.fFracLostSignal),
+ fPedData(digitizer.fPedData),
+ fSpectators2Track(digitizer.fSpectators2Track),
+ fBeamEnergy(digitizer.fBeamEnergy)
+{
+ // Copy constructor
+
+ for(Int_t i=0; i<5; i++){
+ for(Int_t j=0; j<5; j++){
+ fPMGain[i][j] = digitizer.fPMGain[i][j];
+ }
+ }
+ for(Int_t i=0; i<2; i++) fADCRes[i] = digitizer.fADCRes[i];
+
+
+}
+
//____________________________________________________________________________
Bool_t AliZDCDigitizer::Init()
{
// Initialize the digitizer
- // NB -> PM gain vs. HV & ADC resolutions will move to DCDB ***************
- for (Int_t i = 0; i < 3; i++) {
- for(Int_t j = 0; j < 5; j++) {
- fPMGain[i][j] = 100000.;
+
+ AliCDBEntry* entry = AliCDBManager::Instance()->Get("GRP/GRP/Data");
+ if(!entry) AliFatal("No calibration data loaded!");
+ AliGRPObject* grpData = 0x0;
+ if(entry){
+ TMap* m = dynamic_cast<TMap*>(entry->GetObject()); // old GRP entry
+ if(m){
+ //m->Print();
+ grpData = new AliGRPObject();
+ grpData->ReadValuesFromMap(m);
+ }
+ else{
+ grpData = dynamic_cast<AliGRPObject*>(entry->GetObject()); // new GRP entry
+ }
+ entry->SetOwner(0);
+ AliCDBManager::Instance()->UnloadFromCache("GRP/GRP/Data");
+ }
+ if(!grpData){
+ AliError("No GRP entry found in OCDB! \n ");
+ return kFALSE;
+ }
+
+ TString beamType = grpData->GetBeamType();
+ if(beamType==AliGRPObject::GetInvalidString()){
+ AliError("\t UNKNOWN beam type from GRP obj -> PMT gains not set in ZDC digitizer!!!\n");
+ }
+
+ fBeamEnergy = grpData->GetBeamEnergy();
+ if(fBeamEnergy==AliGRPObject::GetInvalidFloat()){
+ AliWarning("GRP/GRP/Data entry: missing value for the beam energy ! Using 0.");
+ AliError("\t UNKNOWN beam type from GRP obj -> PMT gains not set in ZDC digitizer!!!\n");
+ fBeamEnergy = 0.;
+ }
+
+ if((beamType.CompareTo("P-P")) == 0 || (beamType.CompareTo("p-p")) == 0){
+ //PTM gains rescaled to beam energy for p-p
+ // New correction coefficients for PMT gains needed
+ // to reproduce experimental spectra (from Grazia Jul 2010)
+ if(fBeamEnergy != 0){
+ for(Int_t j = 0; j < 5; j++){
+ fPMGain[0][j] = 1.515831*(661.444/fBeamEnergy+0.000740671)*10000000;
+ fPMGain[1][j] = 0.674234*(864.350/fBeamEnergy+0.00234375)*10000000;
+ fPMGain[3][j] = 1.350938*(661.444/fBeamEnergy+0.000740671)*10000000;
+ fPMGain[4][j] = 0.678597*(864.350/fBeamEnergy+0.00234375)*10000000;
+ }
+ fPMGain[2][1] = 0.869654*(1.32312-0.000101515*fBeamEnergy)*10000000;
+ fPMGain[2][2] = 1.030883*(1.32312-0.000101515*fBeamEnergy)*10000000;
+ //
+ AliInfo(Form(" PMT gains for p-p @ %1.0f+%1.0f GeV: ZN(%1.0f), ZP(%1.0f), ZEM(%1.0f)\n",
+ fBeamEnergy, fBeamEnergy, fPMGain[0][0], fPMGain[1][0], fPMGain[2][1]));
+ }
+ else{ // for RELDIS simulation
+ Float_t scalGainFactor = 0.5;
+ for(Int_t j = 0; j < 5; j++){
+ fPMGain[0][j] = 50000./scalGainFactor; // ZNC
+ fPMGain[1][j] = 100000./scalGainFactor; // ZPC
+ fPMGain[2][j] = 100000./scalGainFactor; // ZEM
+ fPMGain[3][j] = 50000./scalGainFactor; // ZNA
+ fPMGain[4][j] = 100000./scalGainFactor; // ZPA
+ }
+ //
+ AliInfo(Form(" PMT gains for RELDIS simulation: ZN(%1.0f), ZP(%1.0f), ZEM(%1.0f)\n",
+ fPMGain[0][0], fPMGain[1][0], fPMGain[2][1]));
}
}
+ else if((beamType.CompareTo("A-A")) == 0){
+ // PTM gains for Pb-Pb @ 2.7+2.7 A TeV ***************
+ // rescaled for Pb-Pb @ 1.38+1.38 A TeV ***************
+ // Values corrected after 2010 Pb-Pb data taking (7/2/2011 - Ch.)
+ // Experimental data compared to EMD simulation for single nucleon peaks:
+ // ZN gains must be divided by 4, ZP gains by 10!
+ Float_t scalGainFactor = fBeamEnergy/2760.;
+ for(Int_t j = 0; j < 5; j++){
+ fPMGain[0][j] = 50000./(4*scalGainFactor); // ZNC
+ fPMGain[1][j] = 100000./(5*scalGainFactor); // ZPC
+ fPMGain[2][j] = 100000./scalGainFactor; // ZEM
+ fPMGain[3][j] = 50000./(4*scalGainFactor); // ZNA
+ fPMGain[4][j] = 100000./(5*scalGainFactor); // ZPA
+ }
+ AliInfo(Form(" PMT gains for Pb-Pb @ %1.0f+%1.0f A GeV: ZN(%1.0f), ZP(%1.0f), ZEM(%1.0f)\n",
+ fBeamEnergy, fBeamEnergy, fPMGain[0][0], fPMGain[1][0], fPMGain[2][1]));
+ }
+
// ADC Caen V965
- fADCRes[0] = 0.0000008; // ADC Resolution high gain: 200 fC/adcCh
- fADCRes[1] = 0.0000064; // ADC Resolution low gain: 25 fC/adcCh
+ fADCRes[0] = 0.0000008; // ADC Resolution high gain: 200 fC/adcCh
+ fADCRes[1] = 0.0000064; // ADC Resolution low gain: 25 fC/adcCh
return kTRUE;
}
{
// Execute digitization
- Float_t pm[3][5];
- // --- pm[0][...] = light in ZN [C, Q1, Q2, Q3, Q4]
- // --- pm[1][...] = light in ZP [C, Q1, Q2, Q3, Q4]
+ // ------------------------------------------------------------
+ // !!! 2nd ZDC set added
+ // *** 1st 3 arrays are digits from REAL (simulated) hits
+ // *** last 2 are copied from simulated digits
+ // --- pm[0][...] = light in ZN side C [C, Q1, Q2, Q3, Q4]
+ // --- pm[1][...] = light in ZP side C [C, Q1, Q2, Q3, Q4]
// --- pm[2][...] = light in ZEM [x, 1, 2, x, x]
- for (Int_t iSector1 = 0; iSector1 < 3; iSector1++)
- for (Int_t iSector2 = 0; iSector2 < 5; iSector2++) {
+ // --- pm[3][...] = light in ZN side A [C, Q1, Q2, Q3, Q4] ->NEW!
+ // --- pm[4][...] = light in ZP side A [C, Q1, Q2, Q3, Q4] ->NEW!
+ // ------------------------------------------------------------
+ Float_t pm[5][5];
+ for(Int_t iSector1=0; iSector1<5; iSector1++)
+ for(Int_t iSector2=0; iSector2<5; iSector2++){
pm[iSector1][iSector2] = 0;
}
+
+ // ------------------------------------------------------------
+ // ### Out of time ADC added (22 channels)
+ // --- same codification as for signal PTMs (see above)
+ // ------------------------------------------------------------
+ Float_t pmoot[5][5];
+ for(Int_t iSector1=0; iSector1<5; iSector1++)
+ for(Int_t iSector2=0; iSector2<5; iSector2++){
+ pmoot[iSector1][iSector2] = 0;
+ }
// impact parameter and number of spectators
- Float_t impPar = -1;
- Int_t specN = 0;
- Int_t specP = 0;
+ Float_t impPar = 0;
+ Int_t specNTarg = 0, specPTarg = 0;
+ Int_t specNProj = 0, specPProj = 0;
+ Float_t signalTime0 = 0.;
// loop over input streams
- for (Int_t iInput = 0; iInput < fManager->GetNinputs(); iInput++) {
+ for(Int_t iInput = 0; iInput<fManager->GetNinputs(); iInput++){
// get run loader and ZDC loader
AliRunLoader* runLoader =
AliRunLoader::GetRunLoader(fManager->GetInputFolderName(iInput));
AliLoader* loader = runLoader->GetLoader("ZDCLoader");
- if (!loader) continue;
+ if(!loader) continue;
// load sdigits
loader->LoadSDigits();
TTree* treeS = loader->TreeS();
- if (!treeS) continue;
+ if(!treeS) continue;
AliZDCSDigit sdigit;
AliZDCSDigit* psdigit = &sdigit;
treeS->SetBranchAddress("ZDC", &psdigit);
// loop over sdigits
- for (Int_t iSDigit = 0; iSDigit < treeS->GetEntries(); iSDigit++) {
+ for(Int_t iSDigit=0; iSDigit<treeS->GetEntries(); iSDigit++){
treeS->GetEntry(iSDigit);
- if (!psdigit) continue;
-
- if ((sdigit.GetSector(1) < 0) || (sdigit.GetSector(1) > 4)) {
+ //
+ if(!psdigit) continue;
+ if((sdigit.GetSector(1) < 0) || (sdigit.GetSector(1) > 4)){
AliError(Form("\nsector[0] = %d, sector[1] = %d\n",
sdigit.GetSector(0), sdigit.GetSector(1)));
continue;
}
+ // Checking if signal is inside ADC gate
+ if(iSDigit==0) signalTime0 = sdigit.GetTrackTime();
+ else{
+ // Assuming a signal lenght of 20 ns, signal is in gate if
+ // signal ENDS in signalTime0+50. -> sdigit.GetTrackTime()+20<=signalTime0+50.
+ if(sdigit.GetTrackTime()<=signalTime0+30.) fIsSignalInADCGate = kTRUE;
+ if(sdigit.GetTrackTime()>signalTime0+30.){
+ fIsSignalInADCGate = kFALSE;
+ // Vedi quaderno per spiegazione approx. usata
+ // nel calcolo della fraz. di segnale perso
+ fFracLostSignal = (sdigit.GetTrackTime()-30)*(sdigit.GetTrackTime()-30)/280.;
+ }
+ }
+
+ Float_t sdSignal = sdigit.GetLightPM();
+ if(fIsSignalInADCGate == kFALSE){
+ AliDebug(2,Form("\t Signal time %f -> fraction %f of ZDC signal for det.(%d, %d) out of ADC gate\n",
+ sdigit.GetTrackTime(),fFracLostSignal,sdigit.GetSector(0),sdigit.GetSector(1)));
+ sdSignal = (1-fFracLostSignal)*sdSignal;
+ }
+
pm[(sdigit.GetSector(0))-1][sdigit.GetSector(1)] += sdigit.GetLightPM();
- printf("\n\t Detector (%d, %d), pm[%d][%d] = %.0f \n",
+ //Ch. debug
+ /*printf("\t Detector %d, Tower %d -> pm[%d][%d] = %.0f \n",
sdigit.GetSector(0), sdigit.GetSector(1),sdigit.GetSector(0)-1,
- sdigit.GetSector(1), pm[sdigit.GetSector(0)-1][sdigit.GetSector(1)]); // Chiara debugging!
+ sdigit.GetSector(1), pm[sdigit.GetSector(0)-1][sdigit.GetSector(1)]);
+ */
+
}
- // unload sdigits
loader->UnloadSDigits();
// get the impact parameter and the number of spectators in case of hijing
- if (!runLoader->GetAliRun()) runLoader->LoadgAlice();
- AliHeader* header = runLoader->GetAliRun()->GetHeader();
- if (!header) continue;
+ if(!runLoader->GetAliRun()) runLoader->LoadgAlice();
+ AliHeader* header = runLoader->GetHeader();
+ if(!header) continue;
AliGenEventHeader* genHeader = header->GenEventHeader();
- if (!genHeader) continue;
- if (!genHeader->InheritsFrom(AliGenHijingEventHeader::Class())) continue;
- impPar = ((AliGenHijingEventHeader*) genHeader)->ImpactParameter();
- //
- specN = ((AliGenHijingEventHeader*) genHeader)->ProjSpectatorsn();
- specP = ((AliGenHijingEventHeader*) genHeader)->ProjSpectatorsp();
- AliDebug(2, Form("\n b = %f fm, Nspecn = %d, Nspecp = %d\n",
- impPar, specN, specP));
- printf("\n\t **** b = %f fm, Nspecn = %d, Nspecp = %d\n",
- impPar, specN, specP);
+ if(!genHeader) continue;
+ if(!genHeader->InheritsFrom(AliGenHijingEventHeader::Class())) continue;
+
+ if(fSpectators2Track==kTRUE){
+ impPar = ((AliGenHijingEventHeader*) genHeader)->ImpactParameter();
+ specNProj = ((AliGenHijingEventHeader*) genHeader)->ProjSpectatorsn();
+ specPProj = ((AliGenHijingEventHeader*) genHeader)->ProjSpectatorsp();
+ specNTarg = ((AliGenHijingEventHeader*) genHeader)->TargSpectatorsn();
+ specPTarg = ((AliGenHijingEventHeader*) genHeader)->TargSpectatorsp();
+ /*printf("\n\t AliZDCDigitizer: b = %1.2f fm\n"
+ " \t PROJ.: #spectator n %d, #spectator p %d\n"
+ " \t TARG.: #spectator n %d, #spectator p %d\n",
+ impPar, specNProj, specPProj, specNTarg, specPTarg);*/
+ }
+
}
- // add spectators
- if (impPar >= 0) {
- Int_t freeSpecN, freeSpecP;
- Fragmentation(impPar, specN, specP, freeSpecN, freeSpecP);
- printf("\n\t ---- Adding signal for %d free spectator n\n",freeSpecN);
- SpectatorSignal(1, freeSpecN, pm);
- printf("\t ---- Adding signal for %d free spectator p\n\n",freeSpecP);
- SpectatorSignal(2, freeSpecP, pm);
+ // Applying fragmentation algorithm and adding spectator signal
+ if(fSpectators2Track==kTRUE && impPar) {
+ Int_t freeSpecNProj, freeSpecPProj;
+ Fragmentation(impPar, specNProj, specPProj, freeSpecNProj, freeSpecPProj);
+ Int_t freeSpecNTarg, freeSpecPTarg;
+ Fragmentation(impPar, specNTarg, specPTarg, freeSpecNTarg, freeSpecPTarg);
+ SpectatorSignal(1, freeSpecNProj, pm);
+// printf("\t AliZDCDigitizer -> Adding signal for %d PROJ free spectator n",freeSpecNProj);
+ SpectatorSignal(2, freeSpecPProj, pm);
+// printf(" and %d free spectator p\n",freeSpecPProj);
+ SpectatorSignal(3, freeSpecNTarg, pm);
+// printf("\t AliZDCDigitizer -> Adding signal for %d TARG free spectator n",freeSpecNTarg);
+ SpectatorSignal(4, freeSpecPTarg, pm);
+// printf(" and %d free spectator p\n\n",freeSpecPTarg);
}
+
// get the output run loader and loader
AliRunLoader* runLoader =
AliRunLoader::GetRunLoader(fManager->GetOutputFolderName());
AliLoader* loader = runLoader->GetLoader("ZDCLoader");
- if (!loader) {
+ if(!loader) {
AliError("no ZDC loader found");
return;
}
// create the output tree
const char* mode = "update";
- if (runLoader->GetEventNumber() == 0) mode = "recreate";
+ if(runLoader->GetEventNumber() == 0) mode = "recreate";
loader->LoadDigits(mode);
loader->MakeTree("D");
TTree* treeD = loader->TreeD();
// Create digits
Int_t sector[2];
- Int_t digi[2];
- for (sector[0] = 1; sector[0] <= 3; sector[0]++)
- for (sector[1] = 0; sector[1] < 5; sector[1]++) {
- if ((sector[0] == 3) && ((sector[1] < 1) || (sector[1] > 2))) continue;
- for (Int_t res = 0; res < 2; res++){
- digi[res] = Phe2ADCch(sector[0], sector[1], pm[sector[0]-1][sector[1]], res)
+ Int_t digi[2], digioot[2];
+ for(sector[0]=1; sector[0]<6; sector[0]++){
+ for(sector[1]=0; sector[1]<5; sector[1]++){
+ if((sector[0]==3) && ((sector[1]<1) || (sector[1]>2))) continue;
+ for(Int_t res=0; res<2; res++){
+ digi[res] = Phe2ADCch(sector[0], sector[1], pm[sector[0]-1][sector[1]], res)
+ Pedestal(sector[0], sector[1], res);
- printf("\t DIGIT added -> det = %d, quad = %d - digi[%d] = %d\n\n",
- sector[0], sector[1], res, digi[res]); // Chiara debugging!
- }
- new(pdigit) AliZDCDigit(sector, digi);
+ }
+ new(pdigit) AliZDCDigit(sector, digi);
+ treeD->Fill();
+
+ //Ch. debug
+ //printf("\t DIGIT added -> det %d quad %d - digi[0,1] = [%d, %d]\n",
+ // sector[0], sector[1], digi[0], digi[1]); // Chiara debugging!
+
+ }
+ } // Loop over detector
+ // Adding in-time digits for 2 reference PTM signals (after signal ch.)
+ // (for the moment the ref. signal is completely invented assuming a PMgain of 5*10^4!)
+ Int_t sectorRef[2];
+ sectorRef[1] = 5;
+ Int_t sigRef[2];
+ // Reference signal are set to 100 (high gain chain) and 800 (low gain chain)
+ if(fIsCalibration==0) {sigRef[0]=100; sigRef[1]=800;}
+ else {sigRef[0]=0; sigRef[1]=0;} // calibration -> simulation of pedestal values
+ //
+ for(Int_t iref=0; iref<2; iref++){
+ sectorRef[0] = 3*iref+1;
+ for(Int_t res=0; res<2; res++){
+ sigRef[res] += Pedestal(sectorRef[0], sectorRef[1], res);
+ }
+ new(pdigit) AliZDCDigit(sectorRef, sigRef);
+ treeD->Fill();
+
+ //Ch. debug
+ //printf("\t RefDigit added -> det = %d, quad = %d - digi[0,1] = [%d, %d]\n",
+ // sectorRef[0], sectorRef[1], sigRef[0], sigRef[1]); // Chiara debugging!
+ }
+ //
+ // --- Adding digits for out-of-time channels after signal digits
+ for(sector[0]=1; sector[0]<6; sector[0]++){
+ for(sector[1]=0; sector[1]<5; sector[1]++){
+ if((sector[0]==3) && ((sector[1]<1) || (sector[1]>2))) continue;
+ for(Int_t res=0; res<2; res++){
+ digioot[res] = Pedestal(sector[0], sector[1], res); // out-of-time ADCs
+ }
+ new(pdigit) AliZDCDigit(sector, digioot);
treeD->Fill();
+
+ //Ch. debug
+ //printf("\t DIGIToot added -> det = %d, quad = %d - digi[0,1] = [%d, %d]\n",
+ // sector[0], sector[1], digioot[0], digioot[1]); // Chiara debugging!
}
+ }
+ // Adding out-of-time digits for 2 reference PTM signals (after out-of-time ch.)
+ Int_t sigRefoot[2];
+ for(Int_t iref=0; iref<2; iref++){
+ sectorRef[0] = 3*iref+1;
+ for(Int_t res=0; res<2; res++){
+ sigRefoot[res] = Pedestal(sectorRef[0], sectorRef[1], res);
+ }
+ new(pdigit) AliZDCDigit(sectorRef, sigRefoot);
+ treeD->Fill();
+ //Ch. debug
+ //printf("\t RefDigitoot added -> det = %d, quad = %d - digi[0,1] = [%d, %d]\n",
+ // sectorRef[0], sectorRef[1], sigRefoot[0], sigRefoot[1]); // Chiara debugging!
+
+ }
+ //printf("\t AliZDCDigitizer -> TreeD has %d entries\n",(Int_t) treeD->GetEntries());
// write the output tree
loader->WriteDigits("OVERWRITE");
{
// simulate fragmentation of spectators
- Int_t zz[100], nn[100];
AliZDCFragment frag(impPar);
- for (Int_t j=0; j<=99; j++){
- zz[j] =0;
- nn[j] =0;
- }
// Fragments generation
- Int_t nAlpha;
- frag.GenerateIMF(zz, nAlpha);
+ frag.GenerateIMF();
+ Int_t nAlpha = frag.GetNalpha();
// Attach neutrons
- Int_t ztot=0;
- Int_t ntot=0;
- frag.AttachNeutrons(zz, nn, ztot, ntot);
+ frag.AttachNeutrons();
+ Int_t ztot = frag.GetZtot();
+ Int_t ntot = frag.GetNtot();
+
+ // Removing fragments and alpha pcs
freeSpecN = specN-ntot-2*nAlpha;
freeSpecP = specP-ztot-2*nAlpha;
+
+ // Removing deuterons
+ Int_t ndeu = (Int_t) (freeSpecN*frag.DeuteronNumber());
+ freeSpecN -= ndeu;
+ freeSpecP -= ndeu;
+ //
if(freeSpecN<0) freeSpecN=0;
if(freeSpecP<0) freeSpecP=0;
AliDebug(2, Form("FreeSpn = %d, FreeSpp = %d", freeSpecN, freeSpecP));
//_____________________________________________________________________________
void AliZDCDigitizer::SpectatorSignal(Int_t SpecType, Int_t numEvents,
- Float_t pm[3][5]) const
+ Float_t pm[5][5]) const
{
// add signal of the spectators
-
- TFile* file = NULL;
- if (SpecType == 1) { // --- Signal for spectator neutrons
- file = TFile::Open("$ALICE/$ALICE_LEVEL/ZDC/ZNsignalntu.root");
- } else if (SpecType == 2) { // --- Signal for spectator protons
- file = TFile::Open("$ALICE/$ALICE_LEVEL/ZDC/ZPsignalntu.root");
- }
- if (!file || !file->IsOpen()) {
- AliError("Opening of file failed");
+
+ TFile *specSignalFile = TFile::Open("$ALICE_ROOT/ZDC/SpectatorSignal.root");
+ if(!specSignalFile || !specSignalFile->IsOpen()) {
+ AliError((" Opening file $ALICE_ROOT/ZDC/SpectatorSignal.root failed\n"));
return;
}
- TNtuple* zdcSignal = (TNtuple*) file->Get("ZDCSignal");
+ TNtuple* zdcSignal=0x0;
+
+ Float_t sqrtS = 2*fBeamEnergy;
+ //
+ if(TMath::Abs(sqrtS-5500) < 100.){
+ specSignalFile->cd("energy5500");
+ //
+ if(SpecType == 1) { // --- Signal for projectile spectator neutrons
+ specSignalFile->GetObject("energy5500/ZNCSignal;1",zdcSignal);
+ if(!zdcSignal) AliError(" PROBLEM!!! Can't retrieve ZNCSignal from SpectatorSignal.root file");
+ }
+ else if(SpecType == 2) { // --- Signal for projectile spectator protons
+ specSignalFile->GetObject("energy5500/ZPCSignal;1",zdcSignal);
+ if(!zdcSignal) AliError(" PROBLEM!!! Can't retrieve ZPCSignal from SpectatorSignal.root file");
+ }
+ else if(SpecType == 3) { // --- Signal for target spectator neutrons
+ specSignalFile->GetObject("energy5500/ZNASignal;1",zdcSignal);
+ if(!zdcSignal) AliError(" PROBLEM!!! Can't retrieve ZNASignal from SpectatorSignal.root file");
+ }
+ else if(SpecType == 4) { // --- Signal for target spectator protons
+ specSignalFile->GetObject("energy5500/ZPASignal;1",zdcSignal);
+ if(!zdcSignal) AliError(" PROBLEM!!! Can't retrieve ZPASignal from SpectatorSignal.root file");
+ }
+ }
+ else if(TMath::Abs(sqrtS-2760) < 100.){
+ specSignalFile->cd("energy2760");
+ //
+ if(SpecType == 1) { // --- Signal for projectile spectator neutrons
+ specSignalFile->GetObject("energy2760/ZNCSignal;1",zdcSignal);
+ if(!zdcSignal) AliError(" PROBLEM!!! Can't retrieve ZNCSignal from SpectatorSignal.root file");
+ }
+ else if(SpecType == 2) { // --- Signal for projectile spectator protons
+ specSignalFile->GetObject("energy2760/ZPCSignal;1",zdcSignal);
+ if(!zdcSignal) AliError(" PROBLEM!!! Can't retrieve ZPCSignal from SpectatorSignal.root file");
+ }
+ else if(SpecType == 3) { // --- Signal for target spectator neutrons
+ specSignalFile->GetObject("energy2760/ZNASignal;1",zdcSignal);
+ if(!zdcSignal) AliError(" PROBLEM!!! Can't retrieve ZNASignal from SpectatorSignal.root file");
+ }
+ else if(SpecType == 4) { // --- Signal for target spectator protons
+ specSignalFile->GetObject("energy2760/ZPASignal;1",zdcSignal);
+ if(!zdcSignal) AliError(" PROBLEM!!! Can't retrieve ZPASignal from SpectatorSignal.root file");
+ }
+ }
+
+ if(!zdcSignal){
+ printf("\n No spectator signal available for ZDC digitization\n");
+ return;
+ }
+
Int_t nentries = (Int_t) zdcSignal->GetEntries();
- Float_t *entry, hitsSpec[7];
- Int_t pl, i, j, k, iev=0, rnd[125], volume[2];
+ Float_t *entry;
+ Int_t pl, i, k, iev=0, rnd[125], volume[2];
for(pl=0;pl<125;pl++) rnd[pl] = 0;
- if (numEvents > 125) {
- AliWarning(Form("numEvents (%d) is larger than 125", numEvents));
+ if(numEvents > 125) {
+ AliDebug(2,Form("numEvents (%d) is larger than 125", numEvents));
numEvents = 125;
}
for(pl=0;pl<numEvents;pl++){
entry = zdcSignal->GetArgs();
if(entry[0] == rnd[iev]){
for(k=0; k<2; k++) volume[k] = (Int_t) entry[k+1];
- for(j=0; j<7; j++) hitsSpec[j] = entry[j+3];
//
- Float_t lightQ = hitsSpec[4];
- Float_t lightC = hitsSpec[5];
- AliDebug(3, Form("Volume = (%d, %d), lightQ = %.0f, lightC = %.0f",
- volume[0], volume[1], lightQ, lightC));
- //printf("\n Volume = (%d, %d), lightQ = %.0f, lightC = %.0f",
- // volume[0], volume[1], lightQ, lightC);
- if (volume[0] < 3) { // ZN or ZP
+ Float_t lightQ = entry[7];
+ Float_t lightC = entry[8];
+ //
+ if(volume[0] != 3) { // ZN or ZP
pm[volume[0]-1][0] += lightC;
pm[volume[0]-1][volume[1]] += lightQ;
//printf("\n pm[%d][0] = %.0f, pm[%d][%d] = %.0f\n",(volume[0]-1),pm[volume[0]-1][0],
// (volume[0]-1),volume[1],pm[volume[0]-1][volume[1]]);
}
else {
- if (volume[1] == 1) pm[2][1] += lightC; // ZEM 1
- else pm[2][2] += lightQ; // ZEM 2
+ if(volume[1] == 1) pm[2][1] += lightC; // ZEM 1
+ else pm[2][2] += lightQ; // ZEM 2
//printf("\n pm[2][1] = %.0f, pm[2][2] = %.0f\n",pm[2][1],pm[2][2]);
}
}
}
}while(iev<numEvents);
- file->Close();
- delete file;
+ specSignalFile->Close();
+ delete specSignalFile;
}
Int_t Res) const
{
// Evaluation of the ADC channel corresponding to the light yield Light
- Int_t ADCch = (Int_t) (Light * fPMGain[Det-1][Quad] * fADCRes[Res]);
- printf("\t Phe2ADCch -> det %d quad %d - phe %.0f ADC %d\n", Det,Quad,Light,ADCch);
- return ADCch;
+ Int_t vADCch = (Int_t) (Light * fPMGain[Det-1][Quad] * fADCRes[Res]);
+ // Ch. debug
+ //printf("\t Phe2ADCch -> det %d quad %d - PMGain[%d][%d] %1.0f phe %1.2f ADC %d\n",
+ // Det,Quad,Det-1,Quad,fPMGain[Det-1][Quad],Light,vADCch);
+
+ return vADCch;
}
//_____________________________________________________________________________
Int_t AliZDCDigitizer::Pedestal(Int_t Det, Int_t Quad, Int_t Res) const
{
- // Get calibration data
- int runNumber = 0;
- AliZDCCalibData *calibda = GetCalibData(runNumber);
- //calibda->Print("");
-
- Float_t meanPed;
- if(Det != 3) meanPed = calibda->GetMeanPed(10*(Det-1)+Quad+5*Res);
- else meanPed = calibda->GetMeanPed(10*(Det-1)+Quad+1*Res);
-
- printf("\t Pedestal -> det = %d, quad = %d, res = %d - Ped[%d] = %d\n",
- Det, Quad, Res,10*(Det-1)+Quad+5*Res,(Int_t) meanPed); // Chiara debugging!
-
- return (Int_t) meanPed;
+ // Returns a pedestal for detector det, PM quad, channel with res.
+ //
+ Float_t pedValue;
+ // Normal run
+ if(fIsCalibration == 0){
+ Int_t index=0, kNch=24;
+ if(Quad!=5){
+ if(Det==1) index = Quad+kNch*Res; // ZNC
+ else if(Det==2) index = (Quad+5)+kNch*Res; // ZPC
+ else if(Det==3) index = (Quad+9)+kNch*Res; // ZEM
+ else if(Det==4) index = (Quad+12)+kNch*Res; // ZNA
+ else if(Det==5) index = (Quad+17)+kNch*Res; // ZPA
+ }
+ else index = (Det-1)/3+22+kNch*Res; // Reference PMs
+ //
+ Float_t meanPed = fPedData->GetMeanPed(index);
+ Float_t pedWidth = fPedData->GetMeanPedWidth(index);
+ pedValue = gRandom->Gaus(meanPed,pedWidth);
+ //
+ /*printf("\t AliZDCDigitizer::Pedestal -> det %d quad %d res %d - Ped[%d] = %d\n",
+ Det, Quad, Res, index,(Int_t) pedValue); // Chiara debugging!
+ */
+ }
+ // To create calibration object
+ else{
+ if(Res == 0) pedValue = gRandom->Gaus((35.+10.*gRandom->Rndm()),(0.5+0.2*gRandom->Rndm())); //High gain
+ else pedValue = gRandom->Gaus((250.+100.*gRandom->Rndm()),(3.5+2.*gRandom->Rndm())); //Low gain
+ }
+
+ return (Int_t) pedValue;
}
//_____________________________________________________________________________
-AliZDCCalibData* AliZDCDigitizer::GetCalibData(int runNumber) const
+AliCDBStorage* AliZDCDigitizer::SetStorage(const char *uri)
{
- printf("\t AliZDCReconstructor::GetCalibData for RUN #%d\n",runNumber);
- //fStorage->PrintSelectionList();
- //AliCDBEntry *entry = fStorage->Get("ZDC/Calib/Data",runNumber);
+ Bool_t deleteManager = kFALSE;
- AliCDBStorage *fStorage = AliCDBManager::Instance()->GetStorage("local://$ALICE_ROOT");
- AliCDBEntry *entry = fStorage->Get("ZDC/Calib/Data",0);
+ AliCDBManager *manager = AliCDBManager::Instance();
+ AliCDBStorage *defstorage = manager->GetDefaultStorage();
- AliZDCCalibData *calibda = (AliZDCCalibData*) entry->GetObject();
- //calibda->Print("");
+ if(!defstorage || !(defstorage->Contains("ZDC"))){
+ AliWarning("No default storage set or default storage doesn't contain ZDC!");
+ manager->SetDefaultStorage(uri);
+ deleteManager = kTRUE;
+ }
+
+ AliCDBStorage *storage = manager->GetDefaultStorage();
+
+ if(deleteManager){
+ AliCDBManager::Instance()->UnsetDefaultStorage();
+ defstorage = 0; // the storage is killed by AliCDBManager::Instance()->Destroy()
+ }
+
+ return storage;
+}
- // AliCDBManager::Instance()->Destroy();
+//_____________________________________________________________________________
+AliZDCPedestals* AliZDCDigitizer::GetPedData() const
+{
+
+ // Getting pedestal calibration object for ZDC set
- return calibda;
+ AliCDBEntry *entry = AliCDBManager::Instance()->Get("ZDC/Calib/Pedestals");
+ if(!entry) AliFatal("No calibration data loaded!");
+ AliZDCPedestals *calibdata = dynamic_cast<AliZDCPedestals*> (entry->GetObject());
+ if(!calibdata) AliFatal("Wrong calibration object in calibration file!");
+
+ return calibdata;
}
+
git://git.uio.no / u / mrichter / AliRoot.git / blobdiff