*/
#define PEDDATA_FILE "ZDCPedestal.dat"
#define MAPDATA_FILE "ZDCChMapping.dat"
+#define ENCALIBDATA_FILE "ZDCEnergyCalib.dat"
#define MBCALIBDATA_FILE "ZDCMBCalib.root"
#include <stdio.h>
int const kNModules = 10;
int const kNChannels = 24;
int const kNScChannels = 32;
- Int_t kFirstADCGeo=0, kLastADCGeo=3;
+ Int_t kFirstADCGeo=0, kLastADCGeo=1;
Int_t iMod=-1;
Int_t modGeo[kNModules], modType[kNModules],modNCh[kNModules];
for(Int_t y=0; y<kNScChannels; y++){
scMod[y]=scCh[y]=scSigCode[y]=scDet[y]=scSec[y]=0;
}
+
+ Int_t itdcCh=0;
+ Int_t tdcMod[kNScChannels], tdcCh[kNScChannels], tdcSigCode[kNScChannels];
+ Int_t tdcDet[kNScChannels], tdcSec[kNScChannels];
+ for(Int_t y=0; y<kNScChannels; y++){
+ tdcMod[y]=tdcCh[y]=tdcSigCode[y]=tdcDet[y]=tdcSec[y]=-1;
+ }
/* log start of process */
printf("ZDC EMD program started\n");
// --- Preparing histos for EM dissociation spectra
//
- TH2F * hZDCvsZEM = new TH2F("hZDCvsZEM","EZDCTot vs. EZEM",100,0.,5.,100,0.,800.);
- TH2F * hZDCCvsZEM = new TH2F("hZDCCvsZEM","EZDCC vs. EZEM",100,0.,5.,100,0.,400.);
- TH2F * hZDCAvsZEM = new TH2F("hZDCAvsZEM","EZDCA vs. EZEM",100,0.,5.,100,0.,400.);
+ TH2F * hZDCvsZEM = new TH2F("hZDCvsZEM","EZDCTot vs. EZEM",100,0.,8.,100,0.,800.);
+ TH2F * hZDCCvsZEM = new TH2F("hZDCCvsZEM","EZDCC vs. EZEM",100,0.,8.,100,0.,400.);
+ TH2F * hZDCAvsZEM = new TH2F("hZDCAvsZEM","EZDCA vs. EZEM",100,0.,8.,100,0.,400.);
/* open result file */
FILE *fp=NULL;
/* report progress */
daqDA_progressReport(10);
-
+
+ FILE *fileEnCal = fopen(ENCALIBDATA_FILE,"r");
+ if(fileEnCal==NULL) {
+ printf("\t ERROR!!! Can't open ZDCEnergyCalib.dat file!!!\n");
+ return -1;
+ }
+
+ Float_t calibCoeff[6];
+ for(Int_t irow=0; irow<6; irow++){
+ fscanf(fileEnCal,"%f",&calibCoeff[irow]);
+ }
/* init some counters */
int nevents_physics=0;
scSec[iScCh] = rawStreamZDC->GetScTowerFromMap(iScCh);
iScCh++;
}
+ else if(modType[iMod]==6 && modGeo[iMod]==4){ // ZDC TDC mapping --------------------
+ tdcMod[itdcCh] = rawStreamZDC->GetTDCModFromMap(itdcCh);
+ tdcCh[itdcCh] = rawStreamZDC->GetTDCChFromMap(itdcCh);
+ tdcSigCode[itdcCh] = rawStreamZDC->GetTDCSignFromMap(itdcCh);
+ itdcCh++;
+ }
}
}
// Writing data on output FXS file
//printf(" CalibMB DA -> %d Scaler: mod %d ch %d, code %d det %d, sec %d\n",
// is,scMod[is],scCh[is],scSigCode[is],scDet[is],scSec[is]);
}
+ for(Int_t is=0; is<kNScChannels; is++){
+ fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\t%d\n",
+ is,tdcMod[is],tdcCh[is],tdcSigCode[is]);
+ //if(tdcMod[is]!=-1) printf(" Mapping DA -> %d TDC: mod %d ch %d, code %d\n",
+ // is,tdcMod[is],tdcCh[is],tdcSigCode[is]);
+ }
for(Int_t is=0; is<kNModules; is++){
fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\n",
modGeo[is],modType[is],modNCh[is]);
if(header){
UChar_t message = header->GetAttributes();
if((message & 0xf0) == 0x60){ // DEDICATED CALIBRATION MB RUN
- //printf("\t STANDALONE_CALIBRAION_MB_RUN raw data found\n");
+ //printf("\t CALIBRATION_MB_RUN raw data found\n");
continue;
}
else{
- printf("\t NO STANDALONE_MB_RUN raw data found\n");
- return -1;
+ //printf("\t NO CALIBRAION_MB_RUN raw data found\n");
+ //return -1;
}
}
else{
rawStreamZDC->SetMapTow(jk, sec[jk]);
}
//
- Float_t rawZDC=0., rawZEM=0.;
- Float_t corrZDC=0., corrZEM=0.;
- Float_t corrZDCTot=0., corrZDCC=0., corrZDCA=0., corrZEMTot=0.;
+ Float_t rawZNC=0., rawZPC=0., rawZNA=0., rawZPA=0., rawZEM1=0., rawZEM2=0.;
+ Float_t corrZNC=0., corrZPC=0., corrZNA=0., corrZPA=0., corrZEM1=0.,corrZEM2=0.;
+ Float_t calZNC=0., calZPC=0., calZNA=0., calZPA=0., calZEM1=0., calZEM2=0.;
+ Float_t calZDCTot=0., calZDCC=0., calZDCA=0., calZEM=0.;
//
while(rawStreamZDC->Next()){
Int_t detector = rawStreamZDC->GetSector(0);
//
if(index!=-1 && quad!=5){
//
- if(detector==3){
- rawZEM = (Float_t) rawStreamZDC->GetADCValue();
- corrZEM = (rawStreamZDC->GetADCValue()) - Pedestal;
- corrZEMTot += corrZEM;
+ if(detector==1){
+ rawZNC = (Float_t) rawStreamZDC->GetADCValue();
+ corrZNC = rawZNC - Pedestal;
}
- else{
- rawZDC = (Float_t) rawStreamZDC->GetADCValue();
- corrZDC = rawZDC - Pedestal;
- if(detector==1 || detector==2) corrZDCC += corrZDC;
- else corrZDCA += corrZDC;
- corrZDCTot += corrZDC;
+ else if(detector==2){
+ rawZPC = (Float_t) rawStreamZDC->GetADCValue();
+ corrZPC = rawZPC - Pedestal;
+ }
+ else if(detector==3){
+ if(quad==1){
+ rawZEM1 = (Float_t) rawStreamZDC->GetADCValue();
+ corrZEM1 = (rawStreamZDC->GetADCValue()) - Pedestal;
+ }
+ else{
+ rawZEM2 = (Float_t) rawStreamZDC->GetADCValue();
+ corrZEM2 = (rawStreamZDC->GetADCValue()) - Pedestal;
+ }
+ }
+ else if(detector==4){
+ rawZNA = (Float_t) rawStreamZDC->GetADCValue();
+ corrZNA = rawZNA - Pedestal;
+ }
+ else if(detector==5){
+ rawZPA = (Float_t) rawStreamZDC->GetADCValue();
+ corrZPA = rawZPA - Pedestal;
}
}
}//IsADCDataWord()
} // Next()
-
- hZDCvsZEM ->Fill(corrZDCTot, corrZEMTot);
- hZDCCvsZEM->Fill(corrZDCC, corrZEMTot);
- hZDCAvsZEM->Fill(corrZDCA, corrZEMTot);
+
+ calZNC = calibCoeff[0]*corrZNC;
+ calZPC = calibCoeff[1]*corrZPC;
+ calZNA = calibCoeff[2]*corrZNA;
+ calZPA = calibCoeff[3]*corrZPA;
+ calZEM1 = calibCoeff[4]*corrZEM1;
+ calZEM2 = calibCoeff[4]*corrZEM2;
+ calZDCTot = calZNC+calZPC+calZPA+calZNA;
+ calZDCC = calZNC+calZPC;
+ calZDCA = calZNA+calZPA;
+ calZEM = calZEM1+calZEM2;
+ //
+ hZDCvsZEM ->Fill(calZDCTot/1000, calZEM/1000);
+ hZDCCvsZEM->Fill(calZDCC/1000, calZEM/1000);
+ hZDCAvsZEM->Fill(calZDCA/1000, calZEM/1000);
nevents_physics++;
}//(if PHYSICS_EVENT)