#include "AliHMPIDPreprocessor.h" //header no includes #include "AliHMPIDDigit.h" //ProcPed() #include "AliHMPIDRawStream.h" //ProcPed() #include //ProcPed() #include //all #include //ProcPed(), ProcDcs() #include //ProcDcs() #include //ProcDcs(), ProcPed() #include //Initialize() #include //Process() #include //Process() #include #include //Process() #include //ProcPed() #include //ProcPed() #include //ProcPed() //. // HMPID Preprocessor base class //. //. //. using std::hex; using std::ifstream; using std::dec; ClassImp(AliHMPIDPreprocessor) //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ void AliHMPIDPreprocessor::Initialize(Int_t run, UInt_t startTime,UInt_t endTime) { // Initialize the parameter coming from AliPreprocessor // run -> run number // startTime -> starting time // endTime -> ending time AliPreprocessor::Initialize(run, startTime, endTime); AliInfo(Form("HMPID started for Run %d \n\tStartTime %s \n\t EndTime %s", run,TTimeStamp(startTime).AsString(),TTimeStamp(endTime).AsString())); } //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ UInt_t AliHMPIDPreprocessor::Process(TMap* pMap) { // Process all information from DCS and DAQ // Arguments: pMap- map of DCS aliases // Returns: 0 on success or 1 on error (opposite to Store!) TString runType = GetRunType(); Log(Form(" AliHMPIDPreprocessor: RunType is %s",runType.Data())); Bool_t statusNoise=kFALSE, statusDcs=kFALSE; // start to check event type and procedures Log("HMPID - Process in Preprocessor started"); if(! pMap) { Log("HMPID - ERROR - Not map of DCS aliases for HMPID - "); return kTRUE; // error in the DCS mapped aliases } if (runType == "CALIBRATION"){ if (!ProcPed()){ Log("HMPID - ERROR - Pedestal processing failed!!"); return kTRUE; // error in pedestal processing } else { Log("HMPID - Pedestal processing successful!!"); return kFALSE; // ok for pedestals } }//CALIBRATION else if ( runType=="STANDALONE" || runType=="PHYSICS"){ statusDcs=ProcDcs(pMap); statusNoise=ProcNoiseMap(); if(!statusDcs || !statusNoise) { Log(Form("HMPID - ERROR - Noise Map(%d) and/or DCS(%d) processing failed!! (0=OK, 1=FAILED)",statusNoise,statusDcs)); return kTRUE; } // error in Noise Map or DCS processing else { Log("HMPID - Noise Map and DCS processing successful!!"); return kFALSE;} // ok }//STANDALONE or PHYSICS run else { Log("HMPID - Nothing to do with preprocessor for HMPID, bye!"); return kFALSE; // ok - nothing done } }//Process() //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Bool_t AliHMPIDPreprocessor::ProcNoiseMap() { // // Goal: Process the Noise Map created by the HMP Physics DA to mask // noisy channels from reconstruction and follow changes in accepatnce // eg. DDL turn on/off after PEDESTAL run and between PHYSICS runs. // Returns kFALSE on success Bool_t stProcNoise=kFALSE; TFile *fNoiseFile; TH2F *hNoiseMap = 0x0; TList *pNoiseSource=GetFileSources(kDAQ,"HmpPhysicsDaNoiseMap.root"); //get list of DAQ source names containing id "HmpPhysicsDaNoiseMap" --> defined in HMPIDphysda.cxx if(!pNoiseSource) {Log(Form("ERROR: Retrieval of sources for noise map: HmpPhysicsDaNoiseMap.root is failed!")); return stProcNoise;} if(!(TObjString*)pNoiseSource->At(0)) {Log(Form("ERROR: empty list received from DAQ Source!")); return stProcNoise;} TString noiseFile = GetFile(kDAQ,Form("HmpPhysicsDaNoiseMap.root"),((TObjString*)pNoiseSource->At(0))->GetName()); if(noiseFile.Length()==0) {Log(Form("ERROR retrieving noise map file: HmpPhysicsDaNoiseMap.root")); return stProcNoise;} fNoiseFile = TFile::Open(noiseFile.Data(),"read"); if(!fNoiseFile) {Log(Form("ERROR cannot open NoiseFile: %s!",noiseFile.Data())); return stProcNoise;} hNoiseMap = (TH2F*) fNoiseFile->Get("hHmpNoiseMaps"); AliCDBMetaData metaDataHisto; metaDataHisto.SetBeamPeriod(0); metaDataHisto.SetResponsible("AliHMPIDPreprocessor"); metaDataHisto.SetComment("AliHMPIDPreprocessor stores the Noise Map object as Reference Data."); AliInfo("Storing Reference Data"); stProcNoise = Store("Calib","NoiseMap",hNoiseMap,&metaDataHisto,0,kTRUE); if(!stProcNoise) { Log("HMPID - failure to store Noise Map data results in OCDB"); } return stProcNoise; }//ProcNoiseMap //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Bool_t AliHMPIDPreprocessor::ProcDcs(TMap* pMap) { // Process: 1 (old). inlet and outlet C6F14 temperature, stores TObjArray of 21 TF1, where TF1 is Nmean=f(t), one per radiator // Process: 1. inlet and outlet C6F14 temperature, stores TObjArray of 42 TF1, where TF1 are Tin and Tout per radiator // + one function for the mean energy photon (in total 43). // 2. CH4 pressure and HV stores TObjArray of 7 TF1 where TF1 is thr=f(t), one per chamber // Arguments: pDcsMap - map of structure "alias name" - TObjArray of AliDCSValue // Assume that: HV is the same during the run for a given chamber, different chambers might have different HV // P=f(t), different for different chambers // Returns: kTRUE on success Bool_t stDcsStore=kFALSE; // Qthr=f(HV,P) [V,mBar] logA0=k*HV+b is taken from p. 64 TDR plot 2.59 for PC32 // A0=f(P) is taken from DiMauro mail // Qthr is estimated as 3*A0 TF2 thr("RthrCH4" ,"3*10^(3.01e-3*x-4.72)+170745848*exp(-y*0.0162012)" ,2000,3000,900,1200); TObjArray arNmean(43); arNmean.SetOwner(kTRUE); //42 Tin and Tout one per radiator + 1 for ePhotMean TObjArray arQthre(42); arQthre.SetOwner(kTRUE); //42 Qthre=f(time) one per sector AliDCSValue *pVal; Int_t cnt=0; Double_t xP,yP; // TF1 **pTin = new TF1*[21]; // TF1 **pTout = new TF1*[21]; TF1 *pTin[21]; TF1 *pTout[21]; // evaluate Environment Pressure TObjArray *pPenv=(TObjArray*)pMap->GetValue("HMP_DET/HMP_ENV/HMP_ENV_PENV.actual.value"); if(!pPenv) { AliWarning(" No Data Points from HMP_ENV_PENV.actual.value!"); return kFALSE; } else { Log(Form(" Environment Pressure data ---> %3i entries",pPenv->GetEntries())); if(pPenv->GetEntries()) { TIter nextPenv(pPenv); TGraph *pGrPenv=new TGraph; cnt=0; while((pVal=(AliDCSValue*)nextPenv())) pGrPenv->SetPoint(cnt++,pVal->GetTimeStamp(),pVal->GetFloat()); //P env if( cnt==1) { pGrPenv->GetPoint(0,xP,yP); new TF1("Penv",Form("%f",yP),fStartTime,fEndTime); } else { pGrPenv->Fit(new TF1("Penv","1000+x*[0]",fStartTime,fEndTime),"Q"); } delete pGrPenv; } else {AliWarning(" No Data Points from HMP_ENV_PENV.actual.value!");return kFALSE;} } // evaluate Pressure for(Int_t iCh=0;iCh<7;iCh++){ TObjArray *pP =(TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_MP%i/HMP_MP%i_GAS/HMP_MP%i_GAS_PMWPC.actual.value",iCh,iCh,iCh)); if(!pP) { AliWarning(Form(" No Data Points from HMP_MP%1i_GAS_PMWPC.actual.value!",iCh)); return kFALSE; } else { Log(Form(" Pressure for module %i data ---> %3i entries",iCh,pP->GetEntries())); if(pP->GetEntries()) { TIter nextP(pP); TGraph *pGrP=new TGraph; cnt=0; while((pVal=(AliDCSValue*)nextP())) pGrP->SetPoint(cnt++,pVal->GetTimeStamp(),pVal->GetFloat()); //P if( cnt==1) { pGrP->GetPoint(0,xP,yP); new TF1(Form("P%i",iCh),Form("%f",yP),fStartTime,fEndTime); } else { pGrP->Fit(new TF1(Form("P%i",iCh),"[0] + x*[1]",fStartTime,fEndTime),"Q"); } delete pGrP; } else {AliWarning(" No Data Points from HMP_MP0-6_GAS_PMWPC.actual.value!");return kFALSE;} } // evaluate High Voltage for(Int_t iSec=0;iSec<6;iSec++){ TObjArray *pHV=(TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_MP%i/HMP_MP%i_PW/HMP_MP%i_SEC%i/HMP_MP%i_SEC%i_HV.actual.vMon",iCh,iCh,iCh,iSec,iCh,iSec)); if(!pHV) { AliWarning(Form(" No Data Points from HMP_MP%1i_SEC%1i_HV.actual.vMon!",iCh,iSec)); return kFALSE; } else { Log(Form(" HV for module %i and secto %i data ---> %3i entries",iCh,iSec,pHV->GetEntries())); if(pHV->GetEntries()) { TIter nextHV(pHV); TGraph *pGrHV=new TGraph; cnt=0; while((pVal=(AliDCSValue*)nextHV())) pGrHV->SetPoint(cnt++,pVal->GetTimeStamp(),pVal->GetFloat()); //HV if( cnt==1) { pGrHV->GetPoint(0,xP,yP); new TF1(Form("HV%i_%i",iCh,iSec),Form("%f",yP),fStartTime,fEndTime); } else { pGrHV->Fit(new TF1(Form("HV%i_%i",iCh,iSec),"[0]+x*[1]",fStartTime,fEndTime),"Q"); } delete pGrHV; } else {AliWarning(" No Data Points from HMP_MP0-6_SEC0-5_HV.actual.vMon!");return kFALSE;} } // evaluate Qthre arQthre.AddAt(new TF1(Form("HMP_QthreC%iS%i",iCh,iSec), Form("3*10^(3.01e-3*HV%i_%i - 4.72)+170745848*exp(-(P%i+Penv)*0.0162012)",iCh,iSec,iCh),fStartTime,fEndTime),6*iCh+iSec); //arQthre.AddAt(new TF1(Form("HMP_QthreC%iS%i",iCh,iSec),"100",fStartTime,fEndTime),6*iCh+iSec); } // evaluate Temperatures: in and out of the radiators // T in for(Int_t iRad=0;iRad<3;iRad++){ pTin[3*iCh+iRad] = new TF1(Form("Tin%i%i" ,iCh,iRad),"[0]+[1]*x",fStartTime,fEndTime); pTout[3*iCh+iRad] = new TF1(Form("Tout%i%i",iCh,iRad),"[0]+[1]*x",fStartTime,fEndTime); //pTin[3*iCh+iRad] = new TF1(Form("Tin%i%i" ,iCh,iRad),"21",fStartTime,fEndTime); //pTout[3*iCh+iRad] = new TF1(Form("Tout%i%i",iCh,iRad),"22",fStartTime,fEndTime); TObjArray *pT1=(TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_MP%i/HMP_MP%i_LIQ_LOOP.actual.sensors.Rad%iIn_Temp",iCh,iCh,iRad)); if(!pT1) { AliWarning(Form(" No Data Points from HMP_MP%1i_LIQ_LOOP.actual.sensors.Rad%1iIn_Temp!",iCh,iRad)); return kFALSE; } else { Log(Form(" Temperatures for module %i inside data ---> %3i entries",iCh,pT1->GetEntries())); if(pT1->GetEntries()) { TIter nextT1(pT1);//Tin TGraph *pGrT1=new TGraph; cnt=0; while((pVal=(AliDCSValue*)nextT1())) pGrT1->SetPoint(cnt++,pVal->GetTimeStamp(),pVal->GetFloat()); //T inlet if(cnt==1) { pGrT1->GetPoint(0,xP,yP); pTin[3*iCh+iRad]->SetParameter(0,yP); pTin[3*iCh+iRad]->SetParameter(1,0); } else { pGrT1->Fit(pTin[3*iCh+iRad],"Q"); } delete pGrT1; } else {AliWarning(" No Data Points from HMP_MP0-6_LIQ_LOOP.actual.sensors.Rad0-2In_Temp!");return kFALSE;} } // T out TObjArray *pT2=(TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_MP%i/HMP_MP%i_LIQ_LOOP.actual.sensors.Rad%iOut_Temp",iCh,iCh,iRad)); if(!pT2) { AliWarning(Form(" No Data Points from HMP_MP%1i_LIQ_LOOP.actual.sensors.Rad%1iOut_Temp!",iCh,iRad)); return kFALSE; } else { Log(Form(" Temperatures for module %i outside data ---> %3i entries",iCh,pT2->GetEntries())); if(pT2->GetEntries()) { TIter nextT2(pT2);//Tout TGraph *pGrT2=new TGraph; cnt=0; while((pVal=(AliDCSValue*)nextT2())) pGrT2->SetPoint(cnt++,pVal->GetTimeStamp(),pVal->GetFloat()); //T outlet if(cnt==1) { pGrT2->GetPoint(0,xP,yP); pTout[3*iCh+iRad]->SetParameter(0,yP); pTout[3*iCh+iRad]->SetParameter(1,0); } else { pGrT2->Fit(pTout[3*iCh+iRad],"Q"); } delete pGrT2; } else {AliWarning(" No Data Points from HMP_MP0-6_LIQ_LOOP.actual.sensors.Rad0-2Out_Temp!");return kFALSE;} } // evaluate Mean Refractive Index arNmean.AddAt(pTin[3*iCh+iRad] ,6*iCh+2*iRad ); //Tin =f(t) arNmean.AddAt(pTout[3*iCh+iRad],6*iCh+2*iRad+1); //Tout=f(t) }//radiators loop }//chambers loop Double_t eMean = ProcTrans(pMap); arNmean.AddAt(new TF1("HMP_PhotEmean",Form("%f",eMean),fStartTime,fEndTime),42); //Photon energy mean AliCDBMetaData metaData; metaData.SetBeamPeriod(0); metaData.SetResponsible("AliHMPIDPreprocessor"); metaData.SetComment("HMPID preprocessor fills TObjArrays."); stDcsStore = Store("Calib","Qthre",&arQthre,&metaData,0,kTRUE) && // from DCS 0,kTRUE generates the file from Run 0 to Run 99999999 Store("Calib","Nmean",&arNmean,&metaData,0,kTRUE); // from DCS // stDcsStore = Store("Calib","Qthre",&arQthre,&metaData) && // from DCS // Store("Calib","Nmean",&arNmean,&metaData); // from DCS if(!stDcsStore) { Log("HMPID - failure to store DCS data results in OCDB"); } // arNmean.Delete(); // arQthre.Delete(); // for(Int_t i=0;i<21;i++) delete pTin[i]; delete []pTin; // for(Int_t i=0;i<21;i++) delete pTout[i]; delete []pTout; return stDcsStore; }//Process() //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Bool_t AliHMPIDPreprocessor::ProcPed() { // Process pedestal files and create 7 M(padx,pady)=sigma, one for each chamber // Arguments: // Returns: kTRUE on success Bool_t stPedStore=kFALSE; Bool_t stDeadMaskedStore=kFALSE; AliHMPIDDigit dig; AliHMPIDRawStream rs; Int_t nSigCut,r,d,a,hard; Float_t mean,sigma; Int_t runNumber,ldcId,timeStamp,nEv,nDdlEv,nBadEv; Char_t tName[10]; Float_t nBadEvPer; TObjArray aDaqSig(7); aDaqSig.SetOwner(kTRUE); for(Int_t i=0;i<7;i++) aDaqSig.AddAt(new TMatrix(160,144),i); //TObjArray of 7 TMatrixF, m(padx,pady)=sigma TObjArray aDeadMasked(7); aDeadMasked.SetOwner(kTRUE); for(Int_t i=0;i<7;i++) aDeadMasked.AddAt(new TMatrix(160,144),i); //TObjArray of 7 TMatrixF, m(padx,pady)=pedestal for(Int_t iddl=0;iddlLDC connection { TList *pLdc=GetFileSources(kDAQ,Form("HmpidPedDdl%02i.txt",iddl)); //get list of LDC names containing id "pedestals" if(!pLdc) {Log(Form("ERROR: Retrieval of sources for pedestals: HmpidPedDdl%02i.txt failed!",iddl));continue;} Log(Form("HMPID - Pedestal files to be read --> %i LDCs for HMPID",pLdc->GetEntries())); for(Int_t i=0;iGetEntries();i++) {//lists of LDCs -- but in general we have 1 LDC for 1 ped file TString fileName = GetFile(kDAQ,Form("HmpidPedDdl%02i.txt",iddl),((TObjString*)pLdc->At(i))->GetName()); if(fileName.Length()==0) {Log(Form("ERROR retrieving pedestal file: HmpidPedDdl%02i.txt!",iddl));continue;} //reading pedestal file ifstream infile(fileName.Data()); if(!infile.is_open()) {Log("No pedestal file found for HMPID,bye!");continue;} TMatrix *pM=(TMatrixF*)aDaqSig.At(iddl/2); TMatrix *pDM=(TMatrixF*)aDeadMasked.At(iddl/2); infile>>tName>>runNumber;Printf("Xcheck: reading run %i",runNumber); infile>>tName>>ldcId; infile>>tName>>timeStamp; infile>>tName>>nEv; infile>>tName>>nDdlEv; infile>>tName>>nBadEv; infile>>tName>>nBadEvPer; infile>>tName>>nSigCut; pM->SetUniqueID(nSigCut); //n. of pedestal distribution sigmas used to create zero suppresion table while(!infile.eof()){ infile>>dec>>r>>d>>a>>mean>>sigma>>hex>>hard; if(rs.GetPad(iddl,r,d,a)>=0){ //the GetPad returns meaningful abs pad number dig.SetPad(rs.GetPad(iddl,r,d,a)); dig.SetQ((Int_t)mean); (*pM)(dig.PadChX(),dig.PadChY()) = sigma; if( (mean == AliHMPIDParam::kPadMeanZeroCharge && sigma == AliHMPIDParam::kPadSigmaZeroCharge) || (mean == AliHMPIDParam::kPadMeanMasked && sigma == AliHMPIDParam::kPadSigmaMasked) ) {(*pDM)(dig.PadChX(),dig.PadChY()) = mean;} } } infile.close(); Log(Form("Pedestal file for DDL %i read successfully",iddl)); }//LDCs reading entries }//DDL AliCDBMetaData metaData; metaData.SetBeamPeriod(0); metaData.SetResponsible("AliHMPIDPreprocessor"); metaData.SetComment("HMPID processor fills TObjArrays."); stPedStore = Store("Calib","DaqSig",&aDaqSig,&metaData,0,kTRUE); if(!stPedStore) { Log("HMPID - failure to store PEDESTAL data results in OCDB"); } stDeadMaskedStore = Store("Calib","Masked",&aDeadMasked,&metaData,0,kTRUE); if(!stDeadMaskedStore) { Log("HMPID - failure to store DEAD & MASKED channel map in OCDB"); } Bool_t pedRes=stPedStore*stDeadMaskedStore; return pedRes; }//ProcPed() //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Double_t AliHMPIDPreprocessor::ProcTrans(TMap* pMap) { // Process transparency monitoring data and calculates Emean Double_t sEnergProb=0, sProb=0; // Double_t tRefCR5 = 19. ; // mean temperature of CR5 where the system is in place Double_t eMean = 0; AliDCSValue *pVal; Double_t aCorrFactor[] = {0.937575212,0.93805688,0.938527113,0.938986068,0.939433897,0.939870746,0.940296755,0.94071206,0.941116795,0.941511085,0.941895054,0.942268821,0.942632502, 0.942986208,0.943330047,0.943664126,0.943988544,0.944303401,0.944608794,0.944904814,0.945191552,0.945469097,0.945737533,0.945996945,0.946247412, 0.946489015,0.94672183,0.946945933,0.947161396,0.947368291}; for(Int_t i=0; i<30; i++){ // evaluate wavelenght TObjArray *pWaveLenght = (TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.waveLenght",i)); if(!pWaveLenght){ AliWarning(Form("No Data Point values for HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.waveLenght -----> Default E mean used!!!!!",i)); return DefaultEMean(); // to be checked } pVal=(AliDCSValue*)pWaveLenght->At(0); Double_t lambda = pVal->GetFloat(); if(lambda<150. || lambda>230.){ AliWarning(Form("Wrong value for HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.waveLenght -----> Default E mean used!!!!!",i)); return DefaultEMean(); // to be checked } Double_t photEn = 1239.842609/lambda; // 1239.842609 from nm to eV if(photEnAliHMPIDParam::EPhotMax()) continue; // evaluate phototube current for argon reference TObjArray *pArgonRef = (TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.argonReference",i)); if(!pArgonRef){ AliWarning(Form("No Data Point values for HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.argonReference -----> Default E mean used!!!!!",i)); return DefaultEMean(); // to be checked } pVal=(AliDCSValue*)pArgonRef->At(0); Double_t aRefArgon = pVal->GetFloat(); // evaluate phototube current for argon cell TObjArray *pArgonCell = (TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.argonCell",i)); if(!pArgonCell){ AliWarning(Form("No Data Point values for HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.argonCell -----> Default E mean used!!!!!",i)); return DefaultEMean(); // to be checked } pVal=(AliDCSValue*)pArgonRef->At(0); Double_t aCellArgon = pVal->GetFloat(); //evaluate phototube current for freon reference TObjArray *pFreonRef = (TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.c6f14Reference",i)); if(!pFreonRef){ AliWarning(Form("No Data Point values for HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.c6f14Reference -----> Default E mean used!!!!!",i)); return DefaultEMean(); // to be checked } pVal=(AliDCSValue*)pFreonRef->At(0); Double_t aRefFreon = pVal->GetFloat(); //evaluate phototube current for freon cell TObjArray *pFreonCell = (TObjArray*)pMap->GetValue(Form("HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.c6f14Cell",i)); if(!pFreonCell){ AliWarning(Form("No Data Point values for HMP_DET/HMP_INFR/HMP_INFR_TRANPLANT/HMP_INFR_TRANPLANT_MEASURE.mesure%i.c6f14Cell -----> Default E mean used!!!!!",i)); return DefaultEMean(); // to be checked } pVal=(AliDCSValue*)pFreonCell->At(0); Double_t aCellFreon = pVal->GetFloat(); //evaluate correction factor to calculate trasparency (Ref. NIMA 486 (2002) 590-609) //Double_t aN1 = AliHMPIDParam::NIdxRad(photEn,tRefCR5); //Double_t aN2 = AliHMPIDParam::NMgF2Idx(photEn); //Double_t aN3 = 1; // Argon Idx // Double_t aR1 = ((aN1 - aN2)*(aN1 - aN2))/((aN1 + aN2)*(aN1 + aN2)); // Double_t aR2 = ((aN2 - aN3)*(aN2 - aN3))/((aN2 + aN3)*(aN2 + aN3)); // Double_t aT1 = (1 - aR1); // Double_t aT2 = (1 - aR2); // Double_t aCorrFactor = (aT1*aT1)/(aT2*aT2); // evaluate 15 mm of thickness C6F14 Trans Double_t aTransRad; Double_t aConvFactor = 1.0 - 0.3/1.8; if(aRefFreon*aRefArgon>0) { aTransRad = TMath::Power((aCellFreon/aRefFreon)/(aCellArgon/aRefArgon)*aCorrFactor[i],aConvFactor); } else { return DefaultEMean(); } // evaluate 0.5 mm of thickness SiO2 Trans Double_t aTransSiO2 = TMath::Exp(-0.5/AliHMPIDParam::LAbsWin(photEn)); // evaluate 80 cm of thickness Gap (low density CH4) transparency Double_t aTransGap = TMath::Exp(-80./AliHMPIDParam::LAbsGap(photEn)); // evaluate CsI quantum efficiency Double_t aCsIQE = AliHMPIDParam::QEffCSI(photEn); // evaluate total convolution of all material optical properties Double_t aTotConvolution = aTransRad*aTransSiO2*aTransGap*aCsIQE; sEnergProb+=aTotConvolution*photEn; sProb+=aTotConvolution; } if(sProb>0) { eMean = sEnergProb/sProb; } else { return DefaultEMean(); } Log(Form(" Mean energy photon calculated ---> %f eV ",eMean)); if(eMeanAliHMPIDParam::EPhotMax()) return DefaultEMean(); return eMean; } //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Double_t AliHMPIDPreprocessor::DefaultEMean() { Double_t eMean = 6.675; //just set a refractive index for C6F14 at ephot=6.675 eV @ T=25 C AliWarning(Form("Mean energy for photons out of range [%f,%f] in Preprocessor. Default value Eph=%f eV taken.",AliHMPIDParam::EPhotMin(), AliHMPIDParam::EPhotMax(), eMean)); return eMean; }