///*-- Author:
///////////////////////////////////////////////////////////////////////////////
// //
-// class for EMCAL time-dep calibration //
+// class for EMCAL time-dep calibration
+// - supposed to run in preprocessor
+// we use input from the following sources:
+// AliEMCALCalibTempCoeff (APD temperature coefficients),
+// AliCaloCalibSignal (LED DA), AliEMCALSensorTempArray (ELMB DCS)
+// AliEMCALCalibReference: LED amplitude and temperature info at reference time
+//
+// output/result is in AliEMCALCalibTimeDepCorrection
// //
///////////////////////////////////////////////////////////////////////////////
#include <iostream>
#include <TGraphSmooth.h>
+#include <TMath.h>
#include "AliLog.h"
#include "AliCDBEntry.h"
#include "AliCDBManager.h"
#include "AliEMCALSensorTempArray.h"
#include "AliCaloCalibSignal.h"
-#include "AliEMCALBiasAPD.h"
-#include "AliEMCALCalibMapAPD.h"
+#include "AliEMCALCalibTempCoeff.h"
#include "AliEMCALCalibReference.h"
#include "AliEMCALCalibTimeDepCorrection.h"
#include "AliEMCALCalibTimeDep.h"
/* first a bunch of constants.. */
-const double fkSecToHour = 1.0/3600.0; // conversion factor from seconds to hours
+const double kSecToHour = 1.0/3600.0; // conversion factor from seconds to hours
// some global variables for APD handling; values from Catania studies, best fit
// TempCoeff = p0+p1*M (M=gain), where p0 and and p1 are functions of the dark current
-const double fkTempCoeffP0Const = -0.903; //
-const double fkTempCoeffP0Factor = -1.381e7; //
-const double fkTempCoeffP1Const = -0.023; //
-const double fkTempCoeffP1Factor = -4.966e5; //
+const double kTempCoeffP0Const = -0.903; //
+const double kTempCoeffP0Factor = -1.381e7; //
+const double kTempCoeffP1Const = -0.023; //
+const double kTempCoeffP1Factor = -4.966e5; //
-const double fkErrorCode = -999; // to indicate that something went wrong
+const double kTempMaxDiffMedian = 2; // Temperature values should not be further away from median value within SM when considered in the average calc.
+
+const double kErrorCode = -999; // to indicate that something went wrong
using namespace std;
fEndTime(0),
fMinTemp(0),
fMaxTemp(0),
+ fMinTempVariation(0),
+ fMaxTempVariation(0),
+ fMinTempValid(15),
+ fMaxTempValid(35),
fMinTime(0),
fMaxTime(0),
fTemperatureResolution(0.1), // 0.1 deg C is default
+ fMaxTemperatureDiff(5), // 5 deg C is default max diff relative to reference
fTimeBinsPerHour(2), // 2 30-min bins per hour is default
fHighLowGainFactor(16), // factor ~16 between High gain and low gain
fTempArray(NULL),
fCalibSignal(NULL),
- fBiasAPD(NULL),
- fCalibMapAPD(NULL),
+ fCalibTempCoeff(NULL),
fCalibReference(NULL),
- fCalibTimeDepCorrection(NULL)
+ fCalibTimeDepCorrection(NULL),
+ fVerbosity(0)
{
// Constructor
}
fEndTime(calibt.GetEndTime()),
fMinTemp(calibt.GetMinTemp()),
fMaxTemp(calibt.GetMaxTemp()),
+ fMinTempVariation(calibt.GetMinTempVariation()),
+ fMaxTempVariation(calibt.GetMaxTempVariation()),
+ fMinTempValid(calibt.GetMinTempValid()),
+ fMaxTempValid(calibt.GetMaxTempValid()),
fMinTime(calibt.GetMinTime()),
fMaxTime(calibt.GetMaxTime()),
fTemperatureResolution(calibt.GetTemperatureResolution()),
+ fMaxTemperatureDiff(calibt.GetMaxTemperatureDiff()),
fTimeBinsPerHour(calibt.GetTimeBinsPerHour()),
fHighLowGainFactor(calibt.GetHighLowGainFactor()),
fTempArray(calibt.GetTempArray()),
fCalibSignal(calibt.GetCalibSignal()),
- fBiasAPD(calibt.GetBiasAPD()),
- fCalibMapAPD(calibt.GetCalibMapAPD()),
+ fCalibTempCoeff(calibt.GetCalibTempCoeff()),
fCalibReference(calibt.GetCalibReference()),
- fCalibTimeDepCorrection(calibt.GetCalibTimeDepCorrection())
+ fCalibTimeDepCorrection(calibt.GetCalibTimeDepCorrection()),
+ fVerbosity(calibt.GetVerbosity())
{
// copy constructor
}
fEndTime = 0;
fMinTemp = 0;
fMaxTemp = 0;
+ fMinTempVariation = 0;
+ fMaxTempVariation = 0;
+ fMinTempValid = 15;
+ fMaxTempValid = 35;
fMinTime = 0;
fMaxTime = 0;
fTemperatureResolution = 0.1; // 0.1 deg C is default
+ fMaxTemperatureDiff = 5; // 5 deg C is default max diff relative to reference
fTimeBinsPerHour = 2; // 2 30-min bins per hour is default
fTempArray = NULL;
fCalibSignal = NULL;
- fBiasAPD = NULL;
- fCalibMapAPD = NULL;
+ fCalibTempCoeff = NULL;
fCalibReference = NULL;
fCalibTimeDepCorrection = NULL;
+ fVerbosity = 0;
return;
}
cout << " VARIABLE DUMP: " << endl
<< " GetStartTime() " << GetStartTime() << endl
<< " GetEndTime() " << GetEndTime() << endl
+ << " GetMinTime() " << GetMinTime() << endl
+ << " GetMaxTime() " << GetMaxTime() << endl
<< " GetMinTemp() " << GetMinTemp() << endl
- << " GetMaxTemp() " << GetMaxTemp() << endl;
+ << " GetMaxTemp() " << GetMaxTemp() << endl
+ << " GetMinTempVariation() " << GetMinTempVariation() << endl
+ << " GetMaxTempVariation() " << GetMaxTempVariation() << endl
+ << " GetTemperatureResolution() " << GetTemperatureResolution() << endl;
// run ranges
cout << " RUN INFO: " << endl
+ << " runnumber " << GetRunNumber() << endl
<< " length (in hours) " << GetLengthOfRunInHours() << endl
+ << " length (in bins) " << GetLengthOfRunInBins() << endl
<< " range of temperature measurements (in hours) " << GetRangeOfTempMeasureInHours()
<< " (in deg. C) " << GetRangeOfTempMeasureInDegrees()
<< endl;
//________________________________________________________________
Double_t AliEMCALCalibTimeDep::GetLengthOfRunInHours() const
{
- return (fEndTime - fStartTime)*fkSecToHour;
+ return (fEndTime - fStartTime)*kSecToHour;
}
//________________________________________________________________
Double_t AliEMCALCalibTimeDep::GetLengthOfRunInBins() const
{
- return (fEndTime - fStartTime)*fkSecToHour*fTimeBinsPerHour;
+ return (fEndTime - fStartTime)*kSecToHour*fTimeBinsPerHour;
}
//________________________________________________________________
Double_t AliEMCALCalibTimeDep::GetRangeOfTempMeasureInHours() const
{
- return (fMaxTime - fMinTime)*fkSecToHour;
+ return (fMaxTime - fMinTime)*kSecToHour;
}
//________________________________________________________________
//________________________________________________________________
void AliEMCALCalibTimeDep::Initialize(Int_t run,
UInt_t startTime, UInt_t endTime)
-{
+{ // setup, and get temperature info
Reset(); // start fresh
fRun = run;
return;
}
-//________________________________________________________________
-Double_t AliEMCALCalibTimeDep::GetTemperature(UInt_t timeStamp) const
-{// return estimate for all SuperModules and sensors, that had data
-
- // first convert from seconds to hours..
- Double_t timeHour = (timeStamp - fStartTime) * fkSecToHour;
-
- Double_t average = 0;
- int n = 0;
-
- for (int i=0; i<fTempArray->NumSensors(); i++) {
-
- AliEMCALSensorTemp *st = fTempArray->GetSensor(i);
-
- // check if we had valid data for the time that is being asked for
- if ( timeStamp>=st->GetStartTime() && timeStamp<=st->GetEndTime() ) {
- AliSplineFit *f = st->GetFit();
- if (f) { // ok, looks like we have valid data/info
- // let's check what the expected value at the time appears to be
- Double_t val = f->Eval(timeHour);
- average += val;
- n++;
- }
- } // time
- } // loop over fTempArray
-
- if (n>0) { // some valid data was found
- average /= n;
- return average;
- }
- else { // no good data
- return fkErrorCode;
- }
-
-}
-
//________________________________________________________________
Double_t AliEMCALCalibTimeDep::GetTemperatureSM(int imod, UInt_t timeStamp) const
{// return estimate for this one SuperModule, if it had data
// first convert from seconds to hours..
- Double_t timeHour = (timeStamp - fStartTime) * fkSecToHour;
+ Double_t timeHour = (timeStamp - fStartTime) * kSecToHour;
- Double_t average = 0;
int n = 0;
+ Double_t valArr[8]={0}; // 8 sensors per SM
for (int i=0; i<fTempArray->NumSensors(); i++) {
if (f) { // ok, looks like we have valid data/info
// let's check what the expected value at the time appears to be
Double_t val = f->Eval(timeHour);
- cout << " i " << i << " val " << val << endl;
- average += val;
- n++;
+ if ( fVerbosity > 0 ) {
+ cout << " sensor i " << i << " val " << val << endl;
+ }
+ if (val>fMinTempValid && val<fMaxTempValid && n<8) {
+ valArr[n] = val;
+ n++;
+ }
}
} // time
}
} // loop over fTempArray
if (n>0) { // some valid data was found
- average /= n;
- return average;
+ Double_t median = TMath::Median(n, valArr);
+ Double_t average = 0;
+ Int_t nval = 0;
+ for (int is=0; is<n; is++) {
+ if (TMath::Abs(valArr[is] - median) < kTempMaxDiffMedian) {
+ average += valArr[is];
+ nval++;
+ }
+ }
+ //cout << " n " << n << " nval " << nval << " median " << median << endl;
+ if (nval > 0) {
+ average /= nval;
+ //cout << " average " << average << endl;
+ return average;
+ }
+ else { // this case should not happen, but kept for completeness (coverity etc)
+ return median;
+ }
}
else { // no good data
- return fkErrorCode;
+ return kErrorCode;
}
}
-//________________________________________________________________
-Double_t AliEMCALCalibTimeDep::GetTemperatureSMSensor(int imod, int isens, UInt_t timeStamp) const
-{// return estimate for this one SuperModule and sensor, if it had data
-
- // first convert from seconds to hours..
- Double_t timeHour = (timeStamp - fStartTime) * fkSecToHour;
-
- for (int i=0; i<fTempArray->NumSensors(); i++) {
-
- AliEMCALSensorTemp *st = fTempArray->GetSensor(i);
- int module = st->GetSector()*2 + st->GetSide();
- if ( module == imod && st->GetNum()==isens ) { // right module, and sensor
- // check if we had valid data for the time that is being asked for
- if ( timeStamp>=st->GetStartTime() && timeStamp<=st->GetEndTime() ) {
- AliSplineFit *f = st->GetFit();
- if (f) { // ok, looks like we have valid data/info
- // let's check what the expected value at the time appears to be
- Double_t val = f->Eval(timeHour);
-
- return val; // no point to move further in for loop, we have found the sensor we were looking for
- }
- } // time
- }
-
- } // loop over fTempArray
-
- // if we made it all here, it means that we didn't find the sensor we were looking for
- // i.e. no good data
- return fkErrorCode;
-
-}
-
//________________________________________________________________
Int_t AliEMCALCalibTimeDep::CalcCorrection()
{ // OK, this is where the real action takes place - the heart of this class..
/* The philosophy is as follows:
- 0. Init corrections to 1.0 values
- 1: if we have LED info for the tower, use it
- 2. if not 1, we rely on LED info averaged over strip
- 3. if not 2 either, we try to use temperature info + APD bias and calibration info
+ 0. Init corrections to 1.0 values, and see how many correction bins we need
+ 1. Check how large temperature variations we have through the run - do we really need all the correction bias (otherwise adjust to single bin)
+ 2. try to use temperature info + APD temperature coefficient info, to estimate correction.
+ For now (from Dec 2009), we do not use LED info.
*/
// 0: Init
// how many SuperModules do we have?
Int_t nSM = fCalibReference->GetNSuperModule();
// how many time-bins should we have for this run?
- Int_t nBins = (Int_t) GetLengthOfRunInBins(); // round-down (from double to int)
+ Int_t nBins = (Int_t) (GetLengthOfRunInBins() + 1); // round-up (from double to int; always at least 1)
Int_t binSize = (Int_t) (3600/fTimeBinsPerHour); // in seconds
+
+ // 1: get info on how much individual sensors might have changed during
+ // the run (compare max-min for each sensor separately)
+ if (fMaxTempVariation < fTemperatureResolution) {
+ nBins = 1; // just one bin needed..
+ }
+ if (nBins == 1) {
+ binSize = fEndTime - fStartTime;
+ }
+ if (fVerbosity > 0) {
+ cout << " nBins " << nBins << " binSize " << binSize << endl;
+ }
+
// set up a reasonable default (correction = 1.0)
+ fCalibTimeDepCorrection = new AliEMCALCalibTimeDepCorrection(nSM);
fCalibTimeDepCorrection->InitCorrection(nSM, nBins, 1.0);
fCalibTimeDepCorrection->SetStartTime(fStartTime);
fCalibTimeDepCorrection->SetNTimeBins(nBins);
fCalibTimeDepCorrection->SetTimeBinSize(binSize);
- // 1+2: try with LED corrections
- Int_t nRemaining = CalcLEDCorrection(nSM, nBins);
-
- // 3: try with Temperature, if needed
- if (nRemaining>0) {
- nRemaining = CalcTemperatureCorrection(nSM, nBins);
- }
+ // 2: try with Temperature correction
+ Int_t nRemaining = CalcTemperatureCorrection(nSM, nBins, binSize);
return nRemaining;
}
{ // estimate the Temperature Coefficient, based on the dark current (IDark)
// and the gain (M), based on Catania parameterizations
- Double_t P0 = fkTempCoeffP0Const + fkTempCoeffP0Factor * IDark;
- Double_t P1 = fkTempCoeffP1Const + fkTempCoeffP1Factor * IDark;
+ Double_t dP0 = kTempCoeffP0Const + kTempCoeffP0Factor * IDark;
+ Double_t dP1 = kTempCoeffP1Const + kTempCoeffP1Factor * IDark;
- Double_t TC = P0 + P1*M;
+ Double_t dTC = dP0 + dP1*M;
+ // from % numbers to regular ones..:
+ dTC *= 0.01;
- return TC;
+ return TMath::Abs(dTC); // return the absolute value, to avoid any sign confusion
}
/* Next come the methods that do the work in picking up all the needed info..*/
fMinTemp = 999; // init to some large value (999 deg C)
fMaxTemp = 0;
+ fMinTempVariation = 999; // init to some large value (999 deg C)
+ fMaxTempVariation = 0;
fMinTime = 2147483647; // init to a large value in the far future (0x7fffffff), year 2038 times..
fMaxTime = 0;
for (int i=0; i<fTempArray->NumSensors(); i++) {
AliEMCALSensorTemp *st = fTempArray->GetSensor(i);
+ if ( st->GetStartTime() == 0 ) { // no valid data
+ continue;
+ }
// check time ranges
if (fMinTime > st->GetStartTime()) { fMinTime = st->GetStartTime(); }
if (fMaxTime < st->GetEndTime()) { fMaxTime = st->GetEndTime(); }
-
+
// check temperature ranges
- TGraph *g = st->GetGraph();
- if (g) { // ok, looks like we have valid data/info
- // let's check what the expected value at the time appears to be
- if (fMinTemp > g->GetMinimum()) { fMinTemp = g->GetMinimum(); }
- if (fMaxTemp < g->GetMaximum()) { fMaxTemp = g->GetMaximum(); }
- n++;
+ AliSplineFit *f = st->GetFit();
+
+ if (f) { // ok, looks like we have valid data/info
+ int np = f->GetKnots();
+ Double_t *y0 = f->GetY0();
+ // min and max values within the single sensor
+ Double_t min = 999;
+ Double_t max = 0;
+ int nval = 0;
+ for (int ip=0; ip<np; ip++) {
+ if (y0[ip]>fMinTempValid && y0[ip]<fMaxTempValid) {
+ if (min > y0[ip]) { min = y0[ip]; }
+ if (max < y0[ip]) { max = y0[ip]; }
+ nval++;
+ }
+ }
+ if (nval>0) {
+ if (fMinTemp > min) { fMinTemp = min; }
+ if (fMaxTemp < max) { fMaxTemp = max; }
+ Double_t variation = max - min;
+ if (fMinTempVariation > variation) { fMinTempVariation = variation; }
+ if (fMaxTempVariation < variation) { fMaxTempVariation = variation; }
+
+ n++;
+ }
}
} // loop over fTempArray
return n;
}
else { // no good data
- return (Int_t) fkErrorCode;
+ return (Int_t) kErrorCode;
}
}
}
if (fCalibSignal) {
- AliInfo( Form("CalibSignal: NEvents %d NAcceptedEvents %d Entries %d AvgEntries LEDRefEntries %d LEDRefAvgEntries %d",
+ AliInfo( Form("CalibSignal: NEvents %d NAcceptedEvents %d Entries %lld AvgEntries LEDRefEntries %lld LEDRefEntries %lld, LEDRefAvgEntries %lld",
fCalibSignal->GetNEvents(), fCalibSignal->GetNAcceptedEvents(),
fCalibSignal->GetTreeAmpVsTime()->GetEntries(),
fCalibSignal->GetTreeAvgAmpVsTime()->GetEntries(),
- fCalibSignal->GetTreeLEDAmpVsTime()->GetEntries(),
+ fCalibSignal->GetTreeLEDAmpVsTime()->GetEntries(),
fCalibSignal->GetTreeLEDAvgAmpVsTime()->GetEntries() ) );
}
else {
}
//________________________________________________________________
-void AliEMCALCalibTimeDep::GetBiasAPDInfo()
+void AliEMCALCalibTimeDep::GetCalibTempCoeffInfo()
{
// pick up Preprocessor output, based on fRun (most recent version)
- AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/BiasAPD", fRun);
- if (entry) {
- fBiasAPD = (AliEMCALBiasAPD *) entry->GetObject();
- }
-
- if (fBiasAPD) {
- AliInfo( Form("BiasAPD: NSuperModule %d ", fBiasAPD->GetNSuperModule() ) );
- }
- else {
- AliWarning( Form("AliEMCALBiasAPD not found!") );
- }
-
- return;
-}
-
-//________________________________________________________________
-void AliEMCALCalibTimeDep::GetCalibMapAPDInfo()
-{
- // pick up Preprocessor output, based on fRun (most recent version)
- AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/MapAPD", fRun);
+ AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/TempCoeff", fRun);
// stored object should be a TTree; read the info
if (entry) {
- fCalibMapAPD = (AliEMCALCalibMapAPD *) entry->GetObject();
+ fCalibTempCoeff = (AliEMCALCalibTempCoeff *) entry->GetObject();
}
- if (fCalibMapAPD) {
- AliInfo( Form("CalibMapAPD: NSuperModule %d ", fCalibMapAPD->GetNSuperModule() ) );
+ if (fCalibTempCoeff) {
+ AliInfo( Form("CalibTempCoeff: NSuperModule %d ", fCalibTempCoeff->GetNSuperModule() ) );
}
else {
- AliWarning( Form("AliEMCALCalibMapAPD not found!") );
+ AliWarning( Form("AliEMCALCalibTempCoeff not found!") );
}
return;
void AliEMCALCalibTimeDep::GetCalibReferenceInfo()
{
// pick up Preprocessor output, based on fRun (most recent version)
- AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/MapAPD", fRun);
+ AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/Reference", fRun);
if (entry) {
fCalibReference = (AliEMCALCalibReference *) entry->GetObject();
}
// sanity check; same SuperModule indices for corrections as for regular calibrations
for (int i = 0; i < nSM; i++) {
- AliEMCALSuperModuleCalibReference * CalibReferenceData = fCalibReference->GetSuperModuleCalibReferenceNum(i);
- AliEMCALSuperModuleCalibTimeDepCorrection * CalibTimeDepCorrectionData = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i);
+ AliEMCALSuperModuleCalibReference * dataCalibReference = fCalibReference->GetSuperModuleCalibReferenceNum(i);
+ AliEMCALSuperModuleCalibTimeDepCorrection * dataCalibTimeDepCorrection = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i);
- int iSMRef = CalibReferenceData->GetSuperModuleNum();
- int iSMCorr = CalibTimeDepCorrectionData->GetSuperModuleNum();
+ int iSMRef = dataCalibReference->GetSuperModuleNum();
+ int iSMCorr = dataCalibTimeDepCorrection->GetSuperModuleNum();
if (iSMRef != iSMCorr) {
AliWarning( Form("AliEMCALCalibTimeDep - SuperModule index mismatch: %d != %d", iSMRef, iSMCorr) );
nRemaining = nSM * AliEMCALGeoParams::fgkEMCALCols * AliEMCALGeoParams::fgkEMCALRows * nBins;
// The fCalibSignal info is stored in TTrees
// Note that the time-bins for the TTree's may not exactly match with our correction time bins
int timeDiff = fCalibSignal->GetStartTime() - fStartTime; // in seconds
- // fCalibSignal time info in seconds: Hour/fkSecToHour
- // corrected for startTime difference: Hour/fkSecToHour + timeDiff
- // converted into a time-bin we use: (Hour + timeDiff*fkSecToHour) * fTimeBinsPerHour
+ // fCalibSignal time info in seconds: Hour/kSecToHour
+ // corrected for startTime difference: Hour/kSecToHour + timeDiff
+ // converted into a time-bin we use: (Hour + timeDiff*kSecToHour) * fTimeBinsPerHour
// values for R(T), size of TArray = nBins
// the [2] dimension below is for the low or high gain
}
// OK, now loop over the TTrees and fill the arrays needed for R(T)
- TTree *TAvg = fCalibSignal->GetTreeAvgAmpVsTime();
- TTree *TLEDRefAvg = fCalibSignal->GetTreeAvgAmpVsTime();
+ TTree *treeAvg = fCalibSignal->GetTreeAvgAmpVsTime();
+ TTree *treeLEDRefAvg = fCalibSignal->GetTreeAvgAmpVsTime();
- int ChannelNum; // for regular towers
- int RefNum; // for LED
- double Hour;
- double AvgAmp;
+ int iChannelNum = 0; // for regular towers
+ int iRefNum = 0; // for LED
+ double dHour = 0;
+ double dAvgAmp = 0;
- TAvg->SetBranchAddress("fChannelNum", &ChannelNum);
- TAvg->SetBranchAddress("fHour", &Hour);
- TAvg->SetBranchAddress("fAvgAmp",&AvgAmp);
+ treeAvg->SetBranchAddress("fChannelNum", &iChannelNum);
+ treeAvg->SetBranchAddress("fHour", &dHour);
+ treeAvg->SetBranchAddress("fAvgAmp",&dAvgAmp);
int iBin = 0;
// counters for how many values were seen per SuperModule
int nCount[AliEMCALGeoParams::fgkEMCALModules] = {0};
int nCountLEDRef[AliEMCALGeoParams::fgkEMCALModules] = {0};
- for (int ient=0; ient<TAvg->GetEntries(); ient++) {
- TAvg->GetEntry(ient);
+ for (int ient=0; ient<treeAvg->GetEntries(); ient++) {
+ treeAvg->GetEntry(ient);
// figure out where this info comes from
- fCalibSignal->DecodeChannelNum(ChannelNum, &iSM, &iCol, &iRow, &iGain);
- iBin = (int) ( (Hour + timeDiff*fkSecToHour) * fTimeBinsPerHour ); // CHECK!!!
+ fCalibSignal->DecodeChannelNum(iChannelNum, &iSM, &iCol, &iRow, &iGain);
+ iBin = (int) ( (dHour + timeDiff*kSecToHour) * fTimeBinsPerHour ); // CHECK!!!
// add value in the arrays
- ampT[iSM][iCol][iRow][iGain].AddAt( ampT[iSM][iCol][iRow][iGain].At(iBin)+AvgAmp, iBin );
+ ampT[iSM][iCol][iRow][iGain].AddAt( ampT[iSM][iCol][iRow][iGain].At(iBin)+dAvgAmp, iBin );
nT[iSM][iCol][iRow][iGain].AddAt( nT[iSM][iCol][iRow][iGain].At(iBin)+1, iBin );
nCount[iSM]++;
}
- TLEDRefAvg->SetBranchAddress("fRefNum", &RefNum);
- TLEDRefAvg->SetBranchAddress("fHour", &Hour);
- TLEDRefAvg->SetBranchAddress("fAvgAmp",&AvgAmp);
+ treeLEDRefAvg->SetBranchAddress("fRefNum", &iRefNum);
+ treeLEDRefAvg->SetBranchAddress("fHour", &dHour);
+ treeLEDRefAvg->SetBranchAddress("fAvgAmp",&dAvgAmp);
- for (int ient=0; ient<TLEDRefAvg->GetEntries(); ient++) {
- TLEDRefAvg->GetEntry(ient);
+ for (int ient=0; ient<treeLEDRefAvg->GetEntries(); ient++) {
+ treeLEDRefAvg->GetEntry(ient);
// figure out where this info comes from
- fCalibSignal->DecodeRefNum(RefNum, &iSM, &iStrip, &iGain);
- iBin = (int) ( (Hour + timeDiff*fkSecToHour) * fTimeBinsPerHour ); // CHECK!!!
+ fCalibSignal->DecodeRefNum(iRefNum, &iSM, &iStrip, &iGain);
+ iBin = (int) ( (dHour + timeDiff*kSecToHour) * fTimeBinsPerHour ); // CHECK!!!
// add value in the arrays
- ampLEDRefT[iSM][iStrip][iGain].AddAt( ampLEDRefT[iSM][iStrip][iGain].At(iBin)+AvgAmp, iBin );
+ ampLEDRefT[iSM][iStrip][iGain].AddAt( ampLEDRefT[iSM][iStrip][iGain].At(iBin)+dAvgAmp, iBin );
nLEDRefT[iSM][iStrip][iGain].AddAt( nLEDRefT[iSM][iStrip][iGain].At(iBin)+1, iBin );
nCountLEDRef[iSM]++;
}
// Calculate correction values, and store them
- // set fkErrorCode values for those that could not be set
+ // set kErrorCode values for those that could not be set
- Float_t Rt0 = 0;
- Float_t RT = 0;
+ Float_t ratiot0 = 0;
+ Float_t ratioT = 0;
Float_t correction = 0; // c(T) = R(t0)/R(T)
Int_t refGain = 0; // typically use low gain for LED reference amplitude (high gain typically well beyond saturation)
for (int i = 0; i < nSM; i++) {
- AliEMCALSuperModuleCalibReference * CalibReferenceData = fCalibReference->GetSuperModuleCalibReferenceNum(i);
- AliEMCALSuperModuleCalibTimeDepCorrection * CalibTimeDepCorrectionData = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i);
- iSM = CalibReferenceData->GetSuperModuleNum();
+ AliEMCALSuperModuleCalibReference * dataCalibReference = fCalibReference->GetSuperModuleCalibReferenceNum(i);
+ AliEMCALSuperModuleCalibTimeDepCorrection * dataCalibTimeDepCorrection = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i);
+ iSM = dataCalibReference->GetSuperModuleNum();
for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) {
// iStrip = AliEMCALGeoParams::GetStripModule(iSM, iCol);
iStrip = (iSM%2==0) ? iCol/2 : AliEMCALGeoParams::fgkEMCALLEDRefs - 1 - iCol/2; //TMP, FIXME
- refGain = CalibReferenceData->GetLEDRefHighLow(iStrip); // LED reference gain value used for reference calibration
+ refGain = dataCalibReference->GetLEDRefHighLow(iStrip); // LED reference gain value used for reference calibration
for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) {
// Calc. R(t0):
- AliEMCALCalibReferenceVal * refVal = CalibReferenceData->GetAPDVal(iCol, iRow);
+ AliEMCALCalibReferenceVal * refVal = dataCalibReference->GetAPDVal(iCol, iRow);
iGain = refVal->GetHighLow(); // gain value used for reference calibration
// valid amplitude values should be larger than 0
- if (refVal->GetLEDAmp()>0 && CalibReferenceData->GetLEDRefAmp(iStrip)>0) {
- Rt0 = refVal->GetLEDAmp() / CalibReferenceData->GetLEDRefAmp(iStrip);
+ if (refVal->GetLEDAmp()>0 && dataCalibReference->GetLEDRefAmp(iStrip)>0) {
+ ratiot0 = refVal->GetLEDAmp() / dataCalibReference->GetLEDRefAmp(iStrip);
}
else {
- Rt0 = fkErrorCode;
+ ratiot0 = kErrorCode;
}
// Calc. R(T)
// same gain as for reference calibration is the default
if (ampT[iSM][iCol][iRow][iGain].At(j)>0 && ampLEDRefT[iSM][iStrip][refGain].At(j)>0) {
// looks like valid data with the right gain combination
- RT = ampT[iSM][iCol][iRow][iGain].At(j) / ampLEDRefT[iSM][iStrip][refGain].At(j);
+ ratioT = ampT[iSM][iCol][iRow][iGain].At(j) / ampLEDRefT[iSM][iStrip][refGain].At(j);
// if data appears to be saturated, and we are in high gain, then try with low gain instead
int newGain = iGain;
// compensate for using different gain than in the reference calibration
// we may need to have a custom H/L ratio value for each tower
// later, but for now just use a common value, as the rest of the code does..
- RT = ampT[iSM][iCol][iRow][newGain].At(j) / ampLEDRefT[iSM][iStrip][newRefGain].At(j);
+ ratioT = ampT[iSM][iCol][iRow][newGain].At(j) / ampLEDRefT[iSM][iStrip][newRefGain].At(j);
if (newGain<iGain) {
- RT *= fHighLowGainFactor;
+ ratioT *= fHighLowGainFactor;
}
else if (newRefGain<refGain) {
- RT /= fHighLowGainFactor;
+ ratioT /= fHighLowGainFactor;
}
}
}
else {
- RT = fkErrorCode;
+ ratioT = kErrorCode;
}
// Calc. correction factor
- if (Rt0>0 && RT>0) {
- correction = Rt0/RT;
+ if (ratiot0>0 && ratioT>0) {
+ correction = ratiot0/ratioT;
}
else {
- correction = fkErrorCode;
+ correction = kErrorCode;
nRemaining++;
}
// Store the value
- CalibTimeDepCorrectionData->GetCorrection(iCol,iRow)->AddAt(correction, j);
+ dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->AddAt(correction, j);
/* Check that
fTimeDepCorrection->SetCorrection(i, iCol, iRow, j, correction);
also works OK */
// for calculating StripAverage info
int nValidTower = 0;
- Float_t StripAverage = 0;
+ Float_t stripAverage = 0;
Float_t val = 0;
int iSM = 0;
int lastCol = 0;
for (int i = 0; i < nSM; i++) {
- AliEMCALSuperModuleCalibTimeDepCorrection * CalibTimeDepCorrectionData = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i);
- iSM = CalibTimeDepCorrectionData->GetSuperModuleNum();
+ AliEMCALSuperModuleCalibTimeDepCorrection * dataCalibTimeDepCorrection = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i);
+ iSM = dataCalibTimeDepCorrection->GetSuperModuleNum();
for (int j = 0; j < nBins; j++) {
nValidTower = 0;
- StripAverage = 0;
+ stripAverage = 0;
for (iStrip = 0; iStrip < AliEMCALGeoParams::fgkEMCALLEDRefs; iStrip++) {
firstCol = iStrip*2;
for (iCol = firstCol; iCol <= lastCol; iCol++) {
for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) {
- val = CalibTimeDepCorrectionData->GetCorrection(iCol,iRow)->At(j);
+ val = dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->At(j);
if (val>0) { // valid value; error code is negative
- StripAverage += val;
+ stripAverage += val;
nValidTower++;
}
}
// calc average over strip
if (nValidTower>0) {
- StripAverage /= nValidTower;
+ stripAverage /= nValidTower;
for (iCol = firstCol; iCol <= lastCol; iCol++) {
for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) {
- val = CalibTimeDepCorrectionData->GetCorrection(iCol,iRow)->At(j);
+ val = dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->At(j);
if (val<0) { // invalid value; error code is negative
- CalibTimeDepCorrectionData->GetCorrection(iCol,iRow)->AddAt(val, j);
+ dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->AddAt(val, j);
}
}
}
}
//________________________________________________________________
-Int_t AliEMCALCalibTimeDep::CalcTemperatureCorrection(Int_t nSM, Int_t nBins)
+Int_t AliEMCALCalibTimeDep::CalcTemperatureCorrection(Int_t nSM, Int_t nBins, Int_t binSize)
{ // OK, so we didn't have valid LED data that allowed us to do the correction only
// with that info.
// So, instead we'll rely on the temperature info and try to do the correction
int iCol = 0;
int iRow = 0;
- Double_t TempCoeff[AliEMCALGeoParams::fgkEMCALCols][AliEMCALGeoParams::fgkEMCALRows];
- memset(TempCoeff, 0, sizeof(TempCoeff));
- Float_t MGain = 0;
+ Double_t dTempCoeff[AliEMCALGeoParams::fgkEMCALCols][AliEMCALGeoParams::fgkEMCALRows];
+ memset(dTempCoeff, 0, sizeof(dTempCoeff));
Double_t correction = 0;
- Double_t secondsPerBin = (3600/fTimeBinsPerHour);
+ Double_t secondsPerBin = (Double_t) binSize;
for (int i = 0; i < nSM; i++) {
- AliEMCALSuperModuleCalibTimeDepCorrection * CalibTimeDepCorrectionData = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(iSM);
- iSM = CalibTimeDepCorrectionData->GetSuperModuleNum();
+ AliEMCALSuperModuleCalibTimeDepCorrection * dataCalibTimeDepCorrection = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i);
+ iSM = dataCalibTimeDepCorrection->GetSuperModuleNum();
- AliEMCALSuperModuleCalibReference * CalibReferenceData = fCalibReference->GetSuperModuleCalibReferenceNum(iSM);
- AliEMCALSuperModuleCalibMapAPD * CalibMapAPDData = fCalibMapAPD->GetSuperModuleCalibMapAPDNum(iSM);
- AliEMCALSuperModuleBiasAPD * BiasAPDData = fBiasAPD->GetSuperModuleBiasAPDNum(iSM);
-
- // first calculate the M=Gain values, and TemperatureCoeff, for all towers in this SuperModule, from BiasAPD and CalibMapAPD info
+ AliEMCALSuperModuleCalibReference * dataCalibReference = fCalibReference->GetSuperModuleCalibReferenceNum(iSM);
+ AliEMCALSuperModuleCalibTempCoeff * dataCalibTempCoeff = fCalibTempCoeff->GetSuperModuleCalibTempCoeffNum(iSM);
+
+ // first get CalibTempCoeff info
for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) {
for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) {
- AliEMCALCalibMapAPDVal * mapAPD = CalibMapAPDData->GetAPDVal(iCol, iRow);
- MGain = fCalibMapAPD->GetGain(mapAPD->GetPar(0), mapAPD->GetPar(1), mapAPD->GetPar(2),
- BiasAPDData->GetVoltage(iCol, iRow));
- TempCoeff[iCol][iRow] = GetTempCoeff(mapAPD->GetDarkCurrent(), MGain);
+
+ dTempCoeff[iCol][iRow] = dataCalibTempCoeff->GetTC(iCol, iRow);
+ if (fVerbosity > 1) {
+ cout << " iSM " << iSM << " iCol " << iCol << " iRow " << iRow
+ << " dTempCoeff " << dTempCoeff[iCol][iRow] << endl;
+ }
}
}
// figure out what the reference temperature is, from fCalibReference
- Double_t ReferenceTemperature = 0;
+ Double_t referenceTemperature = 0;
int nVal = 0;
for (int iSensor = 0; iSensor<AliEMCALGeoParams::fgkEMCALTempSensors ; iSensor++) {
- if (CalibReferenceData->GetTemperature(iSensor)>0) { // hopefully OK value
- ReferenceTemperature += CalibReferenceData->GetTemperature(iSensor);
+ if (dataCalibReference->GetTemperature(iSensor)>0) { // hopefully OK value
+ referenceTemperature += dataCalibReference->GetTemperature(iSensor);
nVal++;
}
}
if (nVal>0) {
- ReferenceTemperature /= nVal; // valid values exist, we can look into corrections
+ referenceTemperature /= nVal; // valid values exist, we can look into corrections
+ Double_t dSMTemperature = 0;
for (int j = 0; j < nBins; j++) {
-
// what is the timestamp in the middle of this bin? (0.5 is for middle of bin)
UInt_t timeStamp = fStartTime + (UInt_t)((j+0.5)*secondsPerBin);
// get the temperature at this time; use average over whole SM for now (TO BE CHECKED LATER - if we can do better with finer grained info)
- Double_t SMTemperature = GetTemperatureSM(iSM, timeStamp);
-
- Double_t TemperatureDiff = ReferenceTemperature - SMTemperature; // old vs new
- // if the new temperature is higher than the old/reference one, then the gain has gone down
- if (fabs(TemperatureDiff)>fTemperatureResolution) {
- // significant enough difference that we need to consider it
+ Double_t oldSMTemperature = dSMTemperature;
+ dSMTemperature = GetTemperatureSM(iSM, timeStamp);
+ if (j>0 && (dSMTemperature==kErrorCode)) {
+ // if we have previous values, and retrieval of values failed - use that instead (hopefully good)
+ dSMTemperature = oldSMTemperature;
+ }
+
+ Double_t temperatureDiff = referenceTemperature - dSMTemperature; // ref - new
+ if (fVerbosity > 0) {
+ cout << " referenceTemperature " << referenceTemperature
+ << " dSMTemperature " << dSMTemperature
+ << " temperatureDiff " << temperatureDiff
+ << endl;
+ }
+ // if the new temperature is higher than the old/reference one (diff<0), then the gain has gone down
+ // if the new temperature is lower than the old/reference one (diff>0), then the gain has gone up
+ // dTempCoeff is a (unsigned) factor describing how many % the gain
+ // changes with a degree change.
+ // i.e. the product temperatureDiff * dTempCoeff increase when the gain goes up
+ // The correction we want to keep is what we should multiply our ADC value with as a function
+ // of time, i.e. the inverse of the gain change..
+ if ( (TMath::Abs(temperatureDiff)>fTemperatureResolution)
+ && (TMath::Abs(temperatureDiff)<fMaxTemperatureDiff) ) {
+ // significant enough difference that we need to consider it, and also not unreasonably large
// loop over all towers; effect of temperature change will depend on gain for this tower
for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) {
for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) {
- correction = TemperatureDiff * TempCoeff[iCol][iRow];
- CalibTimeDepCorrectionData->GetCorrection(iCol,iRow)->AddAt(correction, j);
+ // the correction should be inverse of modification in gain: (see discussion above)
+ // modification in gain: 1.0 + (temperatureDiff * dTempCoeff[iCol][iRow])*0.01;
+ // 1/(1+x) ~= 1 - x for small x, i.e. we arrive at:
+ correction = 1.0 - (temperatureDiff * dTempCoeff[iCol][iRow]);
+ dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->AddAt(correction, j);
+ if (fVerbosity > 1) {
+ cout << " iSM " << iSM
+ << " iCol " << iCol
+ << " iRow " << iRow
+ << " j " << j
+ << " correction " << correction
+ << endl;
+ }
}
}
correction = 1;
for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) {
for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) {
- CalibTimeDepCorrectionData->GetCorrection(iCol,iRow)->AddAt(correction, j);
+ dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->AddAt(correction, j);
}
}
} // else