//Root includes
#include <TObjArray.h>
+#include <TH1.h>
#include <TH1F.h>
#include <TH2S.h>
+#include <TF1.h>
#include <TString.h>
#include <TVectorF.h>
#include <TVectorD.h>
+#include <TVector3.h>
#include <TMatrixD.h>
#include <TMath.h>
#include <TGraph.h>
+#include <TGraphErrors.h>
#include <TString.h>
#include <TMap.h>
#include <TDirectory.h>
#include <TSystem.h>
#include <TFile.h>
#include <TCollection.h>
+#include <TTimeStamp.h>
+#include <TList.h>
+#include <TKey.h>
+#include <TSpectrum.h>
//AliRoot includes
#include "AliLog.h"
#include "AliRawReaderDate.h"
#include "AliRawEventHeaderBase.h"
#include "AliTPCRawStream.h"
-#include "AliTPCRawStreamFast.h"
-#include "AliTPCcalibDB.h"
#include "AliTPCCalROC.h"
#include "AliTPCCalPad.h"
#include "AliTPCROC.h"
#include "AliTPCParam.h"
#include "AliTPCCalibCE.h"
#include "AliMathBase.h"
+#include "AliTPCTransform.h"
+#include "AliTPCLaserTrack.h"
#include "TTreeStream.h"
+#include "AliCDBManager.h"
+#include "AliCDBEntry.h"
//date
#include "event.h"
ClassImp(AliTPCCalibCE)
fVTime0OffsetCounter(72),
fVMeanQ(72),
fVMeanQCounter(72),
- fCurrentCETimeRef(0)
+ fCurrentCETimeRef(0),
+ fProcessOld(kTRUE),
+ fProcessNew(kFALSE),
+ fAnalyseNew(kTRUE),
+ fHnDrift(0x0),
+ fArrHnDrift(100),
+ fTimeBursts(100),
+ fArrFitGraphs(0x0),
+ fEventInBunch(0)
{
//
// AliTPCSignal default constructor
//
SetNameTitle("AliTPCCalibCE","AliTPCCalibCE");
fFirstTimeBin=650;
- fLastTimeBin=1000;
+ fLastTimeBin=1030;
fParam->Update();
for (Int_t i=0;i<1024;++i) fPadSignal[i]=0;
+ for (Int_t i=0;i<14;++i){
+ fPeaks[i]=0;
+ fPeakWidths[i]=0;
+ }
+ for (Int_t i=0; i<100; ++i) fBinsLastAna[i]=0;
}
//_____________________________________________________________________
AliTPCCalibCE::AliTPCCalibCE(const AliTPCCalibCE &sig) :
fVTime0OffsetCounter(72),
fVMeanQ(72),
fVMeanQCounter(72),
- fCurrentCETimeRef(0)
+ fCurrentCETimeRef(0),
+ fProcessOld(sig.fProcessOld),
+ fProcessNew(sig.fProcessNew),
+ fAnalyseNew(sig.fAnalyseNew),
+ fHnDrift(0x0),
+ fArrHnDrift(100),
+ fTimeBursts(100),
+ fArrFitGraphs(0x0),
+ fEventInBunch(0)
{
//
// AliTPCSignal copy constructor
fVEventNumber.SetElements(sig.fVEventNumber.GetMatrixArray());
fParam->Update();
+
+ for (Int_t i=0; i<sig.fArrHnDrift.GetEntries();++i){
+ TObject *o=sig.fArrHnDrift.UncheckedAt(i);
+ if (o){
+ TObject *newo=o->Clone("fHnDrift");
+ fArrHnDrift.AddAt(newo,i);
+ if (sig.fHnDrift && o==sig.fHnDrift) fHnDrift=(THnSparseI*)newo;
+ }
+ }
+
+ for (Int_t i=0;i<sig.fTimeBursts.GetNrows();++i){
+ fTimeBursts[i]=sig.fTimeBursts[i];
+ }
+
+ for (Int_t i=0;i<14;++i){
+ fPeaks[i]=sig.fPeaks[i];
+ fPeakWidths[i]=sig.fPeakWidths[i];
+ }
+ if (sig.fArrFitGraphs) {
+ fArrFitGraphs=(TObjArray*)sig.fArrFitGraphs->Clone();
+ fArrFitGraphs->SetOwner();
+ }
+
+ for (Int_t i=0; i<100; ++i) fBinsLastAna[i]=sig.fBinsLastAna[i];
+
}
//_____________________________________________________________________
AliTPCCalibCE::AliTPCCalibCE(const TMap *config) :
fVTime0OffsetCounter(72),
fVMeanQ(72),
fVMeanQCounter(72),
- fCurrentCETimeRef(0)
+ fCurrentCETimeRef(0),
+ fProcessOld(kTRUE),
+ fProcessNew(kFALSE),
+ fAnalyseNew(kTRUE),
+ fHnDrift(0x0),
+ fArrHnDrift(100),
+ fTimeBursts(100),
+ fArrFitGraphs(0x0),
+ fEventInBunch(0)
{
//
// constructor which uses a tmap as input to set some specific parameters
//
SetNameTitle("AliTPCCalibCE","AliTPCCalibCE");
fFirstTimeBin=650;
- fLastTimeBin=1000;
+ fLastTimeBin=1030;
if (config->GetValue("FirstTimeBin")) fFirstTimeBin = ((TObjString*)config->GetValue("FirstTimeBin"))->GetString().Atoi();
if (config->GetValue("LastTimeBin")) fLastTimeBin = ((TObjString*)config->GetValue("LastTimeBin"))->GetString().Atoi();
if (config->GetValue("NbinsT0")) fNbinsT0 = ((TObjString*)config->GetValue("NbinsT0"))->GetString().Atoi();
if (config->GetValue("UseL1Phase")) fUseL1Phase = (Bool_t)((TObjString*)config->GetValue("UseL1Phase"))->GetString().Atoi();
if (config->GetValue("SecRejectRatio")) fSecRejectRatio = ((TObjString*)config->GetValue("SecRejectRatio"))->GetString().Atof();
+ if (config->GetValue("ProcessOld")) fProcessOld = (Bool_t)((TObjString*)config->GetValue("ProcessOld"))->GetString().Atoi();
+ if (config->GetValue("ProcessNew")) fProcessNew = (Bool_t)((TObjString*)config->GetValue("ProcessNew"))->GetString().Atoi();
+ if (config->GetValue("AnalyseNew")) fAnalyseNew = (Bool_t)((TObjString*)config->GetValue("AnalyseNew"))->GetString().Atoi();
+
for (Int_t i=0;i<1024;++i) fPadSignal[i]=0;
+ for (Int_t i=0;i<14;++i){
+ fPeaks[i]=0;
+ fPeakWidths[i]=0;
+ }
fParam->Update();
+ for (Int_t i=0; i<100; ++i) fBinsLastAna[i]=0;
}
//_____________________________________________________________________
//_____________________________________________________________________
AliTPCCalibCE::~AliTPCCalibCE()
{
- //
- // destructor
- //
-
- fCalRocArrayT0.Delete();
- fCalRocArrayT0Err.Delete();
- fCalRocArrayQ.Delete();
- fCalRocArrayRMS.Delete();
- fCalRocArrayOutliers.Delete();
-
- fHistoQArray.Delete();
- fHistoT0Array.Delete();
- fHistoRMSArray.Delete();
-
- fHistoTmean.Delete();
-
- fParamArrayEventPol1.Delete();
- fParamArrayEventPol2.Delete();
- fTMeanArrayEvent.Delete();
- fQMeanArrayEvent.Delete();
-
- fPadTimesArrayEvent.Delete();
- fPadQArrayEvent.Delete();
- fPadRMSArrayEvent.Delete();
- fPadPedestalArrayEvent.Delete();
-
-// if ( fHTime0 ) delete fHTime0;
- delete fParam;
+ //
+ // destructor
+ //
+
+ fCalRocArrayT0.Delete();
+ fCalRocArrayT0Err.Delete();
+ fCalRocArrayQ.Delete();
+ fCalRocArrayRMS.Delete();
+ fCalRocArrayOutliers.Delete();
+
+ fHistoQArray.Delete();
+ fHistoT0Array.Delete();
+ fHistoRMSArray.Delete();
+
+ fHistoTmean.Delete();
+
+ fParamArrayEventPol1.Delete();
+ fParamArrayEventPol2.Delete();
+ fTMeanArrayEvent.Delete();
+ fQMeanArrayEvent.Delete();
+
+ fPadTimesArrayEvent.Delete();
+ fPadQArrayEvent.Delete();
+ fPadRMSArrayEvent.Delete();
+ fPadPedestalArrayEvent.Delete();
+
+ fArrHnDrift.SetOwner();
+ fArrHnDrift.Delete();
+
+ if (fArrFitGraphs){
+ fArrFitGraphs->SetOwner();
+ delete fArrFitGraphs;
+ }
}
//_____________________________________________________________________
Int_t AliTPCCalibCE::Update(const Int_t icsector,
// assumes that it is looped over consecutive time bins of one pad
//
+ if (!fProcessOld) return 0;
//temp
if (icRow<0) return 0;
}
return 0;
}
+
+//_____________________________________________________________________
+void AliTPCCalibCE::ProcessBunch(const Int_t sector, const Int_t row, const Int_t pad,
+ const Int_t length, const UInt_t startTimeBin, const UShort_t* signal)
+{
+ //
+ // new filling method to fill the THnSparse histogram
+ //
+
+ //only in new processing mode
+ if (!fProcessNew) return;
+ //don't use the IROCs and inner part of OROCs
+ if (sector<36) return;
+ if (row<40) return;
+ //only bunches with reasonable length
+ if (length<3||length>10) return;
+
+ UShort_t timeBin = (UShort_t)startTimeBin;
+ //skip first laser layer
+ if (timeBin<280) return;
+
+ Double_t timeBurst=SetBurstHnDrift();
+
+ Int_t cePeak=((sector/18)%2)*7+6;
+ //after 1 event setup peak ranges
+ if (fEventInBunch==1 && fPeaks[cePeak]==0) {
+ // set time range
+ fHnDrift->GetAxis(4)->SetRangeUser(timeBurst-2*60,timeBurst+2*60);
+ FindLaserLayers();
+ // set time range
+ fHnDrift->GetAxis(4)->SetRangeUser(fHnDrift->GetAxis(4)->GetXmin(),fHnDrift->GetAxis(4)->GetXmax());
+ fHnDrift->Reset();
+ }
+
+ // After the first event only fill every 5th bin in a row with the CE information
+ Int_t padFill=pad;
+ if (fEventInBunch==0||(fPeaks[cePeak]>100&&TMath::Abs((Short_t)fPeaks[cePeak]-(Short_t)timeBin)<(Short_t)fPeakWidths[cePeak])){
+ Int_t mod=5;
+ Int_t n=pad/mod;
+ padFill=mod*n+mod/2;
+ }
+
+ //noise removal
+ if (!IsPeakInRange(timeBin+length/2,sector)) return;
+
+ Double_t x[kHnBinsDV]={(Double_t)sector,(Double_t)row,
+ (Double_t)padFill,(Double_t)timeBin,timeBurst};
+
+ for (Int_t iTimeBin = 0; iTimeBin<length; iTimeBin++){
+ Float_t sig=(Float_t)signal[iTimeBin];
+ // if (fPeaks[6]>900&&timeBin>(fPeaks[6]-20)&&sig<20) continue;
+ // if (fPeaks[6]>900&&timeBin<(fPeaks[6]-fPeakWidth[6])&&sig<5) continue;
+ x[3]=timeBin;
+ fHnDrift->Fill(x,sig);
+ --timeBin;
+ }
+}
+//_____________________________________________________________________
+void AliTPCCalibCE::FindLaserLayers()
+{
+ //
+ // Find the laser layer positoins
+ //
+
+ //A-side + C-side
+ for (Int_t iside=0;iside<2;++iside){
+ Int_t add=7*iside;
+ //find CE signal position and width
+ fHnDrift->GetAxis(0)->SetRangeUser(36+iside*18,53+iside*18);
+ TH1D *hproj=fHnDrift->Projection(3);
+ hproj->GetXaxis()->SetRangeUser(700,1030);
+ Int_t maxbin=hproj->GetMaximumBin();
+ Double_t binc=hproj->GetBinCenter(maxbin);
+ hproj->GetXaxis()->SetRangeUser(binc-5,binc+5);
+
+ fPeaks[add+6]=(UShort_t)TMath::Nint(binc);
+ // fPeakWidths[4]=(UShort_t)TMath::Nint(4*hproj->GetRMS()+.5);
+ fPeakWidths[add+6]=7;
+
+ hproj->GetXaxis()->SetRangeUser(0,maxbin-10);
+ TSpectrum s(6);
+ s.Search(hproj,2,"goff");
+ Int_t index[6];
+ TMath::Sort(6,s.GetPositionX(),index,kFALSE);
+ for (Int_t i=0; i<6; ++i){
+ fPeaks[i+add]=(UShort_t)TMath::Nint(s.GetPositionX()[index[i]]);
+ fPeakWidths[i+add]=5;
+ }
+
+ //other peaks
+
+// Int_t timepos=fPeaks[4]-2*fPeakWidths[4];
+// Int_t width=100;
+
+// for (Int_t i=3; i>=0; --i){
+// hproj->GetXaxis()->SetRangeUser(timepos-width,timepos);
+// fPeaks[i]=hproj->GetMaximumBin();
+// fPeakWidths[i]=(UShort_t)TMath::Nint(10.);
+// width=250;
+// timepos=fPeaks[i]-width/2;
+// }
+
+// for (Int_t i=add; i<add+7; ++i){
+// printf("Peak: %u +- %u\n",fPeaks[i],fPeakWidths[i]);
+// }
+ //check width and reset peak if >100
+// for (Int_t i=0; i<5; ++i){
+// if (fPeakWidths[i]>100) {
+// fPeaks[i]=0;
+// fPeakWidths[i]=0;
+// }
+// }
+
+ delete hproj;
+ }
+}
+
//_____________________________________________________________________
void AliTPCCalibCE::FindPedestal(Float_t part)
{
// before the EndEvent function to set the event timestamp and number!!!
// This is automatically done if the ProcessEvent(AliRawReader *rawReader)
// function was called
-
+ if (!fProcessOld) {
+ if (fProcessNew){
+ ++fNevents;
+ ++fEventInBunch;
+ }
+ return;
+ }
+
//check if last pad has allready been processed, if not do so
if ( fMaxTimeBin>-1 ) ProcessPad();
fVEventTime.GetMatrixArray()[fNevents] = fTimeStamp;
fVEventNumber.GetMatrixArray()[fNevents] = fEventId;
- fNevents++;
+ ++fNevents;
+ if (fProcessNew) ++fEventInBunch;
fOldRunNumber = fRunNumber;
delete calIroc;
// if force is true create a new histogram if it doesn't exist allready
//
if ( !force || arr->UncheckedAt(sector) )
- return (TH2S*)arr->UncheckedAt(sector);
+ return (TH2S*)arr->UncheckedAt(sector);
// if we are forced and histogram doesn't exist yet create it
- Char_t name[255], title[255];
-
- sprintf(name,"hCalib%s%.2d",type,sector);
- sprintf(title,"%s calibration histogram sector %.2d",type,sector);
-
// new histogram with Q calib information. One value for each pad!
- TH2S* hist = new TH2S(name,title,
+ TH2S* hist = new TH2S(Form("hCalib%s%.2d",type,sector),Form("%s calibration histogram sector %.2d",type,sector),
nbinsY, ymin, ymax,
fROC->GetNChannels(sector),0,fROC->GetNChannels(sector));
hist->SetDirectory(0);
// if force is true create a new histogram if it doesn't exist allready
//
if ( !force || arr->UncheckedAt(sector) )
- return (TH1S*)arr->UncheckedAt(sector);
+ return (TH1S*)arr->UncheckedAt(sector);
// if we are forced and histogram doesn't yes exist create it
- Char_t name[255], title[255];
-
- sprintf(name,"hCalib%s%.2d",type,sector);
- sprintf(title,"%s calibration histogram sector %.2d",type,sector);
-
// new histogram with calib information. One value for each pad!
- TH1S* hist = new TH1S(name,title,
+ TH1S* hist = new TH1S(Form("hCalib%s%.2d",type,sector),Form("%s calibration histogram sector %.2d",type,sector),
fLastTimeBin-fFirstTimeBin,fFirstTimeBin,fLastTimeBin);
hist->SetDirectory(0);
arr->AddAt(hist,sector);
TObjArray *arr = &fParamArrayEventPol2;
return GetParamArray(sector, arr, force);
}
+
+//_____________________________________________________________________
+void AliTPCCalibCE::CreateDVhist()
+{
+ //
+ // Setup the THnSparse for the drift velocity determination
+ //
+
+ //HnSparse bins
+ //roc, row, pad, timebin, timestamp
+ TTimeStamp begin(2010,01,01,0,0,0);
+ TTimeStamp end(2035,01,01,0,0,0);
+ Int_t nbinsTime=(end.GetSec()-begin.GetSec())/60; //Minutes resolution
+
+ Int_t bins[kHnBinsDV] = { 72, 96, 140, 1030, nbinsTime};
+ Double_t xmin[kHnBinsDV] = { 0., 0., 0., 0., (Double_t)begin.GetSec()};
+ Double_t xmax[kHnBinsDV] = {72., 96., 140., 1030., (Double_t)end.GetSec()};
+
+ fHnDrift=new THnSparseI("fHnDrift","Laser digits",kHnBinsDV, bins, xmin, xmax);
+ fHnDrift->GetAxis(0)->SetNameTitle("ROC","Read-out chamber number");
+ fHnDrift->GetAxis(1)->SetNameTitle("Row","Row number");
+ fHnDrift->GetAxis(2)->SetNameTitle("Pad","Pad number");
+ fHnDrift->GetAxis(3)->SetNameTitle("Timebin","Time bin [x100ns]");
+ fHnDrift->GetAxis(4)->SetNameTitle("EventTime","Event time");
+ fHnDrift->Reset();
+}
+
//_____________________________________________________________________
void AliTPCCalibCE::ResetEvent()
{
//
// Merge ce to the current AliTPCCalibCE
//
+ MergeBase(ce);
+ Int_t nCEevents = ce->GetNeventsProcessed();
+ if (fProcessOld&&ce->fProcessOld){
//merge histograms
- for (Int_t iSec=0; iSec<72; ++iSec){
- TH2S *hRefQmerge = ce->GetHistoQ(iSec);
- TH2S *hRefT0merge = ce->GetHistoT0(iSec);
- TH2S *hRefRMSmerge = ce->GetHistoRMS(iSec);
-
-
- if ( hRefQmerge ){
- TDirectory *dir = hRefQmerge->GetDirectory(); hRefQmerge->SetDirectory(0);
- TH2S *hRefQ = GetHistoQ(iSec);
- if ( hRefQ ) hRefQ->Add(hRefQmerge);
- else {
- TH2S *hist = new TH2S(*hRefQmerge);
- hist->SetDirectory(0);
- fHistoQArray.AddAt(hist, iSec);
+ for (Int_t iSec=0; iSec<72; ++iSec){
+ TH2S *hRefQmerge = ce->GetHistoQ(iSec);
+ TH2S *hRefT0merge = ce->GetHistoT0(iSec);
+ TH2S *hRefRMSmerge = ce->GetHistoRMS(iSec);
+
+
+ if ( hRefQmerge ){
+ TDirectory *dir = hRefQmerge->GetDirectory(); hRefQmerge->SetDirectory(0);
+ TH2S *hRefQ = GetHistoQ(iSec);
+ if ( hRefQ ) hRefQ->Add(hRefQmerge);
+ else {
+ TH2S *hist = new TH2S(*hRefQmerge);
+ hist->SetDirectory(0);
+ fHistoQArray.AddAt(hist, iSec);
+ }
+ hRefQmerge->SetDirectory(dir);
}
- hRefQmerge->SetDirectory(dir);
- }
- if ( hRefT0merge ){
- TDirectory *dir = hRefT0merge->GetDirectory(); hRefT0merge->SetDirectory(0);
- TH2S *hRefT0 = GetHistoT0(iSec);
- if ( hRefT0 ) hRefT0->Add(hRefT0merge);
- else {
- TH2S *hist = new TH2S(*hRefT0merge);
- hist->SetDirectory(0);
- fHistoT0Array.AddAt(hist, iSec);
+ if ( hRefT0merge ){
+ TDirectory *dir = hRefT0merge->GetDirectory(); hRefT0merge->SetDirectory(0);
+ TH2S *hRefT0 = GetHistoT0(iSec);
+ if ( hRefT0 ) hRefT0->Add(hRefT0merge);
+ else {
+ TH2S *hist = new TH2S(*hRefT0merge);
+ hist->SetDirectory(0);
+ fHistoT0Array.AddAt(hist, iSec);
+ }
+ hRefT0merge->SetDirectory(dir);
}
- hRefT0merge->SetDirectory(dir);
- }
- if ( hRefRMSmerge ){
- TDirectory *dir = hRefRMSmerge->GetDirectory(); hRefRMSmerge->SetDirectory(0);
- TH2S *hRefRMS = GetHistoRMS(iSec);
- if ( hRefRMS ) hRefRMS->Add(hRefRMSmerge);
- else {
- TH2S *hist = new TH2S(*hRefRMSmerge);
- hist->SetDirectory(0);
- fHistoRMSArray.AddAt(hist, iSec);
+ if ( hRefRMSmerge ){
+ TDirectory *dir = hRefRMSmerge->GetDirectory(); hRefRMSmerge->SetDirectory(0);
+ TH2S *hRefRMS = GetHistoRMS(iSec);
+ if ( hRefRMS ) hRefRMS->Add(hRefRMSmerge);
+ else {
+ TH2S *hist = new TH2S(*hRefRMSmerge);
+ hist->SetDirectory(0);
+ fHistoRMSArray.AddAt(hist, iSec);
+ }
+ hRefRMSmerge->SetDirectory(dir);
}
- hRefRMSmerge->SetDirectory(dir);
+
}
- }
-
// merge time information
-
-
- Int_t nCEevents = ce->GetNeventsProcessed();
- for (Int_t iSec=0; iSec<72; ++iSec){
- TObjArray *arrPol1CE = ce->GetParamArrayPol1(iSec);
- TObjArray *arrPol2CE = ce->GetParamArrayPol2(iSec);
- TVectorF *vMeanTimeCE = ce->GetTMeanEvents(iSec);
- TVectorF *vMeanQCE = ce->GetQMeanEvents(iSec);
- TObjArray *arrPol1 = 0x0;
- TObjArray *arrPol2 = 0x0;
- TVectorF *vMeanTime = 0x0;
- TVectorF *vMeanQ = 0x0;
+ for (Int_t iSec=0; iSec<72; ++iSec){
+ TObjArray *arrPol1CE = ce->GetParamArrayPol1(iSec);
+ TObjArray *arrPol2CE = ce->GetParamArrayPol2(iSec);
+ TVectorF *vMeanTimeCE = ce->GetTMeanEvents(iSec);
+ TVectorF *vMeanQCE = ce->GetQMeanEvents(iSec);
+
+ TObjArray *arrPol1 = 0x0;
+ TObjArray *arrPol2 = 0x0;
+ TVectorF *vMeanTime = 0x0;
+ TVectorF *vMeanQ = 0x0;
+
//resize arrays
- if ( arrPol1CE && arrPol2CE ){
- arrPol1 = GetParamArrayPol1(iSec,kTRUE);
- arrPol2 = GetParamArrayPol2(iSec,kTRUE);
- arrPol1->Expand(fNevents+nCEevents);
- arrPol2->Expand(fNevents+nCEevents);
- }
- if ( vMeanTimeCE && vMeanQCE ){
- vMeanTime = GetTMeanEvents(iSec,kTRUE);
- vMeanQ = GetQMeanEvents(iSec,kTRUE);
- vMeanTime->ResizeTo(fNevents+nCEevents);
- vMeanQ->ResizeTo(fNevents+nCEevents);
+ if ( arrPol1CE && arrPol2CE ){
+ arrPol1 = GetParamArrayPol1(iSec,kTRUE);
+ arrPol2 = GetParamArrayPol2(iSec,kTRUE);
+ arrPol1->Expand(fNevents+nCEevents);
+ arrPol2->Expand(fNevents+nCEevents);
+ }
+ if ( vMeanTimeCE && vMeanQCE ){
+ vMeanTime = GetTMeanEvents(iSec,kTRUE);
+ vMeanQ = GetQMeanEvents(iSec,kTRUE);
+ vMeanTime->ResizeTo(fNevents+nCEevents);
+ vMeanQ->ResizeTo(fNevents+nCEevents);
+ }
+
+ for (Int_t iEvent=0; iEvent<nCEevents; ++iEvent){
+ if ( arrPol1CE && arrPol2CE ){
+ TVectorD *paramPol1 = (TVectorD*)(arrPol1CE->UncheckedAt(iEvent));
+ TVectorD *paramPol2 = (TVectorD*)(arrPol2CE->UncheckedAt(iEvent));
+ if ( paramPol1 && paramPol2 ){
+ GetParamArrayPol1(iSec,kTRUE)->AddAt(new TVectorD(*paramPol1), fNevents+iEvent);
+ GetParamArrayPol2(iSec,kTRUE)->AddAt(new TVectorD(*paramPol2), fNevents+iEvent);
+ }
+ }
+ if ( vMeanTimeCE && vMeanQCE ){
+ vMeanTime->GetMatrixArray()[fNevents+iEvent]=vMeanTimeCE->GetMatrixArray()[iEvent];
+ vMeanQ->GetMatrixArray()[fNevents+iEvent]=vMeanQCE->GetMatrixArray()[iEvent];
+ }
+ }
}
+
+ const TVectorD& eventTimes = ce->fVEventTime;
+ const TVectorD& eventIds = ce->fVEventNumber;
+ const TVectorF& time0SideA = ce->fVTime0SideA;
+ const TVectorF& time0SideC = ce->fVTime0SideC;
+ fVEventTime.ResizeTo(fNevents+nCEevents);
+ fVEventNumber.ResizeTo(fNevents+nCEevents);
+ fVTime0SideA.ResizeTo(fNevents+nCEevents);
+ fVTime0SideC.ResizeTo(fNevents+nCEevents);
+
for (Int_t iEvent=0; iEvent<nCEevents; ++iEvent){
- if ( arrPol1CE && arrPol2CE ){
- TVectorD *paramPol1 = (TVectorD*)(arrPol1CE->UncheckedAt(iEvent));
- TVectorD *paramPol2 = (TVectorD*)(arrPol2CE->UncheckedAt(iEvent));
- if ( paramPol1 && paramPol2 ){
- GetParamArrayPol1(iSec,kTRUE)->AddAt(new TVectorD(*paramPol1), fNevents+iEvent);
- GetParamArrayPol2(iSec,kTRUE)->AddAt(new TVectorD(*paramPol2), fNevents+iEvent);
- }
- }
- if ( vMeanTimeCE && vMeanQCE ){
- vMeanTime->GetMatrixArray()[fNevents+iEvent]=vMeanTimeCE->GetMatrixArray()[iEvent];
- vMeanQ->GetMatrixArray()[fNevents+iEvent]=vMeanQCE->GetMatrixArray()[iEvent];
+ Double_t evTime = eventTimes.GetMatrixArray()[iEvent];
+ Double_t evId = eventIds.GetMatrixArray()[iEvent];
+ Float_t t0SideA = time0SideA.GetMatrixArray()[iEvent];
+ Float_t t0SideC = time0SideC.GetMatrixArray()[iEvent];
+
+ fVEventTime.GetMatrixArray()[fNevents+iEvent] = evTime;
+ fVEventNumber.GetMatrixArray()[fNevents+iEvent] = evId;
+ fVTime0SideA.GetMatrixArray()[fNevents+iEvent] = t0SideA;
+ fVTime0SideC.GetMatrixArray()[fNevents+iEvent] = t0SideC;
+ }
+ }
+
+ if (fProcessNew&&ce->fProcessNew) {
+ if (fArrHnDrift.GetEntries() != ce->fArrHnDrift.GetEntries() ){
+ AliError("Number of bursts in the instances to merge are different. No merging done!");
+ } else {
+ for (Int_t i=0;i<fArrHnDrift.GetEntries();++i){
+ THnSparseI *h=(THnSparseI*)fArrHnDrift.UncheckedAt(i);
+ THnSparseI *hce=(THnSparseI*)ce->fArrHnDrift.UncheckedAt(i);
+ if (h && hce) h->Add(hce);
+ else AliError(Form("AliTPCCalibCE::Merge - one THnSparse missing in burst %d",i));
}
+ //TODO: What to do with fTimeBursts???
}
}
-
-
- const TVectorD& eventTimes = ce->fVEventTime;
- const TVectorD& eventIds = ce->fVEventNumber;
- const TVectorF& time0SideA = ce->fVTime0SideA;
- const TVectorF& time0SideC = ce->fVTime0SideC;
- fVEventTime.ResizeTo(fNevents+nCEevents);
- fVEventNumber.ResizeTo(fNevents+nCEevents);
- fVTime0SideA.ResizeTo(fNevents+nCEevents);
- fVTime0SideC.ResizeTo(fNevents+nCEevents);
-
- for (Int_t iEvent=0; iEvent<nCEevents; ++iEvent){
- Double_t evTime = eventTimes.GetMatrixArray()[iEvent];
- Double_t evId = eventIds.GetMatrixArray()[iEvent];
- Float_t t0SideA = time0SideA.GetMatrixArray()[iEvent];
- Float_t t0SideC = time0SideC.GetMatrixArray()[iEvent];
-
- fVEventTime.GetMatrixArray()[fNevents+iEvent] = evTime;
- fVEventNumber.GetMatrixArray()[fNevents+iEvent] = evId;
- fVTime0SideA.GetMatrixArray()[fNevents+iEvent] = t0SideA;
- fVTime0SideC.GetMatrixArray()[fNevents+iEvent] = t0SideC;
- }
fNevents+=nCEevents; //increase event counter
}
// for an example see class description at the beginning
//
- Double_t *x = new Double_t[fNevents];
- Double_t *y = new Double_t[fNevents];
-
TVectorD *xVar = 0x0;
TObjArray *aType = 0x0;
Int_t npoints=0;
for ( Int_t i=0;i<fNevents; ++i) (*xVar)[i]=i;
}
+ Double_t *x = new Double_t[fNevents];
+ Double_t *y = new Double_t[fNevents];
+
for (Int_t ievent =0; ievent<fNevents; ++ievent){
if ( fitType<2 ){
TObjArray *events = (TObjArray*)(aType->At(sector));
TGraph *gr = new TGraph(npoints);
//sort xVariable increasing
Int_t *sortIndex = new Int_t[npoints];
- TMath::Sort(npoints,x,sortIndex);
+ TMath::Sort(npoints,x,sortIndex, kFALSE);
for (Int_t i=0;i<npoints;++i){
gr->SetPoint(i,x[sortIndex[i]],y[sortIndex[i]]);
}
if ( xVariable == 2 ) delete xVar;
- delete x;
- delete y;
- delete sortIndex;
+ delete [] x;
+ delete [] y;
+ delete [] sortIndex;
return gr;
}
//_____________________________________________________________________
//
// Calculate calibration constants
//
+
+ if (fProcessOld){
+ TVectorD paramQ(3);
+ TVectorD paramT0(3);
+ TVectorD paramRMS(3);
+ TMatrixD dummy(3,3);
+
+ Float_t channelCounter=0;
+ fMeanT0rms=0;
+ fMeanQrms=0;
+ fMeanRMSrms=0;
+
+ for (Int_t iSec=0; iSec<72; ++iSec){
+ TH2S *hT0 = GetHistoT0(iSec);
+ if (!hT0 ) continue;
+
+ AliTPCCalROC *rocQ = GetCalRocQ (iSec,kTRUE);
+ AliTPCCalROC *rocT0 = GetCalRocT0 (iSec,kTRUE);
+ AliTPCCalROC *rocT0Err = GetCalRocT0Err (iSec,kTRUE);
+ AliTPCCalROC *rocRMS = GetCalRocRMS(iSec,kTRUE);
+ AliTPCCalROC *rocOut = GetCalRocOutliers(iSec,kTRUE);
+
+ TH2S *hQ = GetHistoQ(iSec);
+ TH2S *hRMS = GetHistoRMS(iSec);
+
+ Short_t *arrayhQ = hQ->GetArray();
+ Short_t *arrayhT0 = hT0->GetArray();
+ Short_t *arrayhRMS = hRMS->GetArray();
+
+ UInt_t nChannels = fROC->GetNChannels(iSec);
+
+ //debug
+ Int_t row=0;
+ Int_t pad=0;
+ Int_t padc=0;
+ //! debug
+
+ for (UInt_t iChannel=0; iChannel<nChannels; ++iChannel){
+
+
+ Float_t cogTime0 = -1000;
+ Float_t cogQ = -1000;
+ Float_t cogRMS = -1000;
+ Float_t cogOut = 0;
+ Float_t rms = 0;
+ Float_t rmsT0 = 0;
+
+
+ Int_t offsetQ = (fNbinsQ+2)*(iChannel+1)+1;
+ Int_t offsetT0 = (fNbinsT0+2)*(iChannel+1)+1;
+ Int_t offsetRMS = (fNbinsRMS+2)*(iChannel+1)+1;
+
+ cogQ = AliMathBase::GetCOG(arrayhQ+offsetQ,fNbinsQ,fXminQ,fXmaxQ,&rms);
+ fMeanQrms+=rms;
+ cogTime0 = AliMathBase::GetCOG(arrayhT0+offsetT0,fNbinsT0,fXminT0,fXmaxT0,&rmsT0);
+ fMeanT0rms+=rmsT0;
+ cogRMS = AliMathBase::GetCOG(arrayhRMS+offsetRMS,fNbinsRMS,fXminRMS,fXmaxRMS,&rms);
+ fMeanRMSrms+=rms;
+ channelCounter++;
+
+ /*
+ //outlier specifications
+ if ( (cogQ < ??) && (cogTime0 > ??) && (cogTime0<??) && ( cogRMS>??) ){
+ cogOut = 1;
+ cogTime0 = 0;
+ cogQ = 0;
+ cogRMS = 0;
+ }
+ */
+ rocQ->SetValue(iChannel, cogQ*cogQ);
+ rocT0->SetValue(iChannel, cogTime0);
+ rocT0Err->SetValue(iChannel, rmsT0);
+ rocRMS->SetValue(iChannel, cogRMS);
+ rocOut->SetValue(iChannel, cogOut);
+
+
+ //debug
+ if ( GetStreamLevel() > 0 ){
+ TTreeSRedirector *streamer=GetDebugStreamer();
+ if ( streamer ) {
+
+ while ( iChannel > (fROC->GetRowIndexes(iSec)[row]+fROC->GetNPads(iSec,row)-1) ) row++;
+ pad = iChannel-fROC->GetRowIndexes(iSec)[row];
+ padc = pad-(fROC->GetNPads(iSec,row)/2);
+
+ (*streamer) << "DataEnd" <<
+ "Sector=" << iSec <<
+ "Pad=" << pad <<
+ "PadC=" << padc <<
+ "Row=" << row <<
+ "PadSec=" << iChannel <<
+ "Q=" << cogQ <<
+ "T0=" << cogTime0 <<
+ "RMS=" << cogRMS <<
+ "\n";
+ }
+ }
+ //! debug
+
+ }
+
+ }
+ if ( channelCounter>0 ){
+ fMeanT0rms/=channelCounter;
+ fMeanQrms/=channelCounter;
+ fMeanRMSrms/=channelCounter;
+ }
+ // if ( fDebugStreamer ) fDebugStreamer->GetFile()->Write();
+ // delete fDebugStreamer;
+ // fDebugStreamer = 0x0;
+ fVEventTime.ResizeTo(fNevents);
+ fVEventNumber.ResizeTo(fNevents);
+ fVTime0SideA.ResizeTo(fNevents);
+ fVTime0SideC.ResizeTo(fNevents);
+ }
+
+ if (fProcessNew&&fAnalyseNew){
+ AnalyseTrack();
+ for (Int_t iburst=0; iburst<fArrHnDrift.GetEntries(); ++iburst){
+ THnSparseI *h=(THnSparseI*)fArrHnDrift.UncheckedAt(iburst);
+ h->GetAxis(4)->SetRangeUser(fTimeBursts[iburst]-60*5,fTimeBursts[iburst]+60*5);
+ }
+ }
+}
+
+
+
+
+//
+// New functions that also use the laser tracks
+//
+
+
+
+//_____________________________________________________________________
+void AliTPCCalibCE::FindLocalMaxima(TObjArray * const arrObj, Double_t timestamp, Int_t burst)
+{
+ //
+ //Find the local maximums for the projections to each axis
+ //
- TVectorD paramQ(3);
- TVectorD paramT0(3);
- TVectorD paramRMS(3);
- TMatrixD dummy(3,3);
+ //find laser layer positoins
+ fHnDrift->GetAxis(4)->SetRangeUser(timestamp-2*60,timestamp+2*60);
+ FindLaserLayers();
+ THnSparse *hProj=fHnDrift;
+ Double_t posCE[4]={0.,0.,0.,0.};
+ Double_t widthCE[4]={0.,0.,0.,0.};
- Float_t channelCounter=0;
- fMeanT0rms=0;
- fMeanQrms=0;
- fMeanRMSrms=0;
+// if(fPeaks[4]!=0){
+ // find central electrode position once more, separately for IROC, OROC, A-, C-Side
- for (Int_t iSec=0; iSec<72; ++iSec){
- TH2S *hT0 = GetHistoT0(iSec);
- if (!hT0 ) continue;
+ for (Int_t i=0; i<4; ++i){
+ Int_t ce=(i/2>0)*7+6;
+ hProj->GetAxis(0)->SetRangeUser(i*18,(i+1)*18-1);
+ TH1 *h=fHnDrift->Projection(3);
+ h->GetXaxis()->SetRangeUser(fPeaks[ce]-fPeakWidths[ce],fPeaks[ce]+fPeakWidths[ce]);
+ Int_t nbinMax=h->GetMaximumBin();
+ Double_t maximum=h->GetMaximum();
+// Double_t maxExpected=fNevents/fArrHnDrift->GetEntries()*556568./5./10.;
+// if (nbinMax<700||maximum<maxExpected) continue;
+ Double_t xbinMax=h->GetBinCenter(nbinMax);
+ TF1 fgaus("gaus","gaus",xbinMax-5,xbinMax+5);
+ fgaus.SetParameters(maximum,xbinMax,2);
+ fgaus.SetParLimits(1,xbinMax-5.,xbinMax+5.);
+ fgaus.SetParLimits(2,0.2,4.);
+ h->Fit(&fgaus,"RQN");
+// Double_t deltaX=4*fgaus.GetParameter(2);
+// xbinMax=fgaus.GetParameter(1);
+ delete h;
+ posCE[i]=fgaus.GetParameter(1);
+ widthCE[i]=4*fgaus.GetParameter(2);
+ hProj->GetAxis(0)->SetRangeUser(0,72);
+ }
+// }
+ //Current drift velocity
+ Float_t vdrift=2.61301900000000000e+06;//fParam->GetDriftV();
+// cout<<"vdrift="<<vdrift<<endl;
+
+ AliDebug(5,Form("Timestamp %f - default drift velocity %f",timestamp,vdrift));
+ //loop over all entries in the histogram
+ Int_t coord[5];
+ for(Long64_t ichunk=0;ichunk<hProj->GetNbins();ichunk++){
+ //get entry position and content
+ Double_t adc=hProj->GetBinContent(ichunk,coord);
- AliTPCCalROC *rocQ = GetCalRocQ (iSec,kTRUE);
- AliTPCCalROC *rocT0 = GetCalRocT0 (iSec,kTRUE);
- AliTPCCalROC *rocT0Err = GetCalRocT0Err (iSec,kTRUE);
- AliTPCCalROC *rocRMS = GetCalRocRMS(iSec,kTRUE);
- AliTPCCalROC *rocOut = GetCalRocOutliers(iSec,kTRUE);
- TH2S *hQ = GetHistoQ(iSec);
- TH2S *hRMS = GetHistoRMS(iSec);
+ Int_t sector = coord[0]-1;
+ Int_t row = coord[1]-1;
+ Int_t pad = coord[2]-1;
+ Int_t timeBin= coord[3]-1;
+ Double_t time = fHnDrift->GetAxis(4)->GetBinCenter(coord[4]);
+ Int_t side = (sector/18)%2;
+// return;
+// fPeaks[4]=(UInt_t)posCE[sector/18];
+// fPeakWidths[4]=(UInt_t)widthCE[sector/18];
- Short_t *arrayhQ = hQ->GetArray();
- Short_t *arrayhT0 = hT0->GetArray();
- Short_t *arrayhRMS = hRMS->GetArray();
+ //cuts
+ if (time<timestamp-120||time>timestamp+120) continue; //window of +- 2min
+ if (adc < 5 ) continue;
+ if (IsEdgePad(sector,row,pad)) continue;
+// if (!IsPeakInRange(timeBin)) continue;
+// if (isCE&&((row%2)||(row%2)||(sector%2))) continue;
+// if (isCE&&(sector!=0)) continue;
- UInt_t nChannels = fROC->GetNChannels(iSec);
+ Int_t padmin=-2, padmax=2;
+ Int_t timemin=-2, timemax=2;
+ Int_t minsumperpad=2;
+ //CE or laser tracks
+ Bool_t isCE=kFALSE;
+ if (TMath::Abs((Short_t)timeBin-(Short_t)posCE[sector/18])<(Short_t)widthCE[sector/18]) {
+ isCE=kTRUE;
+ padmin=0;
+ padmax=0;
+ timemin=-3;
+ timemax=7;
+ }
- //debug
- Int_t row=0;
- Int_t pad=0;
- Int_t padc=0;
- //! debug
+ //
+ // Find local maximum and cogs
+ //
+ Bool_t isMaximum=kTRUE;
+ Float_t totalmass=0, tbcm=0, padcm=0, rmstb=0, rmspad=0;
+ Double_t cogY=0, rmsY=0;
+ Int_t npart=0;
+
+ // for position calculation use
+ for(Int_t ipad=padmin;ipad<=padmax;++ipad){
+ Float_t lxyz[3];
+ fROC->GetPositionLocal(sector,row,pad+ipad,lxyz);
+
+ for(Int_t itime=timemin;itime<=timemax;++itime){
+
+ Int_t a[5]={coord[0],coord[1],coord[2]+ipad,coord[3]+itime,coord[4]};
+ Double_t val=hProj->GetBinContent(a);
+ totalmass+=val;
+
+ tbcm +=(timeBin+itime)*val;
+ padcm+=(pad+ipad)*val;
+ cogY +=lxyz[1]*val;
+
+ rmstb +=(timeBin+itime)*(timeBin+itime)*val;
+ rmspad+=(pad+ipad)*(pad+ipad)*val;
+ rmsY +=lxyz[1]*lxyz[1]*val;
+
+ if (val>0) ++npart;
+ if (val>adc) {
+ isMaximum=kFALSE;
+ break;
+ }
+ }
+ if (!isMaximum) break;
+ }
+
+ if (!isMaximum||!npart) continue;
+ if (totalmass<npart*minsumperpad) continue;
+ if (!isCE&&rmspad<.1) continue; //most probably noise, since signal only in one pad,
+ //for CE we want only one pad by construction
+
+ tbcm/=totalmass;
+ padcm/=totalmass;
+ cogY/=totalmass;
+
+ rmstb/=totalmass;
+ rmspad/=totalmass;
+ rmsY/=totalmass;
+
+ rmstb=TMath::Sqrt(TMath::Abs(tbcm*tbcm-rmstb));
+ rmspad=TMath::Sqrt(TMath::Abs(padcm*padcm-rmspad));
+ rmsY=TMath::Sqrt(TMath::Abs(cogY*cogY-rmsY));
+
+ Int_t cog=TMath::Nint(padcm);
- for (UInt_t iChannel=0; iChannel<nChannels; ++iChannel){
+ // timebin --> z position
+ Float_t zlength=fParam->GetZLength(side);
+// Float_t timePos=tbcm+(1000-fPeaks[4])
+ // drift velocity is in m/s we would like to have cm/100ns, so 100cm/(10^7*100ns)
+ Double_t gz=(zlength-(tbcm*vdrift*1.e-7))*TMath::Power(-1,side);
+
+ // local to global transformation--> x and y positions
+ Float_t padlxyz[3];
+ fROC->GetPositionLocal(sector,row,pad,padlxyz);
+
+ Double_t gxyz[3]={padlxyz[0],cogY,gz};
+ Double_t lxyz[3]={padlxyz[0],cogY,gz};
+ Double_t igxyz[3]={0,0,0};
+ AliTPCTransform t1;
+ t1.RotatedGlobal2Global(sector,gxyz);
+
+ Double_t mindist=0;
+ Int_t trackID=-1;
+ Int_t trackID2=-1;
+
+ //find track id and index of the position in the track (row)
+ Int_t index=0;
+ if (!isCE){
+ index=row+(sector>35)*fROC->GetNRows(0);
+ trackID=FindLaserTrackID(sector,index,gxyz,mindist,lxyz,trackID2);
+ } else {
+ trackID=336+((sector/18)%2);
+ index= fROC->GetRowIndexes(sector)[row]+pad; // global pad position in sector
+ if (sector<36) {
+ index+=(sector%18)*fROC->GetNChannels(sector);
+ } else {
+ index+=18*fROC->GetNChannels(0);
+ index+=(sector%18)*fROC->GetNChannels(sector);
+ }
+ //TODO: find out about the multiple peaks in the CE
+// mindist=TMath::Abs(fPeaks[4]-tbcm);
+ mindist=1.;
+ }
+
+ // fill track vectors
+ if (trackID>0){
+ AliTPCLaserTrack *ltr=(AliTPCLaserTrack*)arrObj->UncheckedAt(trackID);
+ Double_t oldMinDist=ltr->fVecPhi->GetMatrixArray()[index];
- Float_t cogTime0 = -1000;
- Float_t cogQ = -1000;
- Float_t cogRMS = -1000;
- Float_t cogOut = 0;
- Float_t rms = 0;
- Float_t rmsT0 = 0;
+// travel time effect of light includes
+ Double_t raylength=ltr->GetRayLength();
+ Double_t globmir[3]={ltr->Xv(),ltr->Yv(),ltr->Zv()};
+ ltr->GetXYZ(globmir);
+ if(trackID<336){
+ if(side==0){
+ gxyz[2]=gxyz[2]-(TMath::Sqrt((gxyz[0]-globmir[0])*(gxyz[0]-globmir[0])
+ +(gxyz[1]-globmir[1])*(gxyz[1]-globmir[1])
+ +(gxyz[2]-globmir[2])*(gxyz[2]-globmir[2])+raylength))*vdrift*TMath::Power(10.,-6.)/30000;
+ }
+ else {
+ gxyz[2]=gxyz[2]-(TMath::Sqrt((gxyz[0]-globmir[0])*(gxyz[0]-globmir[0])
+ +(gxyz[1]-globmir[1])*(gxyz[1]-globmir[1])
+ +(gxyz[2]-globmir[2])*(gxyz[2]-globmir[2])+raylength))*vdrift*TMath::Power(10.,-6.)/30000;
+ }
+ }
+
+ if (TMath::Abs(oldMinDist)<1.e-20||oldMinDist>mindist){
+ ltr->fVecSec->GetMatrixArray()[index]=sector;
+ ltr->fVecP2->GetMatrixArray()[index]=0;
+ ltr->fVecPhi->GetMatrixArray()[index]=mindist;
+ ltr->fVecGX->GetMatrixArray()[index]=gxyz[0];
+ ltr->fVecGY->GetMatrixArray()[index]=gxyz[1];
+ ltr->fVecGZ->GetMatrixArray()[index]=gxyz[2];
+ ltr->fVecLX->GetMatrixArray()[index]=lxyz[0];
+ ltr->fVecLY->GetMatrixArray()[index]=lxyz[1];
+ ltr->fVecLZ->GetMatrixArray()[index]=lxyz[2];
+// ltr->SetUniqueID((UInt_t)(mindist*10000)); //distance in um
+ }
+ TObjArray *arr=AliTPCLaserTrack::GetTracks();
+ ltr=(AliTPCLaserTrack*)arr->UncheckedAt(trackID);
+ igxyz[0]=ltr->fVecGX->GetMatrixArray()[row];
+ igxyz[1]=ltr->fVecGY->GetMatrixArray()[row];
+ igxyz[2]=ltr->fVecGZ->GetMatrixArray()[row];
+ }
+
+
+ if (fStreamLevel>4){
+ (*GetDebugStreamer()) << "clusters" <<
+ "run=" << fRunNumber <<
+ "timestamp=" << timestamp <<
+ "burst=" << burst <<
+ "side=" << side <<
+ "sec=" << sector <<
+ "row=" << row <<
+ "pad=" << pad <<
+ "padCog=" << cog <<
+ "timebin=" << timeBin <<
+ "cogCE=" << posCE[sector/18] <<
+ "withCE=" << widthCE[sector/18] <<
+ "index=" << index <<
+
+ "padcm=" << padcm <<
+ "rmspad=" << rmspad <<
+
+ "cogtb=" << tbcm <<
+ "rmstb=" << rmstb <<
+
+ "npad=" << npart <<
+
+ "lx=" << padlxyz[0]<<
+ "ly=" << cogY <<
+ "lypad=" << padlxyz[1]<<
+ "rmsY=" << rmsY <<
+
+ "gx=" << gxyz[0] <<
+ "gy=" << gxyz[1] <<
+ "gz=" << gxyz[2] <<
+
+ "igx=" << igxyz[0] <<
+ "igy=" << igxyz[1] <<
+ "igz=" << igxyz[2] <<
+
+ "mind=" << mindist <<
+ "max=" << adc <<
+ "trackid=" << trackID <<
+ "trackid2=" << trackID2 <<
+ "npart=" << npart <<
+ "\n";
+ } // end stream levelmgz.fElements
+
+ }
+
+}
+
+//_____________________________________________________________________
+void AliTPCCalibCE::AnalyseTrack()
+{
+ //
+ // Analyse the tracks
+ //
+
+
+ AliTPCLaserTrack::LoadTracks();
+// AliTPCParam *param=0x0;
+// //cdb run number
+// AliCDBManager *man=AliCDBManager::Instance();
+// if (man->GetDefaultStorage()){
+// AliCDBEntry *entry=man->Get("TPC/Calib/Parameters",fRunNumber);
+// if (entry){
+// entry->SetOwner(kTRUE);
+// param = (AliTPCParam*)(entry->GetObject()->Clone());
+// }
+// }
+// if (param){
+// if (fParam) delete fParam;
+// fParam=param;
+// } else {
+// AliError("Could not get updated AliTPCParam from OCDB!!!");
+// }
+
+ //Measured and ideal laser tracks
+ TObjArray* arrMeasured = SetupMeasured();
+ TObjArray* arrIdeal = AliTPCLaserTrack::GetTracks();
+ AddCEtoIdeal(arrIdeal);
+
+ //find bursts and loop over them
+ for (Int_t iburst=0; iburst<fArrHnDrift.GetEntries();++iburst){
+ Double_t timestamp=fTimeBursts[iburst];
+ AliDebug(5,Form("Burst: %d (%f)",iburst,timestamp));
+ fHnDrift=(THnSparseI*)fArrHnDrift.UncheckedAt(iburst);
+ if (!fHnDrift) continue;
+ UInt_t entries=(UInt_t)fHnDrift->GetEntries();
+ if (fBinsLastAna[iburst]>=entries) continue; //already analysed!!!
+ fBinsLastAna[iburst]=entries;
+
+ for (Int_t iDim=0; iDim<fHnDrift->GetNdimensions(); ++iDim) fHnDrift->GetAxis(iDim)->SetRange(0,0);
+// if (iburst==0) FindLaserLayers();
+
+ //reset laser tracks
+ ResetMeasured(arrMeasured);
+
+ //find clusters and associate to the tracks
+ FindLocalMaxima(arrMeasured, timestamp, iburst);
+
+ //calculate drift velocity
+ CalculateDV(arrIdeal,arrMeasured,iburst);
+
+ //Dump information to file if requested
+ if (fStreamLevel>2){
+ //printf("make tree\n");
+ //laser track information
- Int_t offsetQ = (fNbinsQ+2)*(iChannel+1)+1;
- Int_t offsetT0 = (fNbinsT0+2)*(iChannel+1)+1;
- Int_t offsetRMS = (fNbinsRMS+2)*(iChannel+1)+1;
+ for (Int_t itrack=0; itrack<338; ++itrack){
+ TObject *iltr=arrIdeal->UncheckedAt(itrack);
+ TObject *mltr=arrMeasured->UncheckedAt(itrack);
+ (*GetDebugStreamer()) << "tracks" <<
+ "run=" << fRunNumber <<
+ "time=" << timestamp <<
+ "burst="<< iburst <<
+ "iltr.=" << iltr <<
+ "mltr.=" << mltr <<
+ "\n";
+ }
+ }
+ }
+ if (fStreamLevel>0) GetDebugStreamer()->GetFile()->Write();
+}
+
+//_____________________________________________________________________
+Int_t AliTPCCalibCE::FindLaserTrackID(Int_t sector,Int_t row, const Double_t *peakpos,Double_t &mindist,
+ const Double_t *peakposloc, Int_t &itrackMin2)
+{
+ //
+ // Find the tracks, which are closest to the ideal tracks, from clusters closest to the ideal tracks
+ //
+
+
+ TObjArray *arr=AliTPCLaserTrack::GetTracks();
+ TVector3 vP(peakpos[0],peakpos[1],peakpos[2]);
+ TVector3 vDir;
+ TVector3 vSt;
+
+ Int_t firstbeam=0;
+ Int_t lastbeam=336/2;
+ if ( (sector/18)%2 ) {
+ firstbeam=336/2;
+ lastbeam=336;
+ }
+
+ mindist=1000000;
+ Int_t itrackMin=-1;
+ for (Int_t itrack=firstbeam; itrack<lastbeam; ++itrack){
+ AliTPCLaserTrack *ltr=(AliTPCLaserTrack*)arr->At(itrack); //get the track
+// if (ltr->GetVecSec()->GetMatrixArray()[row]!=sector) continue;
+ vSt.SetXYZ(ltr->GetX(),ltr->GetY(),ltr->GetZ());
+ Double_t deltaZ=ltr->GetZ()-peakpos[2];
+ if (TMath::Abs(deltaZ)>40) continue;
+ vDir.SetMagThetaPhi(1,ltr->Theta(),TMath::ASin(ltr->GetSnp()));
+ vSt.RotateZ(ltr->GetAlpha());
+ vDir.RotateZ(ltr->GetAlpha());
+
+ Double_t dist=(vDir.Cross(vSt-vP)).Mag()/vDir.Mag();
+
+ if (dist<mindist){
+ mindist=dist;
+ itrackMin=itrack;
+ }
+
+ }
+ itrackMin2=-1;
+ Float_t mindist2=10;
+ for (Int_t itrack=firstbeam; itrack<lastbeam; ++itrack){
+ AliTPCLaserTrack *ltr=(AliTPCLaserTrack*)arr->At(itrack); //get the track
+ if ((ltr->fVecSec->GetMatrixArray())[row]!=sector) continue;
+
+ Double_t deltaZ=ltr->GetZ()-peakpos[2];
+ if (TMath::Abs(deltaZ)>40) continue;
+
+ Double_t dist=TMath::Abs((ltr->fVecLY->GetMatrixArray())[row]-peakposloc[1]);
+ if (dist>1) continue;
+
+ if (dist<mindist2){
+ mindist2=dist;
+ itrackMin2=itrack;
+ }
+ }
+ mindist=mindist2;
+ return itrackMin2;
+
+}
+
+//_____________________________________________________________________
+Bool_t AliTPCCalibCE::IsEdgePad(Int_t sector, Int_t row, Int_t pad) const
+{
+ //
+ // return true if pad is on the edge of a row
+ //
+ Int_t edge1 = 0;
+ if ( pad == edge1 ) return kTRUE;
+ Int_t edge2 = fROC->GetNPads(sector,row)-1;
+ if ( pad == edge2 ) return kTRUE;
+
+ return kFALSE;
+}
+
+//_____________________________________________________________________
+TObjArray* AliTPCCalibCE::SetupMeasured()
+{
+ //
+ // setup array of measured laser tracks and CE
+ //
+
+ TObjArray *arrIdeal = AliTPCLaserTrack::GetTracks();
+ TObjArray *arrMeasured = new TObjArray(338);
+ arrMeasured->SetOwner();
+ for(Int_t itrack=0;itrack<336;itrack++){
+ arrMeasured->AddAt(new AliTPCLaserTrack(*((AliTPCLaserTrack*)arrIdeal->At(itrack))),itrack);
+ }
+
+ //"tracks" for CE
+ AliTPCLaserTrack *ltrce=new AliTPCLaserTrack;
+ ltrce->SetId(336);
+ ltrce->SetSide(0);
+ ltrce->fVecSec=new TVectorD(557568/2);
+ ltrce->fVecP2=new TVectorD(557568/2);
+ ltrce->fVecPhi=new TVectorD(557568/2);
+ ltrce->fVecGX=new TVectorD(557568/2);
+ ltrce->fVecGY=new TVectorD(557568/2);
+ ltrce->fVecGZ=new TVectorD(557568/2);
+ ltrce->fVecLX=new TVectorD(557568/2);
+ ltrce->fVecLY=new TVectorD(557568/2);
+ ltrce->fVecLZ=new TVectorD(557568/2);
+
+ arrMeasured->AddAt(ltrce,336); //CE A-Side
+
+ ltrce=new AliTPCLaserTrack;
+ ltrce->SetId(337);
+ ltrce->SetSide(1);
+ ltrce->fVecSec=new TVectorD(557568/2);
+ ltrce->fVecP2=new TVectorD(557568/2);
+ ltrce->fVecPhi=new TVectorD(557568/2);
+ ltrce->fVecGX=new TVectorD(557568/2);
+ ltrce->fVecGY=new TVectorD(557568/2);
+ ltrce->fVecGZ=new TVectorD(557568/2);
+ ltrce->fVecLX=new TVectorD(557568/2);
+ ltrce->fVecLY=new TVectorD(557568/2);
+ ltrce->fVecLZ=new TVectorD(557568/2);
+ arrMeasured->AddAt(ltrce,337); //CE C-Side
+
+ return arrMeasured;
+}
+
+//_____________________________________________________________________
+void AliTPCCalibCE::ResetMeasured(TObjArray * const arr)
+{
+ //
+ // reset array of measured laser tracks and CE
+ //
+ for(Int_t itrack=0;itrack<338;itrack++){
+ AliTPCLaserTrack *ltr=(AliTPCLaserTrack*)arr->UncheckedAt(itrack);
+ ltr->fVecSec->Zero();
+ ltr->fVecP2->Zero();
+ ltr->fVecPhi->Zero();
+ ltr->fVecGX->Zero();
+ ltr->fVecGY->Zero();
+ ltr->fVecGZ->Zero();
+ ltr->fVecLX->Zero();
+ ltr->fVecLY->Zero();
+ ltr->fVecLZ->Zero();
+ }
+}
+
+//_____________________________________________________________________
+void AliTPCCalibCE::AddCEtoIdeal(TObjArray *arr)
+{
+ //
+ // Add ideal CE positions to the ideal track data
+ //
+
+ arr->Expand(338);
+ //"tracks" for CE
+ AliTPCLaserTrack *ltrceA=new AliTPCLaserTrack;
+ ltrceA->SetId(336);
+ ltrceA->SetSide(0);
+ ltrceA->fVecSec=new TVectorD(557568/2);
+ ltrceA->fVecP2=new TVectorD(557568/2);
+ ltrceA->fVecPhi=new TVectorD(557568/2);
+ ltrceA->fVecGX=new TVectorD(557568/2);
+ ltrceA->fVecGY=new TVectorD(557568/2);
+ ltrceA->fVecGZ=new TVectorD(557568/2);
+ ltrceA->fVecLX=new TVectorD(557568/2);
+ ltrceA->fVecLY=new TVectorD(557568/2);
+ ltrceA->fVecLZ=new TVectorD(557568/2);
+ arr->AddAt(ltrceA,336); //CE A-Side
+
+ AliTPCLaserTrack *ltrceC=new AliTPCLaserTrack;
+ ltrceC->SetId(337);
+ ltrceC->SetSide(1);
+ ltrceC->fVecSec=new TVectorD(557568/2);
+ ltrceC->fVecP2=new TVectorD(557568/2);
+ ltrceC->fVecPhi=new TVectorD(557568/2);
+ ltrceC->fVecGX=new TVectorD(557568/2);
+ ltrceC->fVecGY=new TVectorD(557568/2);
+ ltrceC->fVecGZ=new TVectorD(557568/2);
+ ltrceC->fVecLX=new TVectorD(557568/2);
+ ltrceC->fVecLY=new TVectorD(557568/2);
+ ltrceC->fVecLZ=new TVectorD(557568/2);
+ arr->AddAt(ltrceC,337); //CE C-Side
+
+ //Calculate ideal positoins
+ Float_t gxyz[3];
+ Float_t lxyz[3];
+ Int_t channelSideA=0;
+ Int_t channelSideC=0;
+ Int_t channelSide=0;
+ AliTPCLaserTrack *ltrce=0x0;
+
+ for (Int_t isector=0; isector<72; ++isector){
+ Int_t side=((isector/18)%2);
+ for (UInt_t irow=0;irow<fROC->GetNRows(isector);++irow){
+ for (UInt_t ipad=0;ipad<fROC->GetNPads(isector,irow);++ipad){
+ fROC->GetPositionGlobal(isector,irow,ipad,gxyz);
+ fROC->GetPositionLocal(isector,irow,ipad,lxyz);
+ if (side==0) {
+ ltrce=ltrceA;
+ channelSide=channelSideA;
+ } else {
+ ltrce=ltrceC;
+ channelSide=channelSideC;
+ }
+
+ ltrce->fVecSec->GetMatrixArray()[channelSide]=isector;
+ ltrce->fVecP2->GetMatrixArray()[channelSide]=0;
+ ltrce->fVecPhi->GetMatrixArray()[channelSide]=0;
+ ltrce->fVecGX->GetMatrixArray()[channelSide]=gxyz[0];
+ ltrce->fVecGY->GetMatrixArray()[channelSide]=gxyz[1];
+// ltrce->fVecGZ->GetMatrixArray()[channelSide]=-1;
+ ltrce->fVecLX->GetMatrixArray()[channelSide]=lxyz[0];
+ ltrce->fVecLY->GetMatrixArray()[channelSide]=lxyz[1];
+// ltrce->fVecLZ->GetMatrixArray()[channelSide]=-1;
+
+ if (side==0){
+ ltrce->fVecGZ->GetMatrixArray()[channelSide]=-0.335;
+ ltrce->fVecLZ->GetMatrixArray()[channelSide]=-0.335;
+ ++channelSideA;
+ }
+ else {
+ ltrce->fVecGZ->GetMatrixArray()[channelSide]=0.15;
+ ltrce->fVecLZ->GetMatrixArray()[channelSide]=0.15;
+ ++channelSideC;
+ }
+ }
+ }
+ }
+
+
+}
+
+//_____________________________________________________________________
+void AliTPCCalibCE::CalculateDV(TObjArray * const arrIdeal, TObjArray * const arrMeasured, Int_t burst)
+{
+ //
+ // calculate the drift velocity from the reconstructed clusters associated
+ // to the ideal laser tracks
+ // use two different fit scenarios: Separate fit for A- and C-Side
+ // Common fit for A- and C-Side
+ //
+
+ if (!fArrFitGraphs){
+ fArrFitGraphs=new TObjArray;
+ }
+
+// static TLinearFitter fdriftA(5,"hyp4");
+// static TLinearFitter fdriftC(5,"hyp4");
+// static TLinearFitter fdriftAC(6,"hyp5");
+ Double_t timestamp=fTimeBursts[burst];
+
+ static TLinearFitter fdriftA(4,"hyp3");
+ static TLinearFitter fdriftC(4,"hyp3");
+ static TLinearFitter fdriftAC(5,"hyp4");
+ TVectorD fitA(7),fitC(7),fitAC(8); //fit values+chi2+npoints
+
+ Float_t chi2A = 10;
+ Float_t chi2C = 10;
+ Float_t chi2AC = 10;
+ Int_t npointsA=0;
+ Int_t npointsC=0;
+ Int_t npointsAC=0;
+
+ Double_t minres[3]={20.,1,0.8};
+ //----
+ for(Int_t i=0;i<3;i++){
+
+ fdriftA.ClearPoints();
+ fdriftC.ClearPoints();
+ fdriftAC.ClearPoints();
+
+ chi2A = 10;
+ chi2C = 10;
+ chi2AC = 10;
+ npointsA=0;
+ npointsC=0;
+ npointsAC=0;
+
+ for (Int_t itrack=0; itrack<338; ++itrack){
+ AliTPCLaserTrack *iltr=(AliTPCLaserTrack*)arrIdeal->UncheckedAt(itrack);
+ AliTPCLaserTrack *mltr=(AliTPCLaserTrack*)arrMeasured->UncheckedAt(itrack);
+
+ //-- Exclude the tracks which has the biggest inclanation angle
+ if ((itrack%7==0||itrack%7==6)&&itrack<336) continue;
+ Int_t clustercounter=0;
+ Int_t indexMax=159;
- cogQ = AliMathBase::GetCOG(arrayhQ+offsetQ,fNbinsQ,fXminQ,fXmaxQ,&rms);
- fMeanQrms+=rms;
- cogTime0 = AliMathBase::GetCOG(arrayhT0+offsetT0,fNbinsT0,fXminT0,fXmaxT0,&rmsT0);
- fMeanT0rms+=rmsT0;
- cogRMS = AliMathBase::GetCOG(arrayhRMS+offsetRMS,fNbinsRMS,fXminRMS,fXmaxRMS,&rms);
- fMeanRMSrms+=rms;
- channelCounter++;
+ //-- exclude the low intensity tracks
- /*
- //outlier specifications
- if ( (cogQ < ??) && (cogTime0 > ??) && (cogTime0<??) && ( cogRMS>??) ){
- cogOut = 1;
- cogTime0 = 0;
- cogQ = 0;
- cogRMS = 0;
+ for (Int_t index=0; index<indexMax; ++index){
+
+ Double_t mGx=mltr->fVecGX->GetMatrixArray()[index];
+ Double_t mGy=mltr->fVecGY->GetMatrixArray()[index];
+ Double_t mGz=mltr->fVecGZ->GetMatrixArray()[index];
+
+ if (TMath::Abs(mGz)<1e-20 && TMath::Abs(mGy)<1e-20 && TMath::Abs(mGx)<1e-20) clustercounter++;
}
-*/
- rocQ->SetValue(iChannel, cogQ*cogQ);
- rocT0->SetValue(iChannel, cogTime0);
- rocT0Err->SetValue(iChannel, rmsT0);
- rocRMS->SetValue(iChannel, cogRMS);
- rocOut->SetValue(iChannel, cogOut);
+ if (clustercounter>130&&itrack<336) continue; // don't accept tracks with <= 159-130=29 clusters
+ clustercounter=0;
+
+ //-- drift length
+ Double_t zlength = (iltr->GetSide()==0)? fParam->GetZLength(36): fParam->GetZLength(71);
- //debug
- if ( GetStreamLevel() > 0 ){
- TTreeSRedirector *streamer=GetDebugStreamer();
- if ( streamer ) {
+ if (itrack>335) indexMax=557568/2;
+ for (Int_t index=0; index<indexMax; ++index){
+ Double_t iGx=iltr->fVecGX->GetMatrixArray()[index];
+ Double_t iGy=iltr->fVecGY->GetMatrixArray()[index];
+ Double_t iGz=iltr->fVecGZ->GetMatrixArray()[index];
+ Double_t iR=TMath::Sqrt(iGx*iGx+iGy*iGy);
- while ( iChannel > (fROC->GetRowIndexes(iSec)[row]+fROC->GetNPads(iSec,row)-1) ) row++;
- pad = iChannel-fROC->GetRowIndexes(iSec)[row];
- padc = pad-(fROC->GetNPads(iSec,row)/2);
+ Double_t mGx=mltr->fVecGX->GetMatrixArray()[index];
+ Double_t mGy=mltr->fVecGY->GetMatrixArray()[index];
+ Double_t mGz=mltr->fVecGZ->GetMatrixArray()[index];
+ Double_t mR=TMath::Sqrt(mGx*mGx+mGy*mGy);
- (*streamer) << "DataEnd" <<
- "Sector=" << iSec <<
- "Pad=" << pad <<
- "PadC=" << padc <<
- "Row=" << row <<
- "PadSec=" << iChannel <<
- "Q=" << cogQ <<
- "T0=" << cogTime0 <<
- "RMS=" << cogRMS <<
- "\n";
+ //cut if no track info available
+ if (iltr->GetBundle()==0) continue;
+ if (iR<133||mR<133) continue;
+ if(TMath::Abs(mltr->fVecP2->GetMatrixArray()[index])>minres[i]) continue;
+
+ Double_t ldrift = (iltr->GetSide()==0)?zlength-iGz:iGz+zlength;
+ Double_t mdrift = (iltr->GetSide()==0)?zlength-mGz:mGz+zlength;
+
+ //Double_t xxx[4] = {ldrift,iGy*ldrift/(zlength*250.), 250.-mR, iltr->fVecSec->GetMatrixArray()[index]>35};
+ Double_t xxx[3] = {ldrift,iGy*ldrift/(zlength*250.), 250.-mR};
+
+ if (iltr->GetSide()==0){
+ fdriftA.AddPoint(xxx,mdrift,1);
+ }else{
+ fdriftC.AddPoint(xxx,mdrift,1);
}
+// Double_t xxx2[4] = { ldrift,iGy*ldrift/(zlength*250.), 250.-mR, iltr->fVecSec->GetMatrixArray()[index]>35, iltr->GetSide()};
+ Double_t xxx2[4] = { ldrift,iGy*ldrift/(zlength*250.), 250.-mR, iltr->GetSide()};
+ fdriftAC.AddPoint(xxx2,mdrift,1);
+
+ }//end index loop
+ }//end laser track loop
+
+ //perform fit
+ fdriftA.Eval();
+ fdriftC.Eval();
+ fdriftAC.Eval();
+
+
+
+ //get fit values
+ fdriftA.GetParameters(fitA);
+ fdriftC.GetParameters(fitC);
+ fdriftAC.GetParameters(fitAC);
+
+ //Parameters: 0 linear offset
+ // 1 mean drift velocity correction factor
+ // 2 relative global y gradient
+ // 3 radial deformation
+ // 4 IROC/OROC offset
+
+// FindResiduals(arrMeasured,arrIdeal,fitA,fitC);
+
+ for (Int_t itrack=0; itrack<338; ++itrack){
+ AliTPCLaserTrack *iltr=(AliTPCLaserTrack*)arrIdeal->UncheckedAt(itrack);
+ AliTPCLaserTrack *mltr=(AliTPCLaserTrack*)arrMeasured->UncheckedAt(itrack);
+
+ //-- Exclude the tracks which has the biggest inclanation angle
+ if ((itrack%7==0||itrack%7==6)&&itrack<336) continue;
+ Int_t clustercounter=0;
+ Int_t indexMax=159;
+
+ //-- exclude the low intensity tracks
+
+ for (Int_t index=0; index<indexMax; ++index){
+ Double_t mGx=mltr->fVecGX->GetMatrixArray()[index];
+ Double_t mGy=mltr->fVecGY->GetMatrixArray()[index];
+ Double_t mGz=mltr->fVecGZ->GetMatrixArray()[index];
+ if (TMath::Abs(mGz)<1e-20 && TMath::Abs(mGy)<1e-20 && TMath::Abs(mGx)<1e-20) clustercounter++;
}
- //! debug
+ if (clustercounter>130&&itrack<336) continue; // don't accept tracks with <= 159-130=29 clusters
+ clustercounter=0;
+
+ //-- drift length
+ Double_t zlength = (iltr->GetSide()==0)? fParam->GetZLength(36): fParam->GetZLength(71);
+
+ if (itrack>335) indexMax=557568/2;
+ for (Int_t index=0; index<indexMax; ++index){
+ Double_t iGx=iltr->fVecGX->GetMatrixArray()[index];
+ Double_t iGy=iltr->fVecGY->GetMatrixArray()[index];
+ Double_t iGz=iltr->fVecGZ->GetMatrixArray()[index];
+ Double_t iR=TMath::Sqrt(iGx*iGx+iGy*iGy);
+
+ Double_t mGx=mltr->fVecGX->GetMatrixArray()[index];
+ Double_t mGy=mltr->fVecGY->GetMatrixArray()[index];
+ Double_t mGz=mltr->fVecGZ->GetMatrixArray()[index];
+ Double_t mR=TMath::Sqrt(mGx*mGx+mGy*mGy);
+
+ //cut if no track info available
+ if (iR<60||mR<60) continue;
+
+ Double_t ldrift = (iltr->GetSide()==0)?zlength-iGz:iGz+zlength;
+ Double_t mdrift = (iltr->GetSide()==0)?zlength-mGz:mGz+zlength;
+
+ TVectorD *v=&fitA;
+ if (iltr->GetSide()==1) v=&fitC;
+// Double_t iCorr=(*v)[0]+(*v)[1]*ldrift+(*v)[2]*iGy*ldrift/(zlength*250.)+(*v)[3]*(250.-mR)+(*v)[4]*( iltr->fVecSec->GetMatrixArray()[index]>35);
+ Double_t iCorr=(*v)[0]+(*v)[1]*ldrift+(*v)[2]*iGy*ldrift/(zlength*250.)+(*v)[3]*(250.-mR);
+
+ mltr->fVecP2->GetMatrixArray()[index]=mdrift-iCorr;
+
+ }
+ }
+
+ fitA.ResizeTo(7);
+ fitC.ResizeTo(7);
+ fitAC.ResizeTo(8);
+
+//set statistics values
+
+ npointsA= fdriftA.GetNpoints();
+ if (npointsA>0) chi2A = fdriftA.GetChisquare()/fdriftA.GetNpoints();
+ fitA[5]=npointsA;
+ fitA[6]=chi2A;
+
+ npointsC= fdriftC.GetNpoints();
+ if (npointsC>0) chi2C = fdriftC.GetChisquare()/fdriftC.GetNpoints();
+ fitC[5]=npointsC;
+ fitC[6]=chi2C;
+
+ npointsAC= fdriftAC.GetNpoints();
+ if (npointsAC>0) chi2AC = fdriftAC.GetChisquare()/fdriftAC.GetNpoints();
+ fitAC[5]=npointsAC;
+ fitAC[6]=chi2AC;
+
+ if (fStreamLevel>2){
+ //laser track information
+ (*GetDebugStreamer()) << "DriftV" <<
+ "iter=" << i <<
+ "run=" << fRunNumber <<
+ "time=" << timestamp <<
+ "fitA.=" << &fitA <<
+ "fitC.=" << &fitC <<
+ "fitAC.=" << &fitAC <<
+ "\n";
+
+ }
+
+ }
+//-----
+
+
+ //Parameters: 0 linear offset (global)
+ // 1 mean drift velocity correction factor
+ // 2 relative global y gradient
+ // 3 radial deformation
+ // 4 IROC/OROC offset
+ // 5 linear offset relative A-C
+
+ //get graphs
+ TGraphErrors *grA[7];
+ TGraphErrors *grC[7];
+ TGraphErrors *grAC[8];
+ TString names("GRAPH_MEAN_DELAY_LASER_ALL_;GRAPH_MEAN_DRIFT_LASER_ALL_;GRAPH_MEAN_GLOBALYGRADIENT_LASER_ALL_;GRAPH_MEAN_RGRADIENT_LASER_ALL_;GRAPH_MEAN_IROCOROCOFFSET_LASER_ALL_;GRAPH_MEAN_NPOINTS_LASER_ALL_;GRAPH_MEAN_CHI2_LASER_ALL_");
+ TString namesAC("GRAPH_MEAN_DELAY_LASER_ALL_;GRAPH_MEAN_DRIFT_LASER_ALL_;GRAPH_MEAN_GLOBALYGRADIENT_LASER_ALL_;GRAPH_MEAN_RGRADIENT_LASER_ALL_;GRAPH_MEAN_IROCOROCOFFSET_LASER_ALL_;GRAPH_MEAN_NPOINTS_LASER_ALL_;GRAPH_MEAN_CHI2_LASER_ALL_;GRAPH_MEAN_DELAYC_LASER_ALL_");
+
+ TObjArray *arrNames=names.Tokenize(";");
+ TObjArray *arrNamesAC=namesAC.Tokenize(";");
+
+ //A-Side graphs
+ for (Int_t i=0; i<7; ++i){
+ TString grName=arrNames->UncheckedAt(i)->GetName();
+ grName+="A";
+ grA[i]=(TGraphErrors*)fArrFitGraphs->FindObject(grName.Data());
+ if (!grA[i]){
+ grA[i]=new TGraphErrors;
+ grA[i]->SetName(grName.Data());
+ grA[i]->SetTitle(grName.ReplaceAll("_"," ").Data());
+ fArrFitGraphs->Add(grA[i]);
+ }
+// Int_t ipoint=grA[i]->GetN();
+ Int_t ipoint=burst;
+ grA[i]->SetPoint(ipoint,timestamp,fitA(i));
+ grA[i]->SetPointError(ipoint,60,.0001);
+ if (i<4) grA[i]->SetPointError(ipoint,60,fdriftA.GetCovarianceMatrixElement(i,i));
+ }
+
+ //C-Side graphs
+ for (Int_t i=0; i<7; ++i){
+ TString grName=arrNames->UncheckedAt(i)->GetName();
+ grName+="C";
+ grC[i]=(TGraphErrors*)fArrFitGraphs->FindObject(grName.Data());
+ if (!grC[i]){
+ grC[i]=new TGraphErrors;
+ grC[i]->SetName(grName.Data());
+ grC[i]->SetTitle(grName.ReplaceAll("_"," ").Data());
+ fArrFitGraphs->Add(grC[i]);
+ }
+// Int_t ipoint=grC[i]->GetN();
+ Int_t ipoint=burst;
+ grC[i]->SetPoint(ipoint,timestamp,fitC(i));
+ grC[i]->SetPointError(ipoint,60,.0001);
+ if (i<4) grC[i]->SetPointError(ipoint,60,fdriftC.GetCovarianceMatrixElement(i,i));
+ }
+
+ //AC-Side graphs
+ for (Int_t i=0; i<8; ++i){
+ TString grName=arrNamesAC->UncheckedAt(i)->GetName();
+ grName+="AC";
+ grAC[i]=(TGraphErrors*)fArrFitGraphs->FindObject(grName.Data());
+ if (!grAC[i]){
+ grAC[i]=new TGraphErrors;
+ grAC[i]->SetName(grName.Data());
+ grAC[i]->SetTitle(grName.ReplaceAll("_"," ").Data());
+ fArrFitGraphs->Add(grAC[i]);
+ }
+// Int_t ipoint=grAC[i]->GetN();
+ Int_t ipoint=burst;
+ grAC[i]->SetPoint(ipoint,timestamp,fitAC(i));
+ grAC[i]->SetPointError(ipoint,60,.0001);
+ if (i<5) grAC[i]->SetPointError(ipoint,60,fdriftAC.GetCovarianceMatrixElement(i,i));
+ }
+
+ if (fDebugLevel>10){
+ printf("A side fit parameters:\n");
+ fitA.Print();
+ printf("\nC side fit parameters:\n");
+ fitC.Print();
+ printf("\nAC side fit parameters:\n");
+ fitAC.Print();
+ }
+ delete arrNames;
+ delete arrNamesAC;
+}
+
+//_____________________________________________________________________
+Double_t AliTPCCalibCE::SetBurstHnDrift()
+{
+ //
+ // Create a new THnSparse for the current burst
+ // return the time of the current burst
+ //
+ Int_t i=0;
+ for(i=0; i<fTimeBursts.GetNrows(); ++i){
+ if(fTimeBursts.GetMatrixArray()[i]<1.e-20) break;
+ if(TMath::Abs(fTimeBursts.GetMatrixArray()[i]-fTimeStamp)<300){
+ fHnDrift=(THnSparseI*)fArrHnDrift.UncheckedAt(i);
+ return fTimeBursts(i);
+ }
+ }
+
+ CreateDVhist();
+ fArrHnDrift.AddAt(fHnDrift,i);
+ fTimeBursts.GetMatrixArray()[i]=fTimeStamp;
+ for (i=0;i<14;++i){
+ fPeaks[i]=0;
+ fPeakWidths[i]=0;
+ }
+ fEventInBunch=0;
+ return fTimeStamp;
+}
+
+//_____________________________________________________________________
+void AliTPCCalibCE::DumpToFile(const Char_t *filename, const Char_t *dir, Bool_t /*append*/)
+{
+ //
+ // Write class to file
+ // option can be specified in the dir option:
+ // options:
+ // name=<objname>: the name of the calibration object in file will be <objname>
+ // type=<type>: the saving type:
+ // 0 - write the complte object
+ // 1 - Store the histogram arrays separately to make the streamed object smaller, Analyse to be called
+ // 2 - like 2, but in addition delete objects that will most probably not be used for calibration
+ // 3 - store only calibration output, don't store the reference histograms
+ // and THnSparse (requires Analyse called before)
+ //
+ // NOTE: to read the object back, the ReadFromFile function should be used
+ //
+
+ TString sDir(dir);
+ TString objName=GetName();
+ Int_t type=0;
+
+ //get options
+ TObjArray *arr=sDir.Tokenize(",");
+ TIter next(arr);
+ TObjString *s;
+ while ( (s=(TObjString*)next()) ){
+ TString optString=s->GetString();
+ optString.Remove(TString::kBoth,' ');
+ if (optString.BeginsWith("name=")){
+ objName=optString.ReplaceAll("name=","");
}
+ if (optString.BeginsWith("type=")){
+ optString.ReplaceAll("type=","");
+ type=optString.Atoi();
+ }
+ }
+
+ if ( type==4 ){
+ // only for the new algorithm
+ AliTPCCalibCE ce;
+ ce.fArrFitGraphs=fArrFitGraphs;
+ ce.fNevents=fNevents;
+ ce.fTimeBursts.ResizeTo(fTimeBursts.GetNrows());
+ ce.fTimeBursts=fTimeBursts;
+ ce.fProcessNew=kTRUE;
+ TFile f(filename,"recreate");
+ ce.Write(objName.Data());
+ fArrHnDrift.Write("arrHnDrift",TObject::kSingleKey);
+ f.Close();
+ ce.fArrFitGraphs=0x0;
+ return;
+ }
+
+
+ if (type==1||type==2) {
+ //delete most probably not needed stuff
+ //This requires Analyse to be called after reading the object from file
+ fCalRocArrayT0.Delete();
+ fCalRocArrayT0Err.Delete();
+ fCalRocArrayQ.Delete();
+ fCalRocArrayRMS.Delete();
+ fCalRocArrayOutliers.Delete();
+ }
+ if (type==2||type==3){
+ fParamArrayEventPol1.Delete();
+ fParamArrayEventPol2.Delete();
+ }
+
+ TObjArray histoQArray(72);
+ TObjArray histoT0Array(72);
+ TObjArray histoRMSArray(72);
+ TObjArray arrHnDrift(fArrHnDrift.GetEntries());
+
+ //save all large 2D histograms in separte pointers
+ //to have a smaller memory print when saving the object
+ if (type==1||type==2||type==3){
+ for (Int_t i=0; i<72; ++i){
+ histoQArray.AddAt(fHistoQArray.UncheckedAt(i),i);
+ histoT0Array.AddAt(fHistoT0Array.UncheckedAt(i),i);
+ histoRMSArray.AddAt(fHistoRMSArray.UncheckedAt(i),i);
+ }
+ fHistoQArray.SetOwner(kFALSE);
+ fHistoT0Array.SetOwner(kFALSE);
+ fHistoRMSArray.SetOwner(kFALSE);
+ fHistoQArray.Clear();
+ fHistoT0Array.Clear();
+ fHistoRMSArray.Clear();
+ for (Int_t i=0;i<fArrHnDrift.GetEntries();++i){
+ arrHnDrift.AddAt(fArrHnDrift.UncheckedAt(i),i);
+ }
+ fArrHnDrift.SetOwner(kFALSE);
+ fArrHnDrift.Clear();
+ }
+
+
+ TDirectory *backup = gDirectory;
+
+ TFile f(filename,"recreate");
+ Write(objName.Data());
+ if (type==1||type==2) {
+ histoQArray.Write("histoQArray",TObject::kSingleKey);
+ histoT0Array.Write("histoT0Array",TObject::kSingleKey);
+ histoRMSArray.Write("histoRMSArray",TObject::kSingleKey);
+ arrHnDrift.Write("arrHnDrift",TObject::kSingleKey);
+ }
+
+ f.Save();
+ f.Close();
+
+ //move histograms back to the object
+ if (type==1||type==2){
+ for (Int_t i=0; i<72; ++i){
+ fHistoQArray.AddAt(histoQArray.UncheckedAt(i),i);
+ fHistoT0Array.AddAt(histoT0Array.UncheckedAt(i),i);
+ fHistoRMSArray.AddAt(histoRMSArray.UncheckedAt(i),i);
+ }
+ fHistoQArray.SetOwner(kTRUE);
+ fHistoT0Array.SetOwner(kTRUE);
+ fHistoRMSArray.SetOwner(kTRUE);
+
+ for (Int_t i=0;i<arrHnDrift.GetEntries();++i){
+ fArrHnDrift.AddAt(arrHnDrift.UncheckedAt(i),i);
+ }
+ fArrHnDrift.SetOwner(kTRUE);
}
- if ( channelCounter>0 ){
- fMeanT0rms/=channelCounter;
- fMeanQrms/=channelCounter;
- fMeanRMSrms/=channelCounter;
+
+ if ( backup ) backup->cd();
+}
+//_____________________________________________________________________
+AliTPCCalibCE* AliTPCCalibCE::ReadFromFile(const Char_t *filename)
+{
+ //
+ // Read object from file
+ // Handle properly if the histogram arrays were stored separately
+ // call Analyse to make sure to have the calibration relevant information in the object
+ //
+
+ TFile f(filename);
+ if (!f.IsOpen() || f.IsZombie() ) return 0x0;
+ TList *l=f.GetListOfKeys();
+ TIter next(l);
+ TKey *key=0x0;
+ TObject *o=0x0;
+
+ AliTPCCalibCE *ce=0x0;
+ TObjArray *histoQArray=0x0;
+ TObjArray *histoT0Array=0x0;
+ TObjArray *histoRMSArray=0x0;
+ TObjArray *arrHnDrift=0x0;
+
+ while ( (key=(TKey*)next()) ){
+ o=key->ReadObj();
+ if ( o->IsA()==AliTPCCalibCE::Class() ){
+ ce=(AliTPCCalibCE*)o;
+ } else if ( o->IsA()==TObjArray::Class() ){
+ TString name=key->GetName();
+ if ( name=="histoQArray") histoQArray=(TObjArray*)o;
+ if ( name=="histoT0Array") histoT0Array=(TObjArray*)o;
+ if ( name=="histoRMSArray") histoRMSArray=(TObjArray*)o;
+ if ( name=="arrHnDrift") arrHnDrift=(TObjArray*)o;
+ }
}
-// if ( fDebugStreamer ) fDebugStreamer->GetFile()->Write();
-// delete fDebugStreamer;
-// fDebugStreamer = 0x0;
- fVEventTime.ResizeTo(fNevents);
- fVEventNumber.ResizeTo(fNevents);
- fVTime0SideA.ResizeTo(fNevents);
- fVTime0SideC.ResizeTo(fNevents);
+
+ if (ce){
+ //move histograms back to the object
+ TH1* hist=0x0;
+ if (histoQArray){
+ for (Int_t i=0; i<72; ++i){
+ hist=(TH1*)histoQArray->UncheckedAt(i);
+ if (hist) hist->SetDirectory(0x0);
+ ce->fHistoQArray.AddAt(hist,i);
+ }
+ ce->fHistoQArray.SetOwner(kTRUE);
+ }
+
+ if (histoT0Array) {
+ for (Int_t i=0; i<72; ++i){
+ hist=(TH1*)histoT0Array->UncheckedAt(i);
+ if (hist) hist->SetDirectory(0x0);
+ ce->fHistoT0Array.AddAt(hist,i);
+ }
+ ce->fHistoT0Array.SetOwner(kTRUE);
+ }
+
+ if (histoRMSArray){
+ for (Int_t i=0; i<72; ++i){
+ hist=(TH1*)histoRMSArray->UncheckedAt(i);
+ if (hist) hist->SetDirectory(0x0);
+ ce->fHistoRMSArray.AddAt(hist,i);
+ }
+ ce->fHistoRMSArray.SetOwner(kTRUE);
+ }
+
+ if (arrHnDrift){
+ for (Int_t i=0; i<arrHnDrift->GetEntries(); ++i){
+ THnSparseI *hSparse=(THnSparseI*)arrHnDrift->UncheckedAt(i);
+ ce->fArrHnDrift.AddAt(hSparse,i);
+ }
+ }
+
+ ce->Analyse();
+ }
+ f.Close();
+
+ return ce;
}