// Origin: Marian Ivanov
//-------------------------------------------------------
-#include "AliTPCclustererMI.h"
-#include "AliTPCclusterMI.h"
-#include <TObjArray.h>
+#include "Riostream.h"
+#include <TF1.h>
#include <TFile.h>
-#include "AliTPCClustersArray.h"
-#include "AliTPCClustersRow.h"
+#include <TGraph.h>
+#include <TH1F.h>
+#include <TObjArray.h>
+#include <TRandom.h>
+#include <TTree.h>
+#include <TTreeStream.h>
+#include <TVirtualFFT.h>
+
#include "AliDigits.h"
+#include "AliLoader.h"
+#include "AliLog.h"
+#include "AliMathBase.h"
+#include "AliRawEventHeaderBase.h"
+#include "AliRawReader.h"
+#include "AliRunLoader.h"
#include "AliSimDigits.h"
+#include "AliTPCCalPad.h"
+#include "AliTPCCalROC.h"
+#include "AliTPCClustersArray.h"
+#include "AliTPCClustersRow.h"
#include "AliTPCParam.h"
-#include "Riostream.h"
-#include <TTree.h>
+#include "AliTPCRawStream.h"
+#include "AliTPCRecoParam.h"
+#include "AliTPCReconstructor.h"
+#include "AliTPCcalibDB.h"
+#include "AliTPCclusterInfo.h"
+#include "AliTPCclusterMI.h"
+#include "AliTPCTransform.h"
+#include "AliTPCclustererMI.h"
ClassImp(AliTPCclustererMI)
-AliTPCclustererMI::AliTPCclustererMI()
+AliTPCclustererMI::AliTPCclustererMI(const AliTPCParam* par, const AliTPCRecoParam * recoParam):
+ fBins(0),
+ fSigBins(0),
+ fNSigBins(0),
+ fLoop(0),
+ fMaxBin(0),
+ fMaxTime(0),
+ fMaxPad(0),
+ fSector(-1),
+ fRow(-1),
+ fSign(0),
+ fRx(0),
+ fPadWidth(0),
+ fPadLength(0),
+ fZWidth(0),
+ fPedSubtraction(kFALSE),
+ fIsOldRCUFormat(kFALSE),
+ fEventHeader(0),
+ fTimeStamp(0),
+ fEventType(0),
+ fInput(0),
+ fOutput(0),
+ fRowCl(0),
+ fRowDig(0),
+ fParam(0),
+ fNcluster(0),
+ fAmplitudeHisto(0),
+ fDebugStreamer(0),
+ fRecoParam(0),
+ fBDumpSignal(kFALSE),
+ fFFTr2c(0)
{
+ //
+ // COSNTRUCTOR
+ // param - tpc parameters for given file
+ // recoparam - reconstruction parameters
+ //
+ fIsOldRCUFormat = kFALSE;
fInput =0;
fOutput=0;
+ fParam = par;
+ if (recoParam) {
+ fRecoParam = recoParam;
+ }else{
+ //set default parameters if not specified
+ fRecoParam = AliTPCReconstructor::GetRecoParam();
+ if (!fRecoParam) fRecoParam = AliTPCRecoParam::GetLowFluxParam();
+ }
+ fDebugStreamer = new TTreeSRedirector("TPCsignal.root");
+ fAmplitudeHisto = 0;
+ Int_t nPoints = fRecoParam->GetLastBin()-fRecoParam->GetFirstBin();
+ fFFTr2c = TVirtualFFT::FFT(1, &nPoints, "R2C K");
+}
+//______________________________________________________________
+AliTPCclustererMI::AliTPCclustererMI(const AliTPCclustererMI ¶m)
+ :TObject(param),
+ fBins(0),
+ fSigBins(0),
+ fNSigBins(0),
+ fLoop(0),
+ fMaxBin(0),
+ fMaxTime(0),
+ fMaxPad(0),
+ fSector(-1),
+ fRow(-1),
+ fSign(0),
+ fRx(0),
+ fPadWidth(0),
+ fPadLength(0),
+ fZWidth(0),
+ fPedSubtraction(kFALSE),
+ fIsOldRCUFormat(kFALSE),
+ fEventHeader(0),
+ fTimeStamp(0),
+ fEventType(0),
+ fInput(0),
+ fOutput(0),
+ fRowCl(0),
+ fRowDig(0),
+ fParam(0),
+ fNcluster(0),
+ fAmplitudeHisto(0),
+ fDebugStreamer(0),
+ fRecoParam(0),
+ fBDumpSignal(kFALSE),
+ fFFTr2c(0)
+{
+ //
+ // dummy
+ //
+ fMaxBin = param.fMaxBin;
+}
+//______________________________________________________________
+AliTPCclustererMI & AliTPCclustererMI::operator =(const AliTPCclustererMI & param)
+{
+ //
+ // assignment operator - dummy
+ //
+ fMaxBin=param.fMaxBin;
+ return (*this);
}
+//______________________________________________________________
+AliTPCclustererMI::~AliTPCclustererMI(){
+ DumpHistos();
+ if (fAmplitudeHisto) delete fAmplitudeHisto;
+ if (fDebugStreamer) delete fDebugStreamer;
+}
+
void AliTPCclustererMI::SetInput(TTree * tree)
{
//
Float_t AliTPCclustererMI::GetSigmaY2(Int_t iz){
// sigma y2 = in digits - we don't know the angle
- Float_t z = iz*fParam->GetZWidth();
+ Float_t z = iz*fParam->GetZWidth()+fParam->GetNTBinsL1()*fParam->GetZWidth();
Float_t sd2 = (z*fParam->GetDiffL()*fParam->GetDiffL())/
(fPadWidth*fPadWidth);
Float_t sres = 0.25;
Float_t AliTPCclustererMI::GetSigmaZ2(Int_t iz){
//sigma z2 = in digits - angle estimated supposing vertex constraint
- Float_t z = iz*fZWidth;
+ Float_t z = iz*fZWidth+fParam->GetNTBinsL1()*fParam->GetZWidth();
Float_t sd2 = (z*fParam->GetDiffL()*fParam->GetDiffL())/(fZWidth*fZWidth);
- Float_t angular = fPadLength*(fParam->GetZLength()-z)/(fRx*fZWidth);
+ Float_t angular = fPadLength*(fParam->GetZLength(fSector)-z)/(fRx*fZWidth);
angular*=angular;
angular/=12.;
Float_t sres = fParam->GetZSigma()/fZWidth;
return res;
}
-void AliTPCclustererMI::MakeCluster(Int_t k,Int_t max,Int_t *bins, UInt_t m,
+void AliTPCclustererMI::MakeCluster(Int_t k,Int_t max,Float_t *bins, UInt_t /*m*/,
AliTPCclusterMI &c)
{
+ //
+ // k - Make cluster at position k
+ // bins - 2 D array of signals mapped to 1 dimensional array -
+ // max - the number of time bins er one dimension
+ // c - refernce to cluster to be filled
+ //
Int_t i0=k/max; //central pad
Int_t j0=k%max; //central time bin
// set pointers to data
//Int_t dummy[5] ={0,0,0,0,0};
- Int_t * matrix[5]; //5x5 matrix with digits - indexing i = 0 ..4 j = -2..2
- Int_t * resmatrix[5];
+ Float_t * matrix[5]; //5x5 matrix with digits - indexing i = 0 ..4 j = -2..2
for (Int_t di=-2;di<=2;di++){
matrix[di+2] = &bins[k+di*max];
- resmatrix[di+2] = &fResBins[k+di*max];
}
//build matrix with virtual charge
Float_t sigmay2= GetSigmaY2(j0);
Float_t vmatrix[5][5];
vmatrix[2][2] = matrix[2][0];
c.SetType(0);
- c.SetMax(Short_t(vmatrix[2][2])); // write maximal amplitude
+ c.SetMax((UShort_t)(vmatrix[2][2])); // write maximal amplitude
for (Int_t di =-1;di <=1;di++)
for (Int_t dj =-1;dj <=1;dj++){
Float_t amp = matrix[di+2][dj];
//
if ( ( (ry<0.6) || (rz<0.6) ) && fLoop==2) return;
- if ( (ry <1.2) && (rz<1.2) ) {
- //if cluster looks like expected
+ if ( (ry <1.2) && (rz<1.2) || (!fRecoParam->GetDoUnfold())) {
+ //
+ //if cluster looks like expected or Unfolding not switched on
+ //standard COG is used
//+1.2 deviation from expected sigma accepted
// c.fMax = FitMax(vmatrix,meani,meanj,TMath::Sqrt(sigmay2),TMath::Sqrt(sigmaz2));
meanj +=j0;
//set cluster parameters
c.SetQ(sumw);
- c.SetY(meani*fPadWidth);
- c.SetZ(meanj*fZWidth);
+ c.SetPad(meani-2.5);
+ c.SetTimeBin(meanj-2.5);
c.SetSigmaY2(mi2);
c.SetSigmaZ2(mj2);
- AddCluster(c);
- //remove cluster data from data
- for (Int_t di=-2;di<=2;di++)
- for (Int_t dj=-2;dj<=2;dj++){
- resmatrix[di+2][dj] -= Int_t(vmatrix[di+2][dj+2]);
- if (resmatrix[di+2][dj]<0) resmatrix[di+2][dj]=0;
- }
- resmatrix[2][0] =0;
+ c.SetType(0);
+ AddCluster(c,(Float_t*)vmatrix,k);
return;
}
//
//unfolding when neccessary
//
- Int_t * matrix2[7]; //7x7 matrix with digits - indexing i = 0 ..6 j = -3..3
- Int_t dummy[7]={0,0,0,0,0,0};
+ Float_t * matrix2[7]; //7x7 matrix with digits - indexing i = 0 ..6 j = -3..3
+ Float_t dummy[7]={0,0,0,0,0,0};
for (Int_t di=-3;di<=3;di++){
matrix2[di+3] = &bins[k+di*max];
if ((k+di*max)<3) matrix2[di+3] = &dummy[3];
meanj +=j0;
//set cluster parameters
c.SetQ(sumu);
- c.SetY(meani*fPadWidth);
- c.SetZ(meanj*fZWidth);
+ c.SetPad(meani-2.5);
+ c.SetTimeBin(meanj-3);
c.SetSigmaY2(mi2);
c.SetSigmaZ2(mj2);
c.SetType(Char_t(overlap)+1);
- AddCluster(c);
+ AddCluster(c,(Float_t*)vmatrix,k);
//unfolding 2
meani-=i0;
-void AliTPCclustererMI::UnfoldCluster(Int_t * matrix2[7], Float_t recmatrix[5][5], Float_t & meani, Float_t & meanj,
+void AliTPCclustererMI::UnfoldCluster(Float_t * matrix2[7], Float_t recmatrix[5][5], Float_t & meani, Float_t & meanj,
Float_t & sumu, Float_t & overlap )
{
//
return max;
}
-void AliTPCclustererMI::AddCluster(AliTPCclusterMI &c){
+void AliTPCclustererMI::AddCluster(AliTPCclusterMI &c, Float_t * matrix, Int_t pos){
//
- // transform cluster to the global coordinata
- // add the cluster to the array
//
- Float_t meani = c.GetY()/fPadWidth;
- Float_t meanj = c.GetZ()/fZWidth;
+ // Transform cluster to the rotated global coordinata
+ // Assign labels to the cluster
+ // add the cluster to the array
+ // for more details - See AliTPCTranform::Transform(x,i,0,1)
+ Float_t meani = c.GetPad();
+ Float_t meanj = c.GetTimeBin();
- Int_t ki = TMath::Nint(meani-3);
+ Int_t ki = TMath::Nint(meani);
if (ki<0) ki=0;
if (ki>=fMaxPad) ki = fMaxPad-1;
- Int_t kj = TMath::Nint(meanj-3);
+ Int_t kj = TMath::Nint(meanj);
if (kj<0) kj=0;
if (kj>=fMaxTime-3) kj=fMaxTime-4;
- // ki and kj shifted to "real" coordinata
- c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,0)-2,0);
- c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,1)-2,1);
- c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,2)-2,2);
-
+ // ki and kj shifted as integers coordinata
+ if (fRowDig) {
+ c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,0)-2,0);
+ c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,1)-2,1);
+ c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,2)-2,2);
+ }
+ c.SetRow(fRow);
+ c.SetDetector(fSector);
Float_t s2 = c.GetSigmaY2();
Float_t w=fParam->GetPadPitchWidth(fSector);
-
c.SetSigmaY2(s2*w*w);
s2 = c.GetSigmaZ2();
- w=fZWidth;
- c.SetSigmaZ2(s2*w*w);
- c.SetY((meani - 2.5 - 0.5*fMaxPad)*fParam->GetPadPitchWidth(fSector));
- c.SetZ(fZWidth*(meanj-3));
- c.SetZ(c.GetZ() - 3.*fParam->GetZSigma()); // PASA delay
- c.SetZ(fSign*(fParam->GetZLength() - c.GetZ()));
-
+ c.SetSigmaZ2(s2*fZWidth*fZWidth);
+ //
+ //
+ //
+ AliTPCTransform *transform = AliTPCcalibDB::Instance()->GetTransform() ;
+ if (!transform) {
+ AliFatal("Tranformations not in calibDB");
+ }
+ Double_t x[3]={c.GetRow(),c.GetPad(),c.GetTimeBin()};
+ Int_t i[1]={fSector};
+ transform->Transform(x,i,0,1);
+ c.SetX(x[0]);
+ c.SetY(x[1]);
+ c.SetZ(x[2]);
+ //
+ //
+ if (!fRecoParam->GetBYMirror()){
+ if (fSector%36>17){
+ c.SetY(-c.GetY());
+ }
+ }
+
if (ki<=1 || ki>=fMaxPad-1 || kj==1 || kj==fMaxTime-2) {
- //c.SetSigmaY2(c.GetSigmaY2()*25.);
- //c.SetSigmaZ2(c.GetSigmaZ2()*4.);
c.SetType(-(c.GetType()+3)); //edge clusters
}
if (fLoop==2) c.SetType(100);
TClonesArray * arr = fRowCl->GetArray();
- // AliTPCclusterMI * cl =
- new ((*arr)[fNcluster]) AliTPCclusterMI(c);
+ AliTPCclusterMI * cl = new ((*arr)[fNcluster]) AliTPCclusterMI(c);
+ if (fRecoParam->DumpSignal() &&matrix ) {
+ Int_t nbins=0;
+ Float_t *graph =0;
+ if (fRecoParam->GetCalcPedestal() && cl->GetMax()>fRecoParam->GetDumpAmplitudeMin() &&fBDumpSignal){
+ nbins = fMaxTime;
+ graph = &(fBins[fMaxTime*(pos/fMaxTime)]);
+ }
+ AliTPCclusterInfo * info = new AliTPCclusterInfo(matrix,nbins,graph);
+ cl->SetInfo(info);
+ }
+ if (!fRecoParam->DumpSignal()) {
+ cl->SetInfo(0);
+ }
fNcluster++;
}
//_____________________________________________________________________________
-void AliTPCclustererMI::Digits2Clusters(const AliTPCParam *par, Int_t eventn)
+void AliTPCclustererMI::Digits2Clusters()
{
//-----------------------------------------------------------------
// This is a simple cluster finder.
//-----------------------------------------------------------------
- TDirectory *savedir=gDirectory;
- if (fInput==0){
- cerr<<"AliTPC::Digits2Clusters(): input tree not initialised !\n";
+ if (!fInput) {
+ Error("Digits2Clusters", "input tree not initialised");
return;
}
- if (fOutput==0) {
- cerr<<"AliTPC::Digits2Clusters(): output tree not initialised !\n";
- return;
+ if (!fOutput) {
+ Error("Digits2Clusters", "output tree not initialised");
+ return;
}
+ AliTPCCalPad * gainTPC = AliTPCcalibDB::Instance()->GetPadGainFactor();
+ AliTPCCalPad * noiseTPC = AliTPCcalibDB::Instance()->GetPadNoise();
AliSimDigits digarr, *dummy=&digarr;
fRowDig = dummy;
fInput->GetBranch("Segment")->SetAddress(&dummy);
Stat_t nentries = fInput->GetEntries();
- fMaxTime=par->GetMaxTBin()+6; // add 3 virtual time bins before and 3 after
+ fMaxTime=fParam->GetMaxTBin()+6; // add 3 virtual time bins before and 3 after
- fParam = par;
- ((AliTPCParam*)par)->Write(par->GetTitle());
-
Int_t nclusters = 0;
-
+
for (Int_t n=0; n<nentries; n++) {
fInput->GetEvent(n);
- Int_t row;
- if (!par->AdjustSectorRow(digarr.GetID(),fSector,row)) {
+ if (!fParam->AdjustSectorRow(digarr.GetID(),fSector,fRow)) {
cerr<<"AliTPC warning: invalid segment ID ! "<<digarr.GetID()<<endl;
continue;
}
-
+ Int_t row = fRow;
+ AliTPCCalROC * gainROC = gainTPC->GetCalROC(fSector); // pad gains per given sector
+ AliTPCCalROC * noiseROC = noiseTPC->GetCalROC(fSector); // noise per given sector
+ //
AliTPCClustersRow *clrow= new AliTPCClustersRow();
fRowCl = clrow;
clrow->SetClass("AliTPCclusterMI");
clrow->SetID(digarr.GetID());
fOutput->GetBranch("Segment")->SetAddress(&clrow);
- fRx=par->GetPadRowRadii(fSector,row);
+ fRx=fParam->GetPadRowRadii(fSector,row);
- const Int_t kNIS=par->GetNInnerSector(), kNOS=par->GetNOuterSector();
+ const Int_t kNIS=fParam->GetNInnerSector(), kNOS=fParam->GetNOuterSector();
fZWidth = fParam->GetZWidth();
if (fSector < kNIS) {
- fMaxPad = par->GetNPadsLow(row);
+ fMaxPad = fParam->GetNPadsLow(row);
fSign = (fSector < kNIS/2) ? 1 : -1;
- fPadLength = par->GetPadPitchLength(fSector,row);
- fPadWidth = par->GetPadPitchWidth();
+ fPadLength = fParam->GetPadPitchLength(fSector,row);
+ fPadWidth = fParam->GetPadPitchWidth();
} else {
- fMaxPad = par->GetNPadsUp(row);
+ fMaxPad = fParam->GetNPadsUp(row);
fSign = ((fSector-kNIS) < kNOS/2) ? 1 : -1;
- fPadLength = par->GetPadPitchLength(fSector,row);
- fPadWidth = par->GetPadPitchWidth();
+ fPadLength = fParam->GetPadPitchLength(fSector,row);
+ fPadWidth = fParam->GetPadPitchWidth();
}
fMaxBin=fMaxTime*(fMaxPad+6); // add 3 virtual pads before and 3 after
- fBins =new Int_t[fMaxBin];
- fResBins =new Int_t[fMaxBin]; //fBins with residuals after 1 finder loop
- memset(fBins,0,sizeof(Int_t)*fMaxBin);
+ fBins =new Float_t[fMaxBin];
+ fSigBins =new Int_t[fMaxBin];
+ fNSigBins = 0;
+ memset(fBins,0,sizeof(Float_t)*fMaxBin);
if (digarr.First()) //MI change
do {
- Short_t dig=digarr.CurrentDigit();
- if (dig<=par->GetZeroSup()) continue;
+ Float_t dig=digarr.CurrentDigit();
+ if (dig<=fParam->GetZeroSup()) continue;
Int_t j=digarr.CurrentRow()+3, i=digarr.CurrentColumn()+3;
- fBins[i*fMaxTime+j]=dig;
+ Float_t gain = gainROC->GetValue(row,digarr.CurrentColumn());
+ Int_t bin = i*fMaxTime+j;
+ fBins[bin]=dig/gain;
+ fSigBins[fNSigBins++]=bin;
} while (digarr.Next());
digarr.ExpandTrackBuffer();
- //add virtual charge at the edge
- for (Int_t i=0; i<fMaxTime; i++){
- Float_t amp1 = fBins[i+3*fMaxTime];
- Float_t amp0 =0;
- if (amp1>0){
- Float_t amp2 = fBins[i+4*fMaxTime];
- if (amp2==0) amp2=0.5;
- Float_t sigma2 = GetSigmaY2(i);
- amp0 = (amp1*amp1/amp2)*TMath::Exp(-1./sigma2);
- if (gDebug>4) printf("\n%f\n",amp0);
- }
- fBins[i+2*fMaxTime] = Int_t(amp0);
- amp0 = 0;
- amp1 = fBins[(fMaxPad+2)*fMaxTime+i];
- if (amp1>0){
- Float_t amp2 = fBins[i+(fMaxPad+1)*fMaxTime];
- if (amp2==0) amp2=0.5;
- Float_t sigma2 = GetSigmaY2(i);
- amp0 = (amp1*amp1/amp2)*TMath::Exp(-1./sigma2);
- if (gDebug>4) printf("\n%f\n",amp0);
- }
- fBins[(fMaxPad+3)*fMaxTime+i] = Int_t(amp0);
+ FindClusters(noiseROC);
+
+ fOutput->Fill();
+ delete clrow;
+ nclusters+=fNcluster;
+ delete[] fBins;
+ delete[] fSigBins;
+ }
+
+ Info("Digits2Clusters", "Number of found clusters : %d", nclusters);
+}
+
+void AliTPCclustererMI::Digits2Clusters(AliRawReader* rawReader)
+{
+//-----------------------------------------------------------------
+// This is a cluster finder for the TPC raw data.
+// The method assumes NO ordering of the altro channels.
+// The pedestal subtraction can be switched on and off
+// using an option of the TPC reconstructor
+//-----------------------------------------------------------------
+
+ if (!fOutput) {
+ Error("Digits2Clusters", "output tree not initialised");
+ return;
+ }
+
+ fRowDig = NULL;
+ AliTPCROC * roc = AliTPCROC::Instance();
+ AliTPCCalPad * gainTPC = AliTPCcalibDB::Instance()->GetPadGainFactor();
+ AliTPCCalPad * pedestalTPC = AliTPCcalibDB::Instance()->GetPedestals();
+ AliTPCCalPad * noiseTPC = AliTPCcalibDB::Instance()->GetPadNoise();
+ AliTPCAltroMapping** mapping =AliTPCcalibDB::Instance()->GetMapping();
+ //
+ AliTPCRawStream input(rawReader,(AliAltroMapping**)mapping);
+ fEventHeader = (AliRawEventHeaderBase*)rawReader->GetEventHeader();
+ if (fEventHeader){
+ fTimeStamp = fEventHeader->Get("Timestamp");
+ fEventType = fEventHeader->Get("Type");
+ }
+
+
+ Int_t nclusters = 0;
+
+ fMaxTime = fParam->GetMaxTBin() + 6; // add 3 virtual time bins before and 3 after
+ const Int_t kNIS = fParam->GetNInnerSector();
+ const Int_t kNOS = fParam->GetNOuterSector();
+ const Int_t kNS = kNIS + kNOS;
+ fZWidth = fParam->GetZWidth();
+ Int_t zeroSup = fParam->GetZeroSup();
+ //
+ //alocate memory for sector - maximal case
+ //
+ Float_t** allBins = NULL;
+ Int_t** allSigBins = NULL;
+ Int_t* allNSigBins = NULL;
+ Int_t nRowsMax = roc->GetNRows(roc->GetNSector()-1);
+ Int_t nPadsMax = roc->GetNPads(roc->GetNSector()-1,nRowsMax-1);
+ allBins = new Float_t*[nRowsMax];
+ allSigBins = new Int_t*[nRowsMax];
+ allNSigBins = new Int_t[nRowsMax];
+ for (Int_t iRow = 0; iRow < nRowsMax; iRow++) {
+ //
+ Int_t maxBin = fMaxTime*(nPadsMax+6); // add 3 virtual pads before and 3 after
+ allBins[iRow] = new Float_t[maxBin];
+ memset(allBins[iRow],0,sizeof(Float_t)*maxBin);
+ allSigBins[iRow] = new Int_t[maxBin];
+ allNSigBins[iRow]=0;
+ }
+ //
+ // Loop over sectors
+ //
+ for(fSector = 0; fSector < kNS; fSector++) {
+
+ AliTPCCalROC * gainROC = gainTPC->GetCalROC(fSector); // pad gains per given sector
+ AliTPCCalROC * pedestalROC = pedestalTPC->GetCalROC(fSector); // pedestal per given sector
+ AliTPCCalROC * noiseROC = noiseTPC->GetCalROC(fSector); // noise per given sector
+
+ Int_t nRows = 0;
+ Int_t nDDLs = 0, indexDDL = 0;
+ if (fSector < kNIS) {
+ nRows = fParam->GetNRowLow();
+ fSign = (fSector < kNIS/2) ? 1 : -1;
+ nDDLs = 2;
+ indexDDL = fSector * 2;
+ }
+ else {
+ nRows = fParam->GetNRowUp();
+ fSign = ((fSector-kNIS) < kNOS/2) ? 1 : -1;
+ nDDLs = 4;
+ indexDDL = (fSector-kNIS) * 4 + kNIS * 2;
+ }
+
+ for (Int_t iRow = 0; iRow < nRows; iRow++) {
+ Int_t maxPad;
+ if (fSector < kNIS)
+ maxPad = fParam->GetNPadsLow(iRow);
+ else
+ maxPad = fParam->GetNPadsUp(iRow);
+
+ Int_t maxBin = fMaxTime*(maxPad+6); // add 3 virtual pads before and 3 after
+ memset(allBins[iRow],0,sizeof(Float_t)*maxBin);
+ allNSigBins[iRow] = 0;
}
+
+ // Loas the raw data for corresponding DDLs
+ rawReader->Reset();
+ input.SetOldRCUFormat(fIsOldRCUFormat);
+ rawReader->Select("TPC",indexDDL,indexDDL+nDDLs-1);
+ Int_t digCounter=0;
+ // Begin loop over altro data
+ Bool_t calcPedestal = fRecoParam->GetCalcPedestal();
+ Float_t gain =1;
+ Int_t lastPad=-1;
+ while (input.Next()) {
+ digCounter++;
+ if (input.GetSector() != fSector)
+ AliFatal(Form("Sector index mismatch ! Expected (%d), but got (%d) !",fSector,input.GetSector()));
- memcpy(fResBins,fBins, fMaxBin*2);
+
+ Int_t iRow = input.GetRow();
+ if (iRow < 0 || iRow >= nRows)
+ AliFatal(Form("Pad-row index (%d) outside the range (%d -> %d) !",
+ iRow, 0, nRows -1));
+ //pad
+ Int_t iPad = input.GetPad();
+ if (iPad < 0 || iPad >= nPadsMax)
+ AliFatal(Form("Pad index (%d) outside the range (%d -> %d) !",
+ iPad, 0, nPadsMax-1));
+ if (iPad!=lastPad){
+ gain = gainROC->GetValue(iRow,iPad);
+ lastPad = iPad;
+ }
+ iPad+=3;
+ //time
+ Int_t iTimeBin = input.GetTime();
+ if ( iTimeBin < 0 || iTimeBin >= fParam->GetMaxTBin())
+ AliFatal(Form("Timebin index (%d) outside the range (%d -> %d) !",
+ iTimeBin, 0, iTimeBin -1));
+ iTimeBin+=3;
+ //signal
+ Float_t signal = input.GetSignal();
+ if (!calcPedestal && signal <= zeroSup) continue;
+ if (!calcPedestal) {
+ Int_t bin = iPad*fMaxTime+iTimeBin;
+ allBins[iRow][bin] = signal/gain;
+ allSigBins[iRow][allNSigBins[iRow]++] = bin;
+ }else{
+ allBins[iRow][iPad*fMaxTime+iTimeBin] = signal;
+ }
+ allBins[iRow][iPad*fMaxTime+0]=1.; // pad with signal
+ } // End of the loop over altro data
+ //
//
- fNcluster=0;
- //first loop - for "gold cluster"
- fLoop=1;
- Int_t *b=&fBins[-1]+2*fMaxTime;
- Int_t crtime = Int_t((fParam->GetZLength()-1.05*fRx)/fZWidth-5);
-
- for (Int_t i=2*fMaxTime; i<fMaxBin-2*fMaxTime; i++) {
- b++;
- if (*b<8) continue; //threshold form maxima
- if (i%fMaxTime<crtime) {
- Int_t delta = -(i%fMaxTime)+crtime;
- b+=delta;
- i+=delta;
- continue;
+ // Now loop over rows and perform pedestal subtraction
+ if (digCounter==0) continue;
+ // if (fPedSubtraction) {
+ if (calcPedestal) {
+ for (Int_t iRow = 0; iRow < nRows; iRow++) {
+ Int_t maxPad;
+ if (fSector < kNIS)
+ maxPad = fParam->GetNPadsLow(iRow);
+ else
+ maxPad = fParam->GetNPadsUp(iRow);
+
+ for (Int_t iPad = 3; iPad < maxPad + 3; iPad++) {
+ if (allBins[iRow][iPad*fMaxTime+0] <1 ) continue; // no data
+ Float_t *p = &allBins[iRow][iPad*fMaxTime+3];
+ //Float_t pedestal = TMath::Median(fMaxTime, p);
+ Int_t id[3] = {fSector, iRow, iPad-3};
+ // calib values
+ Double_t rmsCalib= noiseROC->GetValue(iRow,iPad-3);
+ Double_t pedestalCalib = pedestalROC->GetValue(iRow,iPad-3);
+ Double_t rmsEvent = rmsCalib;
+ Double_t pedestalEvent = pedestalCalib;
+ ProcesSignal(p, fMaxTime, id, rmsEvent, pedestalEvent);
+ if (rmsEvent<rmsCalib) rmsEvent = rmsCalib; // take worst scenario
+ if (TMath::Abs(pedestalEvent-pedestalCalib)<1.0) pedestalEvent = pedestalCalib;
+
+ //
+ for (Int_t iTimeBin = 0; iTimeBin < fMaxTime; iTimeBin++) {
+ Int_t bin = iPad*fMaxTime+iTimeBin;
+ allBins[iRow][bin] -= pedestalEvent;
+ if (iTimeBin < AliTPCReconstructor::GetRecoParam()->GetFirstBin())
+ allBins[iRow][bin] = 0;
+ if (iTimeBin > AliTPCReconstructor::GetRecoParam()->GetLastBin())
+ allBins[iRow][bin] = 0;
+ if (allBins[iRow][iPad*fMaxTime+iTimeBin] < zeroSup)
+ allBins[iRow][bin] = 0;
+ if (allBins[iRow][bin] < 3.0*rmsEvent) // 3 sigma cut on RMS
+ allBins[iRow][bin] = 0;
+ if (allBins[iRow][bin]) allSigBins[iRow][allNSigBins[iRow]++] = bin;
+ }
+ }
}
-
- if (!IsMaximum(*b,fMaxTime,b)) continue;
- AliTPCclusterMI c;
- Int_t dummy=0;
- MakeCluster(i, fMaxTime, fBins, dummy,c);
- //}
- }
- //memcpy(fBins,fResBins, fMaxBin*2);
- //second loop - for rest cluster
- /*
- fLoop=2;
- b=&fResBins[-1]+2*fMaxTime;
- for (Int_t i=2*fMaxTime; i<fMaxBin-2*fMaxTime; i++) {
- b++;
- if (*b<25) continue; // bigger threshold for maxima
- if (!IsMaximum(*b,fMaxTime,b)) continue;
- AliTPCclusterMI c;
- Int_t dummy;
- MakeCluster(i, fMaxTime, fResBins, dummy,c);
- //}
}
- */
+ // Now loop over rows and find clusters
+ for (fRow = 0; fRow < nRows; fRow++) {
+ fRowCl = new AliTPCClustersRow;
+ fRowCl->SetClass("AliTPCclusterMI");
+ fRowCl->SetArray(1);
+ fRowCl->SetID(fParam->GetIndex(fSector, fRow));
+ fOutput->GetBranch("Segment")->SetAddress(&fRowCl);
- fOutput->Fill();
- delete clrow;
- nclusters+=fNcluster;
- delete[] fBins;
- delete[] fResBins;
+ fRx = fParam->GetPadRowRadii(fSector, fRow);
+ fPadLength = fParam->GetPadPitchLength(fSector, fRow);
+ fPadWidth = fParam->GetPadPitchWidth();
+ if (fSector < kNIS)
+ fMaxPad = fParam->GetNPadsLow(fRow);
+ else
+ fMaxPad = fParam->GetNPadsUp(fRow);
+ fMaxBin = fMaxTime*(fMaxPad+6); // add 3 virtual pads before and 3 after
+
+ fBins = allBins[fRow];
+ fSigBins = allSigBins[fRow];
+ fNSigBins = allNSigBins[fRow];
+
+ FindClusters(noiseROC);
+
+ fOutput->Fill();
+ delete fRowCl;
+ nclusters += fNcluster;
+ } // End of loop to find clusters
+ } // End of loop over sectors
+
+ for (Int_t iRow = 0; iRow < nRowsMax; iRow++) {
+ delete [] allBins[iRow];
+ delete [] allSigBins[iRow];
+ }
+ delete [] allBins;
+ delete [] allSigBins;
+ delete [] allNSigBins;
+
+ Info("Digits2Clusters", "File %s Event\t%d\tNumber of found clusters : %d\n", fOutput->GetName(),*(rawReader->GetEventId()), nclusters);
+
+}
+
+void AliTPCclustererMI::FindClusters(AliTPCCalROC * noiseROC)
+{
+
+ //
+ // add virtual charge at the edge
+ //
+ Double_t kMaxDumpSize = 500000;
+ if (fRecoParam->GetCalcPedestal() && fOutput->GetZipBytes()< kMaxDumpSize) fBDumpSignal =kTRUE; //dump signal flag
+ //
+ fNcluster=0;
+ fLoop=1;
+ Int_t crtime = Int_t((fParam->GetZLength(fSector)-fRecoParam->GetCtgRange()*fRx)/fZWidth-fParam->GetNTBinsL1()-5);
+ Float_t minMaxCutAbs = fRecoParam->GetMinMaxCutAbs();
+ Float_t minLeftRightCutAbs = fRecoParam->GetMinLeftRightCutAbs();
+ Float_t minUpDownCutAbs = fRecoParam->GetMinUpDownCutAbs();
+ Float_t minMaxCutSigma = fRecoParam->GetMinMaxCutSigma();
+ Float_t minLeftRightCutSigma = fRecoParam->GetMinLeftRightCutSigma();
+ Float_t minUpDownCutSigma = fRecoParam->GetMinUpDownCutSigma();
+ for (Int_t iSig = 0; iSig < fNSigBins; iSig++) {
+ Int_t i = fSigBins[iSig];
+ if (i%fMaxTime<=crtime) continue;
+ Float_t *b = &fBins[i];
+ //absolute custs
+ if (b[0]<minMaxCutAbs) continue; //threshold for maxima
+ //
+ if (b[-1]+b[1]+b[-fMaxTime]+b[fMaxTime]<=0) continue; // cut on isolated clusters
+ // if (b[-1]+b[1]<=0) continue; // cut on isolated clusters
+ //if (b[-fMaxTime]+b[fMaxTime]<=0) continue; // cut on isolated clusters
+ //
+ if ((b[0]+b[-1]+b[1])<minUpDownCutAbs) continue; //threshold for up down (TRF)
+ if ((b[0]+b[-fMaxTime]+b[fMaxTime])<minLeftRightCutAbs) continue; //threshold for left right (PRF)
+ if (!IsMaximum(*b,fMaxTime,b)) continue;
+ //
+ Float_t noise = noiseROC->GetValue(fRow, i/fMaxTime);
+ // sigma cuts
+ if (b[0]<minMaxCutSigma*noise) continue; //threshold form maxima
+ if ((b[0]+b[-1]+b[1])<minUpDownCutSigma*noise) continue; //threshold for up town TRF
+ if ((b[0]+b[-fMaxTime]+b[fMaxTime])<minLeftRightCutSigma*noise) continue; //threshold for left right (PRF)
+
+ AliTPCclusterMI c(kFALSE); // default cosntruction without info
+ Int_t dummy=0;
+ MakeCluster(i, fMaxTime, fBins, dummy,c);
+
+ //}
+ }
+}
+
+
+Double_t AliTPCclustererMI::ProcesSignal(Float_t *signal, Int_t nchannels, Int_t id[3], Double_t &rmsEvent, Double_t &pedestalEvent){
+ //
+ // process signal on given pad - + streaming of additional information in special mode
+ //
+ // id[0] - sector
+ // id[1] - row
+ // id[2] - pad
+
+ //
+ // ESTIMATE pedestal and the noise
+ //
+ const Int_t kPedMax = 100;
+ Double_t kMaxDebugSize = 5000000.;
+ Float_t max = 0;
+ Float_t maxPos = 0;
+ Int_t median = -1;
+ Int_t count0 = 0;
+ Int_t count1 = 0;
+ Float_t rmsCalib = rmsEvent; // backup initial value ( from calib)
+ Float_t pedestalCalib = pedestalEvent;// backup initial value ( from calib)
+ Int_t firstBin = AliTPCReconstructor::GetRecoParam()->GetFirstBin();
+ //
+ UShort_t histo[kPedMax];
+ memset(histo,0,kPedMax*sizeof(UShort_t));
+ for (Int_t i=0; i<fMaxTime; i++){
+ if (signal[i]<=0) continue;
+ if (signal[i]>max && i>firstBin) {
+ max = signal[i];
+ maxPos = i;
+ }
+ if (signal[i]>kPedMax-1) continue;
+ histo[int(signal[i]+0.5)]++;
+ count0++;
+ }
+ //
+ for (Int_t i=1; i<kPedMax; i++){
+ if (count1<count0*0.5) median=i;
+ count1+=histo[i];
+ }
+ // truncated mean
+ //
+ Float_t count10=histo[median] ,mean=histo[median]*median, rms=histo[median]*median*median ;
+ Float_t count06=histo[median] ,mean06=histo[median]*median, rms06=histo[median]*median*median ;
+ Float_t count09=histo[median] ,mean09=histo[median]*median, rms09=histo[median]*median*median ;
+ //
+ for (Int_t idelta=1; idelta<10; idelta++){
+ if (median-idelta<=0) continue;
+ if (median+idelta>kPedMax) continue;
+ if (count06<0.6*count1){
+ count06+=histo[median-idelta];
+ mean06 +=histo[median-idelta]*(median-idelta);
+ rms06 +=histo[median-idelta]*(median-idelta)*(median-idelta);
+ count06+=histo[median+idelta];
+ mean06 +=histo[median+idelta]*(median+idelta);
+ rms06 +=histo[median+idelta]*(median+idelta)*(median+idelta);
+ }
+ if (count09<0.9*count1){
+ count09+=histo[median-idelta];
+ mean09 +=histo[median-idelta]*(median-idelta);
+ rms09 +=histo[median-idelta]*(median-idelta)*(median-idelta);
+ count09+=histo[median+idelta];
+ mean09 +=histo[median+idelta]*(median+idelta);
+ rms09 +=histo[median+idelta]*(median+idelta)*(median+idelta);
+ }
+ if (count10<0.95*count1){
+ count10+=histo[median-idelta];
+ mean +=histo[median-idelta]*(median-idelta);
+ rms +=histo[median-idelta]*(median-idelta)*(median-idelta);
+ count10+=histo[median+idelta];
+ mean +=histo[median+idelta]*(median+idelta);
+ rms +=histo[median+idelta]*(median+idelta)*(median+idelta);
+ }
+ }
+ mean /=count10;
+ mean06/=count06;
+ mean09/=count09;
+ rms = TMath::Sqrt(TMath::Abs(rms/count10-mean*mean));
+ rms06 = TMath::Sqrt(TMath::Abs(rms06/count06-mean06*mean06));
+ rms09 = TMath::Sqrt(TMath::Abs(rms09/count09-mean09*mean09));
+ rmsEvent = rms09;
+ //
+ pedestalEvent = median;
+ if (AliLog::GetDebugLevel("","AliTPCclustererMI")==0) return median;
+ //
+ UInt_t uid[3] = {UInt_t(id[0]),UInt_t(id[1]),UInt_t(id[2])};
+ //
+ // Dump mean signal info
+ //
+ (*fDebugStreamer)<<"Signal"<<
+ "TimeStamp="<<fTimeStamp<<
+ "EventType="<<fEventType<<
+ "Sector="<<uid[0]<<
+ "Row="<<uid[1]<<
+ "Pad="<<uid[2]<<
+ "Max="<<max<<
+ "MaxPos="<<maxPos<<
+ //
+ "Median="<<median<<
+ "Mean="<<mean<<
+ "RMS="<<rms<<
+ "Mean06="<<mean06<<
+ "RMS06="<<rms06<<
+ "Mean09="<<mean09<<
+ "RMS09="<<rms09<<
+ "RMSCalib="<<rmsCalib<<
+ "PedCalib="<<pedestalCalib<<
+ "\n";
+ //
+ // fill pedestal histogram
+ //
+ AliTPCROC * roc = AliTPCROC::Instance();
+ if (!fAmplitudeHisto){
+ fAmplitudeHisto = new TObjArray(72);
}
- cerr<<"Number of found clusters : "<<nclusters<<" \n";
+ //
+ if (uid[0]<roc->GetNSectors()
+ && uid[1]< roc->GetNRows(uid[0]) &&
+ uid[2] <roc->GetNPads(uid[0], uid[1])){
+ TObjArray * sectorArray = (TObjArray*)fAmplitudeHisto->UncheckedAt(uid[0]);
+ if (!sectorArray){
+ Int_t npads =roc->GetNChannels(uid[0]);
+ sectorArray = new TObjArray(npads);
+ fAmplitudeHisto->AddAt(sectorArray, uid[0]);
+ }
+ Int_t position = uid[2]+roc->GetRowIndexes(uid[0])[uid[1]];
+ TH1F * histo = (TH1F*)sectorArray->UncheckedAt(position);
+ if (!histo){
+ char hname[100];
+ sprintf(hname,"Amp_%d_%d_%d",uid[0],uid[1],uid[2]);
+ TFile * backup = gFile;
+ fDebugStreamer->GetFile()->cd();
+ histo = new TH1F(hname, hname, 100, 5,100);
+ //histo->SetDirectory(0); // histogram not connected to directory -(File)
+ sectorArray->AddAt(histo, position);
+ if (backup) backup->cd();
+ }
+ for (Int_t i=0; i<nchannels; i++){
+ histo->Fill(signal[i]);
+ }
+ }
+ //
+ //
+ //
+ Float_t kMin =fRecoParam->GetDumpAmplitudeMin(); // minimal signal to be dumped
+ Float_t *dsignal = new Float_t[nchannels];
+ Float_t *dtime = new Float_t[nchannels];
+ for (Int_t i=0; i<nchannels; i++){
+ dtime[i] = i;
+ dsignal[i] = signal[i];
+ }
+ //
+ // Digital noise
+ //
+ // if (max-median>30.*TMath::Max(1.,Double_t(rms06)) && (((*fDebugStreamer)<<"SignalDN").GetSize()<kMaxDebugSize)){
+// //
+// //
+// TGraph * graph =new TGraph(nchannels, dtime, dsignal);
+// //
+// //
+// // jumps left - right
+// Int_t njumps0=0;
+// Double_t deltaT0[2000];
+// Double_t deltaA0[2000];
+// Int_t lastJump0 = fRecoParam->GetFirstBin();
+// Int_t njumps1=0;
+// Double_t deltaT1[2000];
+// Double_t deltaA1[2000];
+// Int_t lastJump1 = fRecoParam->GetFirstBin();
+// Int_t njumps2=0;
+// Double_t deltaT2[2000];
+// Double_t deltaA2[2000];
+// Int_t lastJump2 = fRecoParam->GetFirstBin();
+
+// for (Int_t itime=fRecoParam->GetFirstBin()+1; itime<fRecoParam->GetLastBin()-1; itime++){
+// if (TMath::Abs(dsignal[itime]-dsignal[itime-1])>30.*TMath::Max(1.,Double_t(rms06)) &&
+// TMath::Abs(dsignal[itime]-dsignal[itime+1])>30.*TMath::Max(1.,Double_t(rms06)) &&
+// (dsignal[itime-1]-median<5.*rms06) &&
+// (dsignal[itime+1]-median<5.*rms06)
+// ){
+// deltaA0[njumps0] = dsignal[itime]-dsignal[itime-1];
+// deltaT0[njumps0] = itime-lastJump0;
+// lastJump0 = itime;
+// njumps0++;
+// }
+// if (TMath::Abs(dsignal[itime]-dsignal[itime-1])>30.*TMath::Max(1.,Double_t(rms06)) &&
+// (dsignal[itime-1]-median<5.*rms06)
+// ) {
+// deltaA1[njumps1] = dsignal[itime]-dsignal[itime-1];
+// deltaT1[njumps1] = itime-lastJump1;
+// lastJump1 = itime;
+// njumps1++;
+// }
+// if (TMath::Abs(dsignal[itime]-dsignal[itime+1])>30.*TMath::Max(1.,Double_t(rms06)) &&
+// (dsignal[itime+1]-median<5.*rms06)
+// ) {
+// deltaA2[njumps2] = dsignal[itime]-dsignal[itime+1];
+// deltaT2[njumps2] = itime-lastJump2;
+// lastJump2 = itime;
+// njumps2++;
+// }
+// }
+// //
+// if (njumps0>0 || njumps1>0 || njumps2>0){
+// TGraph *graphDN0 = new TGraph(njumps0, deltaT0, deltaA0);
+// TGraph *graphDN1 = new TGraph(njumps1, deltaT1, deltaA1);
+// TGraph *graphDN2 = new TGraph(njumps2, deltaT2, deltaA2);
+// (*fDebugStreamer)<<"SignalDN"<< //digital - noise pads - or random sample of pads
+// "TimeStamp="<<fTimeStamp<<
+// "EventType="<<fEventType<<
+// "Sector="<<uid[0]<<
+// "Row="<<uid[1]<<
+// "Pad="<<uid[2]<<
+// "Graph="<<graph<<
+// "Max="<<max<<
+// "MaxPos="<<maxPos<<
+// "Graph.="<<graph<<
+// "P0GraphDN0.="<<graphDN0<<
+// "P1GraphDN1.="<<graphDN1<<
+// "P2GraphDN2.="<<graphDN2<<
+// //
+// "Median="<<median<<
+// "Mean="<<mean<<
+// "RMS="<<rms<<
+// "Mean06="<<mean06<<
+// "RMS06="<<rms06<<
+// "Mean09="<<mean09<<
+// "RMS09="<<rms09<<
+// "\n";
+// delete graphDN0;
+// delete graphDN1;
+// delete graphDN2;
+// }
+// delete graph;
+// }
+
+ //
+ // NOISE STUDY Fourier transform
+ //
+ TGraph * graph;
+ Bool_t random = (gRandom->Rndm()<0.0003);
+ if (((*fDebugStreamer)<<"SignalN").GetSize()<kMaxDebugSize)
+ if (max-median>kMin || rms06>1.*fParam->GetZeroSup() || random){
+ graph =new TGraph(nchannels, dtime, dsignal);
+ if (rms06>1.*fParam->GetZeroSup() || random){
+ //Double_t *input, Double_t threshold, Bool_t locMax, Double_t *freq, Double_t *re, Double_t *im, Double_t *mag, Double_t *phi);
+ Float_t * input = &(dsignal[fRecoParam->GetFirstBin()]);
+ Float_t freq[2000], re[2000], im[2000], mag[2000], phi[2000];
+ Int_t npoints = TransformFFT(input, -1,kFALSE, freq, re, im, mag, phi);
+ TGraph *graphMag0 = new TGraph(npoints, freq, mag);
+ TGraph *graphPhi0 = new TGraph(npoints, freq, phi);
+ npoints = TransformFFT(input, 0.5,kTRUE, freq, re, im, mag, phi);
+ TGraph *graphMag1 = new TGraph(npoints, freq, mag);
+ TGraph *graphPhi1 = new TGraph(npoints, freq, phi);
+
+ (*fDebugStreamer)<<"SignalN"<< //noise pads - or random sample of pads
+ "TimeStamp="<<fTimeStamp<<
+ "EventType="<<fEventType<<
+ "Sector="<<uid[0]<<
+ "Row="<<uid[1]<<
+ "Pad="<<uid[2]<<
+ "Graph.="<<graph<<
+ "Max="<<max<<
+ "MaxPos="<<maxPos<<
+ //
+ "Median="<<median<<
+ "Mean="<<mean<<
+ "RMS="<<rms<<
+ "Mean06="<<mean06<<
+ "RMS06="<<rms06<<
+ "Mean09="<<mean09<<
+ "RMS09="<<rms09<<
+ // FFT part
+ "Mag0.="<<graphMag0<<
+ "Mag1.="<<graphMag1<<
+ "Phi0.="<<graphPhi0<<
+ "Phi1.="<<graphPhi1<<
+ "\n";
+ delete graphMag0;
+ delete graphMag1;
+ delete graphPhi0;
+ delete graphPhi1;
+ }
+ //
+ // Big signals dumping
+ //
+
+ if (max-median>kMin &&maxPos>AliTPCReconstructor::GetRecoParam()->GetFirstBin())
+ (*fDebugStreamer)<<"SignalB"<< // pads with signal
+ "TimeStamp="<<fTimeStamp<<
+ "EventType="<<fEventType<<
+ "Sector="<<uid[0]<<
+ "Row="<<uid[1]<<
+ "Pad="<<uid[2]<<
+ "Graph="<<graph<<
+ "Max="<<max<<
+ "MaxPos="<<maxPos<<
+ //
+ "Median="<<median<<
+ "Mean="<<mean<<
+ "RMS="<<rms<<
+ "Mean06="<<mean06<<
+ "RMS06="<<rms06<<
+ "Mean09="<<mean09<<
+ "RMS09="<<rms09<<
+ "\n";
+ delete graph;
+ }
- fOutput->Write();
- savedir->cd();
+ //
+ //
+ // Central Electrode signal analysis
+ //
+ Float_t ceQmax =0, ceQsum=0, ceTime=0;
+ Float_t cemean = mean06, cerms=rms06 ;
+ Int_t cemaxpos= 0;
+ Float_t ceThreshold=5.*cerms;
+ Float_t ceSumThreshold=8.*cerms;
+ const Int_t kCemin=5; // range for the analysis of the ce signal +- channels from the peak
+ const Int_t kCemax=5;
+ for (Int_t i=nchannels-2; i>nchannels/2; i--){
+ if ( (dsignal[i]-mean06)>ceThreshold && dsignal[i]>=dsignal[i+1] && dsignal[i]>=dsignal[i-1] ){
+ cemaxpos=i;
+ break;
+ }
+ }
+ if (cemaxpos!=0){
+ ceQmax = 0;
+ Int_t cemaxpos2=0;
+ for (Int_t i=cemaxpos-20; i<cemaxpos+5; i++){
+ if (i<0 || i>nchannels-1) continue;
+ Double_t val=dsignal[i]- cemean;
+ if (val>ceQmax){
+ cemaxpos2=i;
+ ceQmax = val;
+ }
+ }
+ cemaxpos = cemaxpos2;
+
+ for (Int_t i=cemaxpos-kCemin; i<cemaxpos+kCemax; i++){
+ if (i>0 && i<nchannels&&dsignal[i]- cemean>0){
+ Double_t val=dsignal[i]- cemean;
+ ceTime+=val*dtime[i];
+ ceQsum+=val;
+ if (val>ceQmax) ceQmax=val;
+ }
+ }
+ if (ceQmax&&ceQsum>ceSumThreshold) {
+ ceTime/=ceQsum;
+ (*fDebugStreamer)<<"Signalce"<<
+ "TimeStamp="<<fTimeStamp<<
+ "EventType="<<fEventType<<
+ "Sector="<<uid[0]<<
+ "Row="<<uid[1]<<
+ "Pad="<<uid[2]<<
+ "Max="<<ceQmax<<
+ "Qsum="<<ceQsum<<
+ "Time="<<ceTime<<
+ "RMS06="<<rms06<<
+ //
+ "\n";
+ }
+ }
+ // end of ce signal analysis
+ //
+
+ //
+ // Gating grid signal analysis
+ //
+ Double_t ggQmax =0, ggQsum=0, ggTime=0;
+ Double_t ggmean = mean06, ggrms=rms06 ;
+ Int_t ggmaxpos= 0;
+ Double_t ggThreshold=5.*ggrms;
+ Double_t ggSumThreshold=8.*ggrms;
+
+ for (Int_t i=1; i<nchannels/4; i++){
+ if ( (dsignal[i]-mean06)>ggThreshold && dsignal[i]>=dsignal[i+1] && dsignal[i]>=dsignal[i-1] &&
+ (dsignal[i]+dsignal[i+1]+dsignal[i-1]-3*mean06)>ggSumThreshold){
+ ggmaxpos=i;
+ if (dsignal[i-1]>dsignal[i+1]) ggmaxpos=i-1;
+ break;
+ }
+ }
+ if (ggmaxpos!=0){
+ for (Int_t i=ggmaxpos-1; i<ggmaxpos+3; i++){
+ if (i>0 && i<nchannels && dsignal[i]-ggmean>0){
+ Double_t val=dsignal[i]- ggmean;
+ ggTime+=val*dtime[i];
+ ggQsum+=val;
+ if (val>ggQmax) ggQmax=val;
+ }
+ }
+ if (ggQmax&&ggQsum>ggSumThreshold) {
+ ggTime/=ggQsum;
+ (*fDebugStreamer)<<"Signalgg"<<
+ "TimeStamp="<<fTimeStamp<<
+ "EventType="<<fEventType<<
+ "Sector="<<uid[0]<<
+ "Row="<<uid[1]<<
+ "Pad="<<uid[2]<<
+ "Max="<<ggQmax<<
+ "Qsum="<<ggQsum<<
+ "Time="<<ggTime<<
+ "RMS06="<<rms06<<
+ //
+ "\n";
+ }
+ }
+ // end of gg signal analysis
+
+
+ delete [] dsignal;
+ delete [] dtime;
+ if (rms06>fRecoParam->GetMaxNoise()) {
+ pedestalEvent+=1024.;
+ return 1024+median; // sign noisy channel in debug mode
+ }
+ return median;
+}
+
+
+
+void AliTPCclustererMI::DumpHistos(){
+ //
+ // Dump histogram information
+ //
+ if (!fAmplitudeHisto) return;
+ AliTPCROC * roc = AliTPCROC::Instance();
+ for (UInt_t isector=0; isector<AliTPCROC::Instance()->GetNSectors(); isector++){
+ TObjArray * array = (TObjArray*)fAmplitudeHisto->UncheckedAt(isector);
+ if (!array) continue;
+ for (UInt_t ipad = 0; ipad <(UInt_t)array->GetEntriesFast(); ipad++){
+ TH1F * histo = (TH1F*) array->UncheckedAt(ipad);
+ if (!histo) continue;
+ if (histo->GetEntries()<100) continue;
+ histo->Fit("gaus","q");
+ Float_t mean = histo->GetMean();
+ Float_t rms = histo->GetRMS();
+ Float_t gmean = histo->GetFunction("gaus")->GetParameter(1);
+ Float_t gsigma = histo->GetFunction("gaus")->GetParameter(2);
+ Float_t gmeanErr = histo->GetFunction("gaus")->GetParError(1);
+ Float_t gsigmaErr = histo->GetFunction("gaus")->GetParError(2);
+ Float_t max = histo->GetFunction("gaus")->GetParameter(0);
+
+ // get pad number
+ UInt_t row=0, pad =0;
+ const UInt_t *indexes =roc->GetRowIndexes(isector);
+ for (UInt_t irow=0; irow<roc->GetNRows(isector); irow++){
+ if (indexes[irow]<=ipad){
+ row = irow;
+ pad = ipad-indexes[irow];
+ }
+ }
+ Int_t rpad = pad - (AliTPCROC::Instance()->GetNPads(isector,row))/2;
+ //
+ (*fDebugStreamer)<<"Fit"<<
+ "TimeStamp="<<fTimeStamp<<
+ "EventType="<<fEventType<<
+ "Sector="<<isector<<
+ "Row="<<row<<
+ "Pad="<<pad<<
+ "RPad="<<rpad<<
+ "Max="<<max<<
+ "Mean="<<mean<<
+ "RMS="<<rms<<
+ "GMean="<<gmean<<
+ "GSigma="<<gsigma<<
+ "GMeanErr="<<gmeanErr<<
+ "GSigmaErr="<<gsigmaErr<<
+ "\n";
+ if (array->UncheckedAt(ipad)) fDebugStreamer->StoreObject(array->UncheckedAt(ipad));
+ }
+ }
}
+
+
+
+Int_t AliTPCclustererMI::TransformFFT(Float_t *input, Float_t threshold, Bool_t locMax, Float_t *freq, Float_t *re, Float_t *im, Float_t *mag, Float_t *phi)
+{
+ //
+ // calculate fourrie transform
+ // return only frequncies with mag over threshold
+ // if locMax is spectified only freque with local maxima over theshold is returned
+
+ if (! fFFTr2c) return kFALSE;
+ if (!freq) return kFALSE;
+
+ Int_t current=0;
+ Int_t nPoints = fRecoParam->GetLastBin()-fRecoParam->GetFirstBin();
+ Double_t *in = new Double_t[nPoints];
+ Double_t *rfft = new Double_t[nPoints];
+ Double_t *ifft = new Double_t[nPoints];
+ for (Int_t i=0; i<nPoints; i++){in[i]=input[i];}
+ fFFTr2c->SetPoints(in);
+ fFFTr2c->Transform();
+ fFFTr2c->GetPointsComplex(rfft, ifft);
+ for (Int_t i=3; i<nPoints/2-3; i++){
+ Float_t lmag = TMath::Sqrt(rfft[i]*rfft[i]+ifft[i]*ifft[i])/nPoints;
+ if (lmag<threshold) continue;
+ if (locMax){
+ if ( TMath::Sqrt(rfft[i-1]*rfft[i-1]+ifft[i-1]*ifft[i-1])/nPoints>lmag) continue;
+ if ( TMath::Sqrt(rfft[i+1]*rfft[i+1]+ifft[i+1]*ifft[i+1])/nPoints>lmag) continue;
+ if ( TMath::Sqrt(rfft[i-2]*rfft[i-2]+ifft[i-2]*ifft[i-2])/nPoints>lmag) continue;
+ if ( TMath::Sqrt(rfft[i+2]*rfft[i+2]+ifft[i+2]*ifft[i+2])/nPoints>lmag) continue;
+ if ( TMath::Sqrt(rfft[i-3]*rfft[i-3]+ifft[i-3]*ifft[i-3])/nPoints>lmag) continue;
+ if ( TMath::Sqrt(rfft[i+3]*rfft[i+3]+ifft[i+3]*ifft[i+3])/nPoints>lmag) continue;
+ }
+
+ freq[current] = Float_t(i)/Float_t(nPoints);
+ //
+ re[current] = rfft[i];
+ im[current] = ifft[i];
+ mag[current]=lmag;
+ phi[current]=TMath::ATan2(ifft[i],rfft[i]);
+ current++;
+ }
+ delete [] in;
+ delete [] rfft;
+ delete [] ifft;
+ return current;
+}
+