/* $Id$ */
-// Clusterizer class developped by Zitchenko (Dubna)
+// Clusterizer class developed by A. Zinchenko (Dubna), based on the
+// Expectation-Maximization algorithm
#include <stdlib.h>
#include <Riostream.h>
-#include <TROOT.h>
-#include <TCanvas.h>
-#include <TLine.h>
-#include <TTree.h>
#include <TH2.h>
-#include <TView.h>
-#include <TStyle.h>
#include <TMinuit.h>
#include <TMatrixD.h>
#include "AliMUONClusterFinderAZ.h"
-#include "AliHeader.h"
+#include "AliMUONClusterDrawAZ.h"
+#include "AliMUONVGeometryDESegmentation.h"
+#include "AliMUONGeometryModuleTransformer.h"
#include "AliRun.h"
#include "AliMUON.h"
-#include "AliMUONChamber.h"
#include "AliMUONDigit.h"
-#include "AliMUONHit.h"
-#include "AliMUONChamber.h"
#include "AliMUONRawCluster.h"
#include "AliMUONClusterInput.h"
#include "AliMUONPixel.h"
-#include "AliMC.h"
+#include "AliMUONMathieson.h"
#include "AliLog.h"
ClassImp(AliMUONClusterFinderAZ)
const Double_t AliMUONClusterFinderAZ::fgkCouplMin = 1.e-3; // threshold on coupling
+ const Double_t AliMUONClusterFinderAZ::fgkZeroSuppression = 6; // average zero suppression value
+ const Double_t AliMUONClusterFinderAZ::fgkSaturation = 3000; // average saturation level
AliMUONClusterFinderAZ* AliMUONClusterFinderAZ::fgClusterFinder = 0x0;
TMinuit* AliMUONClusterFinderAZ::fgMinuit = 0x0;
+//FILE *lun1 = fopen("nxny.dat","w");
//_____________________________________________________________________________
-AliMUONClusterFinderAZ::AliMUONClusterFinderAZ(Bool_t draw, Int_t iReco)
+AliMUONClusterFinderAZ::AliMUONClusterFinderAZ(Bool_t draw)
: AliMUONClusterFinderVS()
{
// Constructor
- for (Int_t i=0; i<4; i++) {fHist[i] = 0;}
- fMuonDigits = 0;
- fSegmentation[1] = fSegmentation[0] = 0;
- fgClusterFinder = 0x0;
- fgMinuit = 0x0;
- if (!fgClusterFinder) fgClusterFinder = this;
+ fnPads[0]=fnPads[1]=0;
+
+ for (Int_t i=0; i<7; i++)
+ for (Int_t j=0; j<fgkDim; j++)
+ fXyq[i][j]= 9999.;
+
+ for (Int_t i=0; i<4; i++)
+ for (Int_t j=0; j<fgkDim; j++)
+ fPadIJ[i][j]=-1;
+
+ for (Int_t i=0; i<2; i++)
+ for (Int_t j=0; j<fgkDim; j++)
+ fUsed[i][j] = 0;
+
+ fSegmentation[1] = fSegmentation[0] = 0x0;
+
+ fZpad = 0;
+ fQtot = 0;
+ fPadBeg[0] = fPadBeg[1] = fCathBeg = fNpar = fnCoupled = 0;
+
if (!fgMinuit) fgMinuit = new TMinuit(8);
- fDraw = draw;
- fReco = iReco;
+ if (!fgClusterFinder) fgClusterFinder = this;
fPixArray = new TObjArray(20);
- /*
- fPoints = 0;
- fPhits = 0;
- fRpoints = 0;
- fCanvas = 0;
- fNextCathode = kFALSE;
- fColPad = 0;
- */
+
+ fDebug = 0; //0;
+ fReco = 1;
+ fDraw = 0x0;
+ if (draw) {
+ fDebug = 1;
+ fReco = 0;
+ fDraw = new AliMUONClusterDrawAZ(this);
+ }
+ cout << " *** Running AZ cluster finder *** " << endl;
}
//_____________________________________________________________________________
{
// Destructor
delete fgMinuit; fgMinuit = 0; delete fPixArray; fPixArray = 0;
- /*
- // Delete space point structure
- if (fPoints) fPoints->Delete();
- delete fPoints;
- fPoints = 0;
- //
- if (fPhits) fPhits->Delete();
- delete fPhits;
- fPhits = 0;
- //
- if (fRpoints) fRpoints->Delete();
- delete fRpoints;
- fRpoints = 0;
- */
+ delete fDraw;
}
//_____________________________________________________________________________
{
// To provide the same interface as in AliMUONClusterFinderVS
- EventLoop (gAlice->GetHeader()->GetEvent(), AliMUONClusterInput::Instance()->Chamber());
+ ResetRawClusters();
+ EventLoop (gAlice->GetEvNumber(), fInput->Chamber());
}
//_____________________________________________________________________________
-void AliMUONClusterFinderAZ::EventLoop(Int_t nev=0, Int_t ch=0)
+void AliMUONClusterFinderAZ::EventLoop(Int_t nev, Int_t ch)
{
-// Loop over events
-
- FILE *lun = 0;
- TCanvas *c1 = 0;
- TView *view = 0;
- TH2F *hist = 0;
- Double_t p1[3]={0}, p2[3];
- TTree *treeR = 0;
- if (fDraw) {
- // File
- lun = fopen("pool.dat","w");
- c1 = new TCanvas("c1","Clusters",0,0,600,700);
- c1->Divide(1,2);
- new TCanvas("c2","Mlem",700,0,600,350);
- }
-
-newev:
- Int_t nparticles = 0, nent;
-
- //Loaders
- AliRunLoader * rl = AliRunLoader::GetRunLoader();
- AliLoader * gime = rl->GetLoader("MUONLoader");
-
- if (!fReco) nparticles = rl->GetEvent(nev);
- else nparticles = gAlice->GetMCApp()->GetNtrack();
- cout << "nev " << nev <<endl;
- cout << "nparticles " << nparticles <<endl;
- if (nparticles <= 0) return;
+// Loop over digits
- TTree *treeH = gime->TreeH();
- Int_t ntracks = (Int_t) treeH->GetEntries();
- cout<<"ntracks "<<ntracks<<endl;
-
- // Get pointers to Alice detectors and Digits containers
- AliMUON *muon = (AliMUON*) gAlice->GetModule("MUON");
- if (!muon) return;
- // TClonesArray *Particles = gAlice->Particles();
- if (!fReco) {
- treeR = gime->TreeR();
- if (treeR) {
- muon->ResetRawClusters();
- nent = (Int_t) treeR->GetEntries();
- if (nent != 1) {
- AliError(Form("nent = %d not equal to 1",nent));
- //exit(0);
- }
- } // if (treeR)
- } // if (!fReco)
+ if (fDraw && !fDraw->FindEvCh(nev, ch)) return;
- TTree *treeD = gime->TreeD();
- //muon->ResetDigits();
-
- TClonesArray *listMUONrawclust ;
- AliMUONChamber* iChamber = 0;
-
- // As default draw the first cluster of the chamber #0
-
-newchamber:
- if (ch > 9) {if (fReco) return; nev++; ch = 0; goto newev;}
- //gAlice->ResetDigits();
- fMuonDigits = muon->GetMUONData()->Digits(ch);
- if (fMuonDigits == 0) return;
- iChamber = &(muon->Chamber(ch));
- fSegmentation[0] = iChamber->SegmentationModel(1);
- fSegmentation[1] = iChamber->SegmentationModel(2);
- fResponse = iChamber->ResponseModel();
+ fSegmentation[0] = (AliMUONVGeometryDESegmentation*) fInput->
+ Segmentation2(0)->GetDESegmentation(fInput->DetElemId());
+ fSegmentation[1] = (AliMUONVGeometryDESegmentation*) fInput->
+ Segmentation2(1)->GetDESegmentation(fInput->DetElemId());
- nent = 0;
-
- if (treeD) {
- nent = (Int_t) treeD->GetEntries();
- //printf(" entries %d \n", nent);
- }
-
- Int_t ndigits[2]={9,9}, nShown[2]={0};
- for (Int_t i=0; i<2; i++) {
- for (Int_t j=0; j<fgkDim; j++) {fUsed[i][j]=kFALSE;}
+ Int_t ndigits[2] = {9,9}, nShown[2] = {0};
+ if (fReco != 2) { // skip initialization for the combined cluster / track
+ fCathBeg = fPadBeg[0] = fPadBeg[1] = 0;
+ for (Int_t i = 0; i < 2; i++) {
+ for (Int_t j = 0; j < fgkDim; j++) { fUsed[i][j] = kFALSE; }
+ }
}
next:
- if (ndigits[0] == nShown[0] && ndigits[1] == nShown[1]) {
- // No more clusters
- if (fReco) return;
- ch++;
- goto newchamber; // next chamber
- }
+ if (fReco == 2 && (nShown[0] || nShown[1])) return; // only one precluster for the combined finder
+ if (ndigits[0] == nShown[0] && ndigits[1] == nShown[1]) return;
+
Float_t xpad, ypad, zpad, zpad0;
- TLine *line[99]={0};
- Int_t nLine = 0;
Bool_t first = kTRUE;
- cout << " *** Event # " << nev << " chamber: " << ch << endl;
+ if (fDebug) cout << " *** Event # " << nev << " chamber: " << ch << endl;
fnPads[0] = fnPads[1] = 0;
- for (Int_t i=0; i<fgkDim; i++) {fPadIJ[1][i] = 0;}
- //for (Int_t iii = 0; iii<999; iii++) {
- for (Int_t iii = 0; iii<2; iii++) {
- Int_t cath = TMath::Odd(iii);
- gAlice->ResetDigits();
- treeD->GetEvent(cath);
- fMuonDigits = muon->GetMUONData()->Digits(ch);
+ for (Int_t i = 0; i < fgkDim; i++) fPadIJ[1][i] = 0;
- ndigits[cath] = fMuonDigits->GetEntriesFast();
- if (!ndigits[0] && !ndigits[1]) {if (fReco) return; ch++; goto newchamber;}
+ for (Int_t iii = fCathBeg; iii < 2; iii++) {
+ Int_t cath = TMath::Odd(iii);
+ ndigits[cath] = fInput->NDigits(cath);
+ if (!ndigits[0] && !ndigits[1]) return;
if (ndigits[cath] == 0) continue;
- cout << " ndigits: " << ndigits[cath] << " " << cath << endl;
+ if (fDebug) cout << " ndigits: " << ndigits[cath] << " " << cath << endl;
AliMUONDigit *mdig;
Int_t digit;
Bool_t eEOC = kTRUE; // end-of-cluster
- for (digit = 0; digit < ndigits[cath]; digit++) {
- mdig = (AliMUONDigit*)fMuonDigits->UncheckedAt(digit);
- if (mdig->Cathode() != cath) continue;
+ for (digit = fPadBeg[cath]; digit < ndigits[cath]; digit++) {
+ mdig = AliMUONClusterInput::Instance()->Digit(cath,digit);
if (first) {
// Find first unused pad
if (fUsed[cath][digit]) continue;
- fSegmentation[cath]->GetPadC(mdig->PadX(),mdig->PadY(),xpad,ypad,zpad0);
+ //if (!fSegmentation[cath]->GetPadC(fInput->DetElemId(),mdig->PadX(),mdig->PadY(),xpad,ypad,zpad0)) {
+ if (!fSegmentation[cath]->HasPad(mdig->PadX(), mdig->PadY())) {
+ // Handle "non-existing" pads
+ fUsed[cath][digit] = kTRUE;
+ continue;
+ }
+ fSegmentation[cath]->GetPadC(mdig->PadX(), mdig->PadY(), xpad, ypad, zpad0);
} else {
if (fUsed[cath][digit]) continue;
- fSegmentation[cath]->GetPadC(mdig->PadX(),mdig->PadY(),xpad,ypad,zpad);
- if (TMath::Abs(zpad-zpad0)>0.1) continue; // different slats
+ //if (!fSegmentation[cath]->GetPadC(fInput->DetElemId(),mdig->PadX(),mdig->PadY(),xpad,ypad,zpad)) {
+ if (!fSegmentation[cath]->HasPad(mdig->PadX(), mdig->PadY())) {
+ // Handle "non-existing" pads
+ fUsed[cath][digit] = kTRUE;
+ continue;
+ }
+ fSegmentation[cath]->GetPadC(mdig->PadX(), mdig->PadY(), xpad, ypad, zpad);
+ //if (TMath::Abs(zpad-zpad0) > 0.1) continue; // different slats
// Find a pad overlapping with the cluster
if (!Overlap(cath,mdig)) continue;
}
// Add pad - recursive call
AddPad(cath,digit);
+ //AZ !!!!!! Temporary fix of St1 overlap regions !!!!!!!!
+ /*
+ if (cath && ch < 2) {
+ Int_t npads = fnPads[0] + fnPads[1] - 1;
+ Int_t cath1 = fPadIJ[0][npads];
+ Int_t idig = TMath::Nint (fXyq[5][npads]);
+ mdig = AliMUONClusterInput::Instance()->Digit(cath1,idig);
+ //fSegmentation[cath1]->GetPadC(fInput->DetElemId(),mdig->PadX(),mdig->PadY(),xpad,ypad,zpad);
+ fSegmentation[cath1]->GetPadC(mdig->PadX(), mdig->PadY(), xpad, ypad, zpad);
+ if (TMath::Abs(zpad-zpad0) > 0.1) zpad0 = zpad;
+ }
+ */
eEOC = kFALSE;
if (digit >= 0) break;
}
if (first && eEOC) {
// No more unused pads
if (cath == 0) continue; // on cathode #0 - check #1
- else {
- // No more clusters
- if (fReco) return;
- ch++;
- goto newchamber; // next chamber
- }
+ else return; // No more clusters
}
if (eEOC) break; // cluster found
first = kFALSE;
- cout << " nPads: " << fnPads[cath] << " " << nShown[cath]+fnPads[cath] << " " << cath << endl;
+ if (fDebug) cout << " nPads: " << fnPads[cath] << " " << nShown[cath]+fnPads[cath] << " " << cath << endl;
} // for (Int_t iii = 0;
-
- if (fReco) goto skip;
- char hName[4];
- for (Int_t cath = 0; cath<2; cath++) {
- // Build histograms
- if (fHist[cath*2]) {fHist[cath*2]->Delete(); fHist[cath*2] = 0;}
- if (fHist[cath*2+1]) {fHist[cath*2+1]->Delete(); fHist[cath*2+1] = 0;}
- if (fnPads[cath] == 0) continue; // cluster on one cathode only
- Float_t wxMin=999, wxMax=0, wyMin=999, wyMax=0;
- Int_t minDx=0, maxDx=0, minDy=0, maxDy=0;
- for (Int_t i=0; i<fnPads[0]+fnPads[1]; i++) {
- if (fPadIJ[0][i] != cath) continue;
- if (fXyq[3][i] < wxMin) {wxMin = fXyq[3][i]; minDx = i;}
- if (fXyq[3][i] > wxMax) {wxMax = fXyq[3][i]; maxDx = i;}
- if (fXyq[4][i] < wyMin) {wyMin = fXyq[4][i]; minDy = i;}
- if (fXyq[4][i] > wyMax) {wyMax = fXyq[4][i]; maxDy = i;}
- }
- cout << minDx << maxDx << minDy << maxDy << endl;
- Int_t nx, ny, padSize;
- Float_t xmin=9999, xmax=-9999, ymin=9999, ymax=-9999;
- if (TMath::Nint(fXyq[3][minDx]*1000) == TMath::Nint(fXyq[3][maxDx]*1000) &&
- TMath::Nint(fXyq[4][minDy]*1000) == TMath::Nint(fXyq[4][maxDy]*1000)) {
- // the same segmentation
- cout << " Same" << endl;
- cout << fXyq[3][minDx] << " " << fXyq[3][maxDx] << " " << fXyq[4][minDy] << " " << fXyq[4][maxDy] << endl;
- for (Int_t i=0; i<fnPads[0]+fnPads[1]; i++) {
- if (fPadIJ[0][i] != cath) continue;
- if (fXyq[0][i] < xmin) xmin = fXyq[0][i];
- if (fXyq[0][i] > xmax) xmax = fXyq[0][i];
- if (fXyq[1][i] < ymin) ymin = fXyq[1][i];
- if (fXyq[1][i] > ymax) ymax = fXyq[1][i];
- }
- xmin -= fXyq[3][minDx]; xmax += fXyq[3][minDx];
- ymin -= fXyq[4][minDy]; ymax += fXyq[4][minDy];
- nx = TMath::Nint ((xmax-xmin)/wxMin/2);
- ny = TMath::Nint ((ymax-ymin)/wyMin/2);
- sprintf(hName,"h%d",cath*2);
- fHist[cath*2] = new TH2F(hName,"cluster",nx,xmin,xmax,ny,ymin,ymax);
- cout << fHist[cath*2] << " " << fnPads[cath] << endl;
- for (Int_t i=0; i<fnPads[0]+fnPads[1]; i++) {
- if (fPadIJ[0][i] != cath) continue;
- fHist[cath*2]->Fill(fXyq[0][i],fXyq[1][i],fXyq[2][i]);
- //cout << fXyq[0][i] << fXyq[1][i] << fXyq[2][i] << endl;
- }
- } else {
- // different segmentation in the cluster
- cout << " Different" << endl;
- cout << fXyq[3][minDx] << " " << fXyq[3][maxDx] << " " << fXyq[4][minDy] << " " << fXyq[4][maxDy] << endl;
- Int_t nOK = 0;
- Int_t indx, locMin, locMax;
- if (TMath::Nint(fXyq[3][minDx]*1000) != TMath::Nint(fXyq[3][maxDx]*1000)) {
- // different segmentation along x
- indx = 0;
- locMin = minDx;
- locMax = maxDx;
- } else {
- // different segmentation along y
- indx = 1;
- locMin = minDy;
- locMax = maxDy;
- }
- Int_t loc = locMin;
- for (Int_t i=0; i<2; i++) {
- // loop over different pad sizes
- if (i>0) loc = locMax;
- padSize = TMath::Nint(fXyq[indx+3][loc]*1000);
- xmin = 9999; xmax = -9999; ymin = 9999; ymax = -9999;
- for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
- if (fPadIJ[0][j] != cath) continue;
- if (TMath::Nint(fXyq[indx+3][j]*1000) != padSize) continue;
- nOK++;
- xmin = TMath::Min (xmin,fXyq[0][j]);
- xmax = TMath::Max (xmax,fXyq[0][j]);
- ymin = TMath::Min (ymin,fXyq[1][j]);
- ymax = TMath::Max (ymax,fXyq[1][j]);
- }
- xmin -= fXyq[3][loc]; xmax += fXyq[3][loc];
- ymin -= fXyq[4][loc]; ymax += fXyq[4][loc];
- nx = TMath::Nint ((xmax-xmin)/fXyq[3][loc]/2);
- ny = TMath::Nint ((ymax-ymin)/fXyq[4][loc]/2);
- sprintf(hName,"h%d",cath*2+i);
- fHist[cath*2+i] = new TH2F(hName,"cluster",nx,xmin,xmax,ny,ymin,ymax);
- for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
- if (fPadIJ[0][j] != cath) continue;
- if (TMath::Nint(fXyq[indx+3][j]*1000) != padSize) continue;
- fHist[cath*2+i]->Fill(fXyq[0][j],fXyq[1][j],fXyq[2][j]);
- }
- } // for (Int_t i=0;
- if (nOK != fnPads[cath]) cout << " *** Too many segmentations: nPads, nOK " << fnPads[cath] << " " << nOK << endl;
- } // if (TMath::Nint(fXyq[3][minDx]*1000)
- } // for (Int_t cath = 0;
-
- // Draw histograms and coordinates
- for (Int_t cath=0; cath<2; cath++) {
- if (cath == 0) ModifyHistos();
- if (fnPads[cath] == 0) continue; // cluster on one cathode only
- if (fDraw) {
- c1->cd(cath+1);
- gPad->SetTheta(55);
- gPad->SetPhi(30);
- Double_t x, y, x0, y0, r1=999, r2=0;
- if (fHist[cath*2+1]) {
- //
- x0 = fHist[cath*2]->GetXaxis()->GetXmin() - 1000*TMath::Cos(30*TMath::Pi()/180);
- y0 = fHist[cath*2]->GetYaxis()->GetXmin() - 1000*TMath::Sin(30*TMath::Pi()/180);
- r1 = 0;
- Int_t ihist=cath*2;
- for (Int_t iy=1; iy<=fHist[ihist]->GetNbinsY(); iy++) {
- y = fHist[ihist]->GetYaxis()->GetBinCenter(iy)
- + fHist[ihist]->GetYaxis()->GetBinWidth(iy);
- for (Int_t ix=1; ix<=fHist[ihist]->GetNbinsX(); ix++) {
- if (fHist[ihist]->GetCellContent(ix,iy) > 0.1) {
- x = fHist[ihist]->GetXaxis()->GetBinCenter(ix)
- + fHist[ihist]->GetXaxis()->GetBinWidth(ix);
- r1 = TMath::Max (r1,TMath::Sqrt((x-x0)*(x-x0)+(y-y0)*(y-y0)));
- }
- }
- }
- ihist = cath*2 + 1 ;
- for (Int_t iy=1; iy<=fHist[ihist]->GetNbinsY(); iy++) {
- y = fHist[ihist]->GetYaxis()->GetBinCenter(iy)
- + fHist[ihist]->GetYaxis()->GetBinWidth(iy);
- for (Int_t ix=1; ix<=fHist[ihist]->GetNbinsX(); ix++) {
- if (fHist[ihist]->GetCellContent(ix,iy) > 0.1) {
- x = fHist[ihist]->GetXaxis()->GetBinCenter(ix)
- + fHist[ihist]->GetXaxis()->GetBinWidth(ix);
- r2 = TMath::Max (r2,TMath::Sqrt((x-x0)*(x-x0)+(y-y0)*(y-y0)));
- }
- }
- }
- cout << r1 << " " << r2 << endl;
- } // if (fHist[cath*2+1])
- if (r1 > r2) {
- //fHist[cath*2]->Draw("lego1");
- fHist[cath*2]->Draw("lego1Fb");
- //if (fHist[cath*2+1]) fHist[cath*2+1]->Draw("lego1SameAxisBb");
- if (fHist[cath*2+1]) fHist[cath*2+1]->Draw("lego1SameAxisBbFb");
- } else {
- //fHist[cath*2+1]->Draw("lego1");
- fHist[cath*2+1]->Draw("lego1Fb");
- //fHist[cath*2]->Draw("lego1SameAxisBb");
- fHist[cath*2]->Draw("lego1SameAxisFbBb");
- }
- c1->Update();
- } // if (fDraw)
- } // for (Int_t cath = 0;
-
- // Draw generated hits
- Double_t xNDC[6];
- hist = fHist[0] ? fHist[0] : fHist[2];
- p2[2] = hist->GetMaximum();
- view = 0;
- if (c1) view = c1->Pad()->GetView();
- cout << " *** GEANT hits *** " << endl;
- fnMu = 0;
- Int_t ix, iy, iok;
- for (Int_t i=0; i<ntracks; i++) {
- treeH->GetEvent(i);
- for (AliMUONHit* mHit=(AliMUONHit*)muon->FirstHit(-1);
- mHit;
- mHit=(AliMUONHit*)muon->NextHit()) {
- if (mHit->Chamber() != ch+1) continue; // chamber number
- if (TMath::Abs(mHit->Z()-zpad0) > 1) continue; // different slat
- p2[0] = p1[0] = mHit->X(); // x-pos of hit
- p2[1] = p1[1] = mHit->Y(); // y-pos
- if (p1[0] < hist->GetXaxis()->GetXmin() ||
- p1[0] > hist->GetXaxis()->GetXmax()) continue;
- if (p1[1] < hist->GetYaxis()->GetXmin() ||
- p1[1] > hist->GetYaxis()->GetXmax()) continue;
- // Check if track comes thru pads with signal
- iok = 0;
- for (Int_t ihist=0; ihist<4; ihist++) {
- if (!fHist[ihist]) continue;
- ix = fHist[ihist]->GetXaxis()->FindBin(p1[0]);
- iy = fHist[ihist]->GetYaxis()->FindBin(p1[1]);
- if (fHist[ihist]->GetCellContent(ix,iy) > 0.5) {iok = 1; break;}
- }
- if (!iok) continue;
- gStyle->SetLineColor(1);
- if (TMath::Abs((Int_t)mHit->Particle()) == 13) {
- gStyle->SetLineColor(4);
- fnMu++;
- if (fnMu <= 2) {
- fxyMu[fnMu-1][0] = p1[0];
- fxyMu[fnMu-1][1] = p1[1];
- }
- }
- printf(" X=%10.4f, Y=%10.4f, Z=%10.4f\n",p1[0],p1[1],mHit->Z());
- if (view) {
- view->WCtoNDC(p1, &xNDC[0]);
- view->WCtoNDC(p2, &xNDC[3]);
- for (Int_t ipad=1; ipad<3; ipad++) {
- c1->cd(ipad);
- //c1->DrawLine(xpad[0],xpad[1],xpad[3],xpad[4]);
- line[nLine] = new TLine(xNDC[0],xNDC[1],xNDC[3],xNDC[4]);
- line[nLine++]->Draw();
- }
- }
- } // for (AliMUONHit* mHit=
- } // for (Int_t i=0; i<ntracks;
-
- // Draw reconstructed coordinates
- listMUONrawclust = muon->GetMUONData()->RawClusters(ch);
- treeR->GetEvent(ch);
- //cout << listMUONrawclust << " " << listMUONrawclust ->GetEntries() << endl;
- AliMUONRawCluster *mRaw;
- gStyle->SetLineColor(3);
- cout << " *** Reconstructed hits *** " << endl;
- for (Int_t i=0; i<listMUONrawclust ->GetEntries(); i++) {
- mRaw = (AliMUONRawCluster*)listMUONrawclust ->UncheckedAt(i);
- if (TMath::Abs(mRaw->GetZ(0)-zpad0) > 1) continue; // different slat
- p2[0] = p1[0] = mRaw->GetX(0); // x-pos of hit
- p2[1] = p1[1] = mRaw->GetY(0); // y-pos
- if (p1[0] < hist->GetXaxis()->GetXmin() ||
- p1[0] > hist->GetXaxis()->GetXmax()) continue;
- if (p1[1] < hist->GetYaxis()->GetXmin() ||
- p1[1] > hist->GetYaxis()->GetXmax()) continue;
- /*
- treeD->GetEvent(cath);
- cout << mRaw->fMultiplicity[0] << mRaw->fMultiplicity[1] << endl;
- for (Int_t j=0; j<mRaw->fMultiplicity[cath]; j++) {
- Int_t digit = mRaw->fIndexMap[j][cath];
- cout << ((AliMUONDigit*)fMuonDigits->UncheckedAt(digit))->Signal() << endl;
- }
- */
- // Check if track comes thru pads with signal
- iok = 0;
- for (Int_t ihist=0; ihist<4; ihist++) {
- if (!fHist[ihist]) continue;
- ix = fHist[ihist]->GetXaxis()->FindBin(p1[0]);
- iy = fHist[ihist]->GetYaxis()->FindBin(p1[1]);
- if (fHist[ihist]->GetCellContent(ix,iy) > 0.5) {iok = 1; break;}
- }
- if (!iok) continue;
- printf(" X=%10.4f, Y=%10.4f, Z=%10.4f\n",p1[0],p1[1],mRaw->GetZ(0));
- if (view) {
- view->WCtoNDC(p1, &xNDC[0]);
- view->WCtoNDC(p2, &xNDC[3]);
- for (Int_t ipad=1; ipad<3; ipad++) {
- c1->cd(ipad);
- line[nLine] = new TLine(xNDC[0],xNDC[1],xNDC[3],xNDC[4]);
- line[nLine++]->Draw();
- }
- }
- } // for (Int_t i=0; i<listMUONrawclust ->GetEntries();
- if (fDraw) c1->Update();
+ fZpad = zpad0;
+ if (fDraw) fDraw->DrawCluster();
-skip:
// Use MLEM for cluster finder
- fZpad = zpad0;
Int_t nMax = 1, localMax[100], maxPos[100];
Double_t maxVal[100];
if (CheckPrecluster(nShown)) {
BuildPixArray();
- if (fnPads[0]+fnPads[1] > 50) nMax = FindLocalMaxima(localMax, maxVal);
+ //*
+ if (fnPads[0]+fnPads[1] > 50) nMax = FindLocalMaxima(fPixArray, localMax, maxVal);
if (nMax > 1) TMath::Sort(nMax, maxVal, maxPos, kTRUE); // in decreasing order
+ Int_t iSimple = 0, nInX = -1, nInY;
+ PadsInXandY(nInX, nInY);
+ if (fDebug) cout << "Pads in X and Y: " << nInX << " " << nInY << endl;
+ if (nMax == 1 && nInX < 4 && nInY < 4) iSimple = 1; //1; // simple cluster
+ //*/
+ /* For test
+ Int_t iSimple = 0, nInX = -1, nInY;
+ PadsInXandY(nInX, nInY);
+ if (fDebug) cout << "Pads in X and Y: " << nInX << " " << nInY << endl;
+ if (nMax == 1 && nInX < 4 && nInY < 4) iSimple = 1; //1; // simple cluster
+ if (!iSimple) nMax = FindLocalMaxima(fPixArray, localMax, maxVal);
+ nMax = 1;
+ if (nMax > 1) TMath::Sort(nMax, maxVal, maxPos, kTRUE); // in decreasing order
+ */
for (Int_t i=0; i<nMax; i++) {
if (nMax > 1) FindCluster(localMax, maxPos[i]);
- if (!MainLoop()) cout << " MainLoop failed " << endl;
+ if (!MainLoop(iSimple)) AliWarning(Form(" MainLoop failed "));
if (i < nMax-1) {
for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
if (fPadIJ[1][j] == 0) continue; // pad charge was not modified
fPadIJ[1][j] = 0;
- fXyq[2][j] = fXyq[5][j]; // use backup charge value
+ fXyq[2][j] = fXyq[6][j]; // use backup charge value
}
}
- }
- }
- if (fReco) goto next;
-
- for (Int_t i=0; i<fnMu; i++) {
- // Check again if muon come thru the used pads (due to extra splitting)
- for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
- if (TMath::Abs(fxyMu[i][0]-fXyq[0][j])<fXyq[3][j] &&
- TMath::Abs(fxyMu[i][1]-fXyq[1][j])<fXyq[4][j]) {
- printf("%12.3e %12.3e %12.3e %12.3e\n",fxyMu[i][2],fxyMu[i][3],fxyMu[i][4],fxyMu[i][5]);
- if (lun) fprintf(lun,"%4d %2d %12.3e %12.3e %12.3e %12.3e\n",nev,ch,fxyMu[i][2],fxyMu[i][3],fxyMu[i][4],fxyMu[i][5]);
- break;
- }
- }
- } // for (Int_t i=0; i<fnMu;
-
- // What's next?
- char command[8];
- cout << " What is next? " << endl;
- command[0] = ' ';
- if (fDraw) gets(command);
- if (command[0] == 'n' || command[0] == 'N') {nev++; goto newev;} // next event
- else if (command[0] == 'q' || command[0] == 'Q') {fclose(lun); return;} // exit display
- //else if (command[0] == 'r' || command[0] == 'R') goto redraw; // redraw points
- else if (command[0] == 'c' || command[0] == 'C') {
- // new chamber
- sscanf(command+1,"%d",&ch);
- goto newchamber;
- }
- else if (command[0] == 'e' || command[0] == 'E') {
- // new event
- sscanf(command+1,"%d",&nev);
- goto newev;
- }
- else goto next; // Next cluster
-}
-
-//_____________________________________________________________________________
-void AliMUONClusterFinderAZ::ModifyHistos(void)
-{
- // Modify histograms to bring them to the same size
- Int_t nhist = 0;
- Float_t hlim[4][4], hbin[4][4]; // first index - xmin, xmax, ymin, ymax
- Float_t binMin[4] = {999,999,999,999};
-
- for (Int_t i=0; i<4; i++) {
- if (!fHist[i]) continue;
- hlim[0][nhist] = fHist[i]->GetXaxis()->GetXmin(); // xmin
- hlim[1][nhist] = fHist[i]->GetXaxis()->GetXmax(); // xmax
- hlim[2][nhist] = fHist[i]->GetYaxis()->GetXmin(); // ymin
- hlim[3][nhist] = fHist[i]->GetYaxis()->GetXmax(); // ymax
- hbin[0][nhist] = hbin[1][nhist] = fHist[i]->GetXaxis()->GetBinWidth(1);
- hbin[2][nhist] = hbin[3][nhist] = fHist[i]->GetYaxis()->GetBinWidth(1);
- binMin[0] = TMath::Min(binMin[0],hbin[0][nhist]);
- binMin[2] = TMath::Min(binMin[2],hbin[2][nhist]);
- nhist++;
- }
- binMin[1] = binMin[0];
- binMin[3] = binMin[2];
- cout << " Nhist: " << nhist << endl;
-
- Int_t imin, imax;
- for (Int_t lim=0; lim<4; lim++) {
- while (1) {
- imin = TMath::LocMin(nhist,hlim[lim]);
- imax = TMath::LocMax(nhist,hlim[lim]);
- if (TMath::Abs(hlim[lim][imin]-hlim[lim][imax])<0.01*binMin[lim]) break;
- if (lim == 0 || lim == 2) {
- // find lower limit
- hlim[lim][imax] -= hbin[lim][imax];
- } else {
- // find upper limit
- hlim[lim][imin] += hbin[lim][imin];
- }
- } // while (1)
- }
-
- // Rebuild histograms
- nhist = 0;
- TH2F *hist = 0;
- Int_t nx, ny;
- Double_t x, y, cont, cmax=0;
- char hName[4];
- for (Int_t ihist=0; ihist<4; ihist++) {
- if (!fHist[ihist]) continue;
- nx = TMath::Nint((hlim[1][nhist]-hlim[0][nhist])/hbin[0][nhist]);
- ny = TMath::Nint((hlim[3][nhist]-hlim[2][nhist])/hbin[2][nhist]);
- //hist = new TH2F("h","hist",nx,hlim[0][nhist],hlim[1][nhist],ny,hlim[2][nhist],hlim[3][nhist]);
- sprintf(hName,"hh%d",ihist);
- hist = new TH2F(hName,"hist",nx,hlim[0][nhist],hlim[1][nhist],ny,hlim[2][nhist],hlim[3][nhist]);
- for (Int_t i=1; i<=fHist[ihist]->GetNbinsX(); i++) {
- x = fHist[ihist]->GetXaxis()->GetBinCenter(i);
- for (Int_t j=1; j<=fHist[ihist]->GetNbinsY(); j++) {
- y = fHist[ihist]->GetYaxis()->GetBinCenter(j);
- cont = fHist[ihist]->GetCellContent(i,j);
- hist->Fill(x,y,cont);
- }
- }
- cmax = TMath::Max (cmax,hist->GetMaximum());
- fHist[ihist]->Delete();
- fHist[ihist] = new TH2F(*hist);
- hist->Delete();
- nhist++;
- }
- printf("%f \n",cmax);
-
- for (Int_t ihist=0; ihist<4; ihist++) {
- if (!fHist[ihist]) continue;
- fHist[ihist]->SetMaximum(cmax);
+ } // for (Int_t i=0; i<nMax;
+ if (nMax > 1) ((TH2D*) gROOT->FindObject("anode"))->Delete();
+ TH2D *mlem = (TH2D*) gROOT->FindObject("mlem");
+ if (mlem) mlem->Delete();
}
+ if (!fDraw || fDraw->Next()) goto next;
}
//_____________________________________________________________________________
void AliMUONClusterFinderAZ::AddPad(Int_t cath, Int_t digit)
{
// Add pad to the cluster
- AliMUONDigit *mdig = (AliMUONDigit*)fMuonDigits->UncheckedAt(digit);
+ AliMUONDigit *mdig = fInput->Digit(cath,digit);
Int_t charge = mdig->Signal();
// get the center of the pad
- Float_t xpad, ypad, zpad;
- fSegmentation[cath]->GetPadC(mdig->PadX(), mdig->PadY(), xpad, ypad, zpad);
-
- Int_t isec = fSegmentation[cath]->Sector(mdig->PadX(), mdig->PadY());
+ Float_t xpad, ypad, zpad0;
+ //if (!fSegmentation[cath]->GetPadC(fInput->DetElemId(),mdig->PadX(),mdig->PadY(),xpad,ypad,zpad0)) { // Handle "non-existing" pads
+ if (!fSegmentation[cath]->HasPad(mdig->PadX(), mdig->PadY())) {
+ fUsed[cath][digit] = kTRUE;
+ return;
+ }
+ fSegmentation[cath]->GetPadC(mdig->PadX(), mdig->PadY(), xpad, ypad, zpad0);
+ Int_t isec = fSegmentation[cath]->Sector(mdig->PadX(), mdig->PadY());
Int_t nPads = fnPads[0] + fnPads[1];
fXyq[0][nPads] = xpad;
fXyq[1][nPads] = ypad;
fXyq[3][nPads] = fSegmentation[cath]->Dpx(isec)/2;
fXyq[4][nPads] = fSegmentation[cath]->Dpy(isec)/2;
fXyq[5][nPads] = digit;
+ fXyq[6][nPads] = 0;
fPadIJ[0][nPads] = cath;
fPadIJ[1][nPads] = 0;
+ fPadIJ[2][nPads] = mdig->PadX();
+ fPadIJ[3][nPads] = mdig->PadY();
fUsed[cath][digit] = kTRUE;
- //cout << " bbb " << fXyq[cath][2][nPads] << " " << fXyq[cath][0][nPads] << " " << fXyq[cath][1][nPads] << " " << fXyq[cath][3][nPads] << " " << fXyq[cath][4][nPads] << " " << zpad << " " << nPads << endl;
+ if (fDebug) printf(" bbb %d %d %f %f %f %f %f %4d %3d %3d \n", nPads, cath, xpad, ypad, zpad0, fXyq[3][nPads]*2, fXyq[4][nPads]*2, charge, mdig->PadX(), mdig->PadY());
fnPads[cath]++;
// Check neighbours
Int_t nn, ix, iy, xList[10], yList[10];
AliMUONDigit *mdig1;
- Int_t ndigits = fMuonDigits->GetEntriesFast();
- fSegmentation[cath]->Neighbours(mdig->PadX(),mdig->PadY(),&nn,xList,yList);
- for (Int_t in=0; in<nn; in++) {
- ix=xList[in];
- iy=yList[in];
+ Int_t ndigits = fInput->NDigits(cath);
+ fSegmentation[cath]->Neighbours(mdig->PadX(), mdig->PadY(), &nn, xList, yList);
+ for (Int_t in = 0; in < nn; in++) {
+ ix = xList[in];
+ iy = yList[in];
for (Int_t digit1 = 0; digit1 < ndigits; digit1++) {
if (digit1 == digit) continue;
- mdig1 = (AliMUONDigit*)fMuonDigits->UncheckedAt(digit1);
- if (mdig1->Cathode() != cath) continue;
+ mdig1 = fInput->Digit(cath,digit1);
if (!fUsed[cath][digit1] && mdig1->PadX() == ix && mdig1->PadY() == iy) {
fUsed[cath][digit1] = kTRUE;
// Add pad - recursive call
AddPad(cath,digit1);
}
} //for (Int_t digit1 = 0;
- } // for (Int_t in=0;
+ } // for (Int_t in = 0;
}
//_____________________________________________________________________________
-Bool_t AliMUONClusterFinderAZ::Overlap(Int_t cath, TObject *dig)
+Bool_t AliMUONClusterFinderAZ::Overlap(Int_t cath, AliMUONDigit *mdig)
{
// Check if the pad from one cathode overlaps with a pad
// in the precluster on the other cathode
- AliMUONDigit *mdig = (AliMUONDigit*) dig;
-
Float_t xpad, ypad, zpad;
fSegmentation[cath]->GetPadC(mdig->PadX(), mdig->PadY(), xpad, ypad, zpad);
- Int_t isec = fSegmentation[cath]->Sector(mdig->PadX(), mdig->PadY());
+ Int_t isec = fSegmentation[cath]->Sector(mdig->PadX(), mdig->PadY());
Float_t xy1[4], xy12[4];
xy1[0] = xpad - fSegmentation[cath]->Dpx(isec)/2;
return kTRUE;
}
-//_____________________________________________________________________________
-/*
-Bool_t AliMUONClusterFinderAZ::Overlap(Int_t i, Int_t j, Float_t *xy12, Int_t iSkip)
-{
- // Check if the pads i and j overlap and return overlap area
-
- Float_t xy1[4], xy2[4];
- return Overlap(xy1, xy2, xy12, iSkip);
-}
-*/
//_____________________________________________________________________________
Bool_t AliMUONClusterFinderAZ::CheckPrecluster(Int_t *nShown)
{
// Check precluster in order to attempt to simplify it (mostly for
// two-cathode preclusters)
- Int_t i1, i2;
+ Int_t i1, i2, cath=0, digit=0;
Float_t xy1[4], xy12[4];
Int_t npad = fnPads[0] + fnPads[1];
+ if (npad == 1) {
+ // Disregard one-pad clusters (leftovers from splitting)
+ nShown[0] += fnPads[0];
+ nShown[1] += fnPads[1];
+ return kFALSE;
+ }
// If pads have the same size take average of pads on both cathodes
- Int_t sameSize = (fnPads[0] && fnPads[1]) ? 1 : 0;
+ //Int_t sameSize = (fnPads[0] && fnPads[1]) ? 1 : 0;
+ Int_t sameSize = 0; //AZ - 17-01-06
+
if (sameSize) {
Double_t xSize = -1, ySize = 0;
for (Int_t i=0; i<npad; i++) {
if (TMath::Abs(xSize-fXyq[3][i]) > 1.e-4 || TMath::Abs(ySize-fXyq[4][i]) > 1.e-4) { sameSize = 0; break; }
}
} // if (sameSize)
- if (sameSize && (fnPads[0] > 2 || fnPads[1] > 2)) {
+ if (sameSize && fnPads[0] == 1 && fnPads[1] == 1) sameSize = 0; //AZ
+ // Handle shift by half a pad in Station 1
+ if (sameSize) {
+ Int_t cath0 = fPadIJ[0][0];
+ for (Int_t i = 1; i < npad; i++) {
+ if (fPadIJ[0][i] == cath0) continue;
+ Double_t dx = TMath::Abs ((fXyq[0][i] - fXyq[0][0]) / fXyq[3][i] / 2);
+ Int_t idx = (Int_t) TMath::Abs ((fXyq[0][i] - fXyq[0][0]) / fXyq[3][i] / 2);
+ if (TMath::Abs (dx - idx) > 0.001) sameSize = 0;
+ break;
+ }
+ } // if (sameSize)
+
+ if (sameSize && (fnPads[0] >= 2 || fnPads[1] >= 2)) {
nShown[0] += fnPads[0];
nShown[1] += fnPads[1];
fnPads[0] = fnPads[1] = 0;
if (fXyq[2][i] < 0) continue; // used pad
fXyq[2][fnPads[0]] = fXyq[2][i];
div = 1;
+ cath = fPadIJ[0][i];
for (Int_t j=i+1; j<npad; j++) {
if (fPadIJ[0][j] == fPadIJ[0][i]) continue; // same cathode
if (TMath::Abs(fXyq[0][j]-fXyq[0][i]) > 1.e-4) continue;
fXyq[2][fnPads[0]] += fXyq[2][j];
div = 2;
fXyq[2][j] = -2;
+ if (cath) fXyq[5][fnPads[0]] = fXyq[5][j]; // save digit number for cath 0
break;
}
+ // Flag that the digit from the other cathode
+ if (cath && div == 1) fXyq[5][fnPads[0]] = -fXyq[5][i] - 1;
+ // If low pad charge take the other equal to 0
+ //if (div == 1 && fXyq[2][fnPads[0]] < fgkZeroSuppression + 1.5*3) div = 2;
fXyq[2][fnPads[0]] /= div;
fXyq[0][fnPads[0]] = fXyq[0][i];
fXyq[1][fnPads[0]] = fXyq[1][i];
+ fPadIJ[2][fnPads[0]] = fPadIJ[2][i];
+ fPadIJ[3][fnPads[0]] = fPadIJ[3][i];
fPadIJ[0][fnPads[0]++] = 0;
}
} // if (sameSize)
} // for (Int_t i=0;
// Check if all pads overlap
- Int_t digit=0, cath, nFlags=0;
- for (Int_t i=0; i<npad; i++) {nFlags += !flags[i];}
- if (nFlags) cout << " nFlags = " << nFlags << endl;
+ Int_t nFlags=0;
+ for (Int_t i=0; i<npad; i++) {
+ if (flags[i]) continue;
+ nFlags ++;
+ if (fDebug) cout << i << " " << fPadIJ[0][i] << " " << fXyq[0][i] << " " << fXyq[1][i] << endl;
+ }
+ if (fDebug && nFlags) cout << " nFlags = " << nFlags << endl;
//if (nFlags > 2 || (Float_t)nFlags / npad > 0.2) { // why 2 ??? - empirical choice
if (nFlags > 0) {
for (Int_t i=0; i<npad; i++) {
if (flags[i]) continue;
digit = TMath::Nint (fXyq[5][i]);
cath = fPadIJ[0][i];
+ // Check for edge effect (missing pads on the other cathode)
+ Int_t cath1 = TMath::Even(cath), ix, iy;
+ ix = iy = 0;
+ //if (!fSegmentation[cath1]->GetPadI(fInput->DetElemId(),fXyq[0][i],fXyq[1][i],fZpad,ix,iy)) continue;
+ if (!fSegmentation[cath1]->HasPad(fXyq[0][i], fXyq[1][i], fZpad)) continue;
+ if (nFlags == 1 && fXyq[2][i] < fgkZeroSuppression * 3) continue;
fUsed[cath][digit] = kFALSE; // release pad
fXyq[2][i] = -2;
fnPads[cath]--;
}
+ if (fDraw) fDraw->UpdateCluster(npad);
} // if (nFlags > 2)
// Check correlations of cathode charges
for (Int_t i=0; i<npad; i++) {
cath = fPadIJ[0][i];
if (fXyq[2][i] > 0) sum[cath] += fXyq[2][i];
- if (fXyq[2][i] > fResponse->MaxAdc()-1) over[cath] = 0;
+ if (fXyq[2][i] > fgkSaturation-1) over[cath] = 0;
}
- cout << " Total charge: " << sum[0] << " " << sum[1] << endl;
+ if (fDebug) cout << " Total charge: " << sum[0] << " " << sum[1] << endl;
if ((over[0] || over[1]) && TMath::Abs(sum[0]-sum[1])/(sum[0]+sum[1])*2 > 1) { // 3 times difference
- cout << " Release " << endl;
+ if (fDebug) cout << " Release " << endl;
// Big difference
- cath = sum[0]>sum[1] ? 0 : 1;
- Int_t imax = 0;
- Double_t cmax=-1;
+ cath = sum[0] > sum[1] ? 0 : 1;
+ Int_t imax = 0, imin = 0;
+ Double_t cmax = -1, cmin = 9999, dxMin = 0, dyMin = 0;
Double_t *dist = new Double_t[npad];
- for (Int_t i=0; i<npad; i++) {
- if (fPadIJ[0][i] != cath) continue;
+ for (Int_t i = 0; i < npad; i++) {
+ if (fPadIJ[0][i] != cath || fXyq[2][i] < 0) continue;
+ if (fXyq[2][i] < cmin) {
+ cmin = fXyq[2][i];
+ imin = i;
+ }
if (fXyq[2][i] < cmax) continue;
cmax = fXyq[2][i];
imax = i;
}
// Arrange pads according to their distance to the max,
// normalized to the pad size
- for (Int_t i=0; i<npad; i++) {
+ for (Int_t i = 0; i < npad; i++) {
dist[i] = 0;
- if (fPadIJ[0][i] != cath) continue;
+ if (fPadIJ[0][i] != cath || fXyq[2][i] < 0) continue;
if (i == imax) continue;
- if (fXyq[2][i] < 0) continue;
- dist[i] = (fXyq[0][i]-fXyq[0][imax])*(fXyq[0][i]-fXyq[0][imax])/
- fXyq[3][imax]/fXyq[3][imax]/4;
- dist[i] += (fXyq[1][i]-fXyq[1][imax])*(fXyq[1][i]-fXyq[1][imax])/
- fXyq[4][imax]/fXyq[4][imax]/4;
- dist[i] = TMath::Sqrt (dist[i]);
+ Double_t dx = (fXyq[0][i] - fXyq[0][imax]) / fXyq[3][imax] / 2;
+ Double_t dy = (fXyq[1][i] - fXyq[1][imax]) / fXyq[4][imax] / 2;
+ dist[i] = TMath::Sqrt (dx * dx + dy * dy);
+ if (i == imin) {
+ cmin = dist[i] + 0.001; // distance to the pad with minimum charge
+ dxMin = dx;
+ dyMin = dy;
+ }
}
TMath::Sort(npad, dist, flags, kFALSE); // in increasing order
Int_t indx;
Double_t xmax = -1;
- for (Int_t i=0; i<npad; i++) {
+ for (Int_t i = 0; i < npad; i++) {
indx = flags[i];
- if (fPadIJ[0][indx] != cath) continue;
- if (fXyq[2][indx] < 0) continue;
- if (fXyq[2][indx] <= cmax || TMath::Abs(dist[indx]-xmax)<1.e-3) {
+ if (fPadIJ[0][indx] != cath || fXyq[2][indx] < 0) continue;
+ if (dist[indx] > cmin) {
+ // Farther than the minimum pad
+ Double_t dx = (fXyq[0][indx] - fXyq[0][imax]) / fXyq[3][imax] / 2;
+ Double_t dy = (fXyq[1][indx] - fXyq[1][imax]) / fXyq[4][imax] / 2;
+ dx *= dxMin;
+ dy *= dyMin;
+ if (dx >= 0 && dy >= 0) continue;
+ if (TMath::Abs(dx) > TMath::Abs(dy) && dx >= 0) continue;
+ if (TMath::Abs(dy) > TMath::Abs(dx) && dy >= 0) continue;
+ }
+ if (fXyq[2][indx] <= cmax || TMath::Abs(dist[indx]-xmax) < 1.e-3) {
// Release pads
- if (TMath::Abs(dist[indx]-xmax)<1.e-3)
+ if (TMath::Abs(dist[indx]-xmax) < 1.e-3)
cmax = TMath::Max((Double_t)(fXyq[2][indx]),cmax);
else cmax = fXyq[2][indx];
xmax = dist[indx];
fUsed[cath][digit] = kFALSE;
fXyq[2][indx] = -2;
fnPads[cath]--;
- // xmax = dist[i]; // Bug?
+ }
+ } // for (Int_t i = 0; i < npad;
+
+ // Check pad overlaps once more
+ for (Int_t j = 0; j < npad; j++) flags[j] = 0;
+ for (Int_t k = 0; k < npad; k++) {
+ if (fXyq[2][k] < 0 || fPadIJ[0][k] != i1) continue;
+ xy1[0] = fXyq[0][k] - fXyq[3][k];
+ xy1[1] = fXyq[0][k] + fXyq[3][k];
+ xy1[2] = fXyq[1][k] - fXyq[4][k];
+ xy1[3] = fXyq[1][k] + fXyq[4][k];
+ for (Int_t j = 0; j < npad; j++) {
+ if (fXyq[2][j] < 0) continue;
+ if (fPadIJ[0][j] != i2) continue;
+ if (!Overlap(xy1, j, xy12, 0)) continue;
+ flags[k] = flags[j] = 1; // mark overlapped pads
+ } // for (Int_t j = 0;
+ } // for (Int_t k = 0;
+ nFlags = 0;
+ for (Int_t j = 0; j < npad; j++) {
+ if (fXyq[2][j] < 0 || flags[j]) continue;
+ nFlags ++;
+ }
+ if (nFlags == fnPads[0] + fnPads[1]) {
+ // No overlap
+ for (Int_t j = 0; j < npad; j++) {
+ if (fXyq[2][j] < 0 || fPadIJ[0][j] != cath) continue;
+ fXyq[2][j] = -2;
+ fnPads[cath]--;
}
- else break;
- }
+ }
delete [] dist; dist = 0;
+ if (fDraw) fDraw->UpdateCluster(npad);
} // TMath::Abs(sum[0]-sum[1])...
} // if (fnPads[0] && fnPads[1])
delete [] flags; flags = 0;
for (Int_t j=end; j>beg; j--) {
if (fXyq[2][j] < 0) continue;
end = j - 1;
- for (Int_t j1=0; j1<2; j1++) {
+ for (Int_t j1=0; j1<4; j1++) {
padij = fPadIJ[j1][beg];
fPadIJ[j1][beg] = fPadIJ[j1][j];
fPadIJ[j1][j] = padij;
beg++;
} // while
npad = fnPads[0] + fnPads[1];
- if (npad > 500) { cout << " ***** Too large cluster. Give up. " << npad << endl; return kFALSE; }
+ if (npad > 500) {
+ AliWarning(Form(" *** Too large cluster. Give up. %d ", npad));
+ return kFALSE;
+ }
// Back up charge value
- for (Int_t j=0; j<npad; j++) fXyq[5][j] = fXyq[2][j];
+ for (Int_t j = 0; j < npad; j++) fXyq[6][j] = fXyq[2][j];
return kTRUE;
}
nPix++;
}
} else { // two-cathode precluster
- for (Int_t i=0; i<npad; i++) {
+ i1 = fPadIJ[0][0];
+ i2 = TMath::Even (i1);
+ for (Int_t i = 0; i < npad; i++) {
if (fPadIJ[0][i] != i1) continue;
xy1[0] = fXyq[0][i] - fXyq[3][i];
xy1[1] = fXyq[0][i] + fXyq[3][i];
xy1[2] = fXyq[1][i] - fXyq[4][i];
xy1[3] = fXyq[1][i] + fXyq[4][i];
- for (Int_t j=0; j<npad; j++) {
+ for (Int_t j = 1; j < npad; j++) {
if (fPadIJ[0][j] != i2) continue;
if (!Overlap(xy1, j, xy12, 1)) continue;
pixPtr = new AliMUONPixel();
}
pixPtr->SetCharge(TMath::Min (fXyq[2][i],fXyq[2][j])); //charge
fPixArray->Add((TObject*)pixPtr);
+ //cout << nPix << " " << pixPtr->Coord(0) << " " << pixPtr->Size(0) << " " << pixPtr->Coord(1) << " " << pixPtr->Size(1) << " " << pixPtr->Charge() << endl;
nPix++;
} // for (Int_t j=0;
} // for (Int_t i=0;
} // else
- Float_t wxmin=999, wymin=999;
- for (Int_t i=0; i<npad; i++) {
- if (fPadIJ[0][i] == i1) wymin = TMath::Min (wymin,fXyq[4][i]);
- if (fPadIJ[0][i] == i2) wxmin = TMath::Min (wxmin,fXyq[3][i]);
+ Float_t xPadMin = 999, yPadMin = 999;
+ for (Int_t i = 0; i < npad; i++) {
+ xPadMin = TMath::Min (xPadMin, fXyq[3][i]);
+ yPadMin = TMath::Min (yPadMin, fXyq[4][i]);
+ }
+ if (fDebug) cout << xPadMin << " " << yPadMin << endl;
+
+ Float_t wxmin = 999, wymin = 999;
+ for (Int_t i = 0; i < nPix; i++) {
+ pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
+ wxmin = TMath::Min ((Double_t)wxmin, pixPtr->Size(0));
+ wymin = TMath::Min ((Double_t)wymin, pixPtr->Size(1));
}
- cout << wxmin << " " << wymin << endl;
+ if (fDebug) cout << wxmin << " " << wymin << endl;
+ wxmin = TMath::Abs (wxmin - xPadMin/2) > 0.001 ? xPadMin : xPadMin / 2;
+ wymin = TMath::Abs (wymin - yPadMin/2) > 0.001 ? yPadMin : yPadMin / 2;
+ //wxmin = xPadMin; wymin = yPadMin;
// Check if small pixel X-size
- AjustPixel(wxmin, 0);
+ AdjustPixel(wxmin, 0);
// Check if small pixel Y-size
- AjustPixel(wymin, 1);
+ AdjustPixel(wymin, 1);
// Check if large pixel size
- AjustPixel(wxmin, wymin);
+ AdjustPixel(wxmin, wymin);
// Remove discarded pixels
for (Int_t i=0; i<nPix; i++) {
nPix = fPixArray->GetEntriesFast();
if (nPix > npad) {
- cout << nPix << endl;
+ if (fDebug) cout << nPix << endl;
// Too many pixels - sort and remove pixels with the lowest signal
fPixArray->Sort();
for (Int_t i=npad; i<nPix; i++) {
for (Int_t i=0; i<nPix; i++) {
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
//pixPtr->SetCharge(10);
- cout << i+1 << " " << pixPtr->Coord(0) << " " << pixPtr->Coord(1) << " " << pixPtr->Size(0) << " " << pixPtr->Size(1) << endl;
+ if (fDebug) cout << i+1 << " " << pixPtr->Coord(0) << " " << pixPtr->Coord(1) << " " << pixPtr->Size(0) << " " << pixPtr->Size(1) << endl;
}
}
//_____________________________________________________________________________
-void AliMUONClusterFinderAZ::AjustPixel(Float_t width, Int_t ixy)
+void AliMUONClusterFinderAZ::AdjustPixel(Float_t width, Int_t ixy)
{
- // Check if some pixels have small size (ajust if necessary)
+ // Check if some pixels have small size (adjust if necessary)
AliMUONPixel *pixPtr, *pixPtr1 = 0;
Int_t ixy1 = TMath::Even(ixy);
if (pixPtr->Charge() < 1) continue; // discarded pixel
if (pixPtr->Size(ixy)-width < -1.e-4) {
// try to merge
- cout << " Small X or Y: " << ixy << " " << pixPtr->Size(ixy) << " " << width << " " << pixPtr->Coord(0) << " " << pixPtr->Coord(1) << endl;
+ if (fDebug) cout << i << " Small X or Y: " << ixy << " " << pixPtr->Size(ixy) << " " << width << " " << pixPtr->Coord(0) << " " << pixPtr->Coord(1) << endl;
for (Int_t j=i+1; j<nPix; j++) {
pixPtr1 = (AliMUONPixel*) fPixArray->UncheckedAt(j);
if (pixPtr1->Charge() < 1) continue; // discarded pixel
if (TMath::Abs(pixPtr1->Coord(ixy1)-pixPtr->Coord(ixy1)) > 1.e-4) continue; // different rows/columns
if (TMath::Abs(pixPtr1->Coord(ixy)-pixPtr->Coord(ixy)) < 2*width) {
// merge
+ Double_t tmp = pixPtr->Coord(ixy) + pixPtr1->Size(ixy) *
+ TMath::Sign (1., pixPtr1->Coord(ixy) - pixPtr->Coord(ixy));
+ pixPtr->SetCoord(ixy, tmp);
pixPtr->SetSize(ixy, width);
- pixPtr->SetCoord(ixy, (pixPtr->Coord(ixy)+pixPtr1->Coord(ixy))/2);
pixPtr->SetCharge(TMath::Min (pixPtr->Charge(),pixPtr1->Charge()));
pixPtr1->SetCharge(0);
pixPtr1 = 0;
//else if (pixPtr1->Charge() > 0.5 || i == nPix-1) {
if (pixPtr1 || i == nPix-1) {
// edge pixel - just increase its size
- cout << " Edge ..." << endl;
+ if (fDebug) cout << " Edge ..." << endl;
for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
- // ???if (fPadIJ[0][j] != i1) continue;
- if (TMath::Abs(pixPtr->Coord(ixy1)-fXyq[ixy1][j]) > 1.e-4) continue;
+ //if (fPadIJ[0][j] != ixy1) continue;
+ //???-check if (TMath::Abs(pixPtr->Coord(ixy1)-fXyq[ixy1][j]) > 1.e-4) continue;
if (pixPtr->Coord(ixy) < fXyq[ixy][j])
- pixPtr->Shift(ixy, -pixPtr->Size(ixy));
- else pixPtr->Shift(ixy, pixPtr->Size(ixy));
+ //pixPtr->Shift(ixy, -pixPtr->Size(ixy));
+ pixPtr->Shift(ixy, pixPtr->Size(ixy)-width);
+ //else pixPtr->Shift(ixy, pixPtr->Size(ixy));
+ else pixPtr->Shift(ixy, -pixPtr->Size(ixy)+width);
pixPtr->SetSize(ixy, width);
break;
}
}
//_____________________________________________________________________________
-void AliMUONClusterFinderAZ::AjustPixel(Float_t wxmin, Float_t wymin)
+void AliMUONClusterFinderAZ::AdjustPixel(Float_t wxmin, Float_t wymin)
{
- // Check if some pixels have large size (ajust if necessary)
+ // Check if some pixels have large size (adjust if necessary)
- Int_t nx, ny;
- Int_t nPix = fPixArray->GetEntriesFast();
- AliMUONPixel *pixPtr, *pixPtr1, pix;
+ Int_t n1[2], n2[2], iOK = 1, nPix = fPixArray->GetEntriesFast();
+ AliMUONPixel *pixPtr, pix;
+ Double_t xy0[2] = {9999, 9999}, wxy[2], dist[2];
// Check if large pixel size
- for (Int_t i=0; i<nPix; i++) {
+ for (Int_t i = 0; i < nPix; i++) {
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
if (pixPtr->Charge() < 1) continue; // discarded pixel
- if (pixPtr->Size(0)-wxmin > 1.e-4 || pixPtr->Size(1)-wymin > 1.e-4) {
- cout << " Different " << pixPtr->Size(0) << " " << wxmin << " " << pixPtr->Size(1) << " " << wymin << endl;
- pix = *pixPtr;
- nx = TMath::Nint (pix.Size(0)/wxmin);
- ny = TMath::Nint (pix.Size(1)/wymin);
- pix.Shift(0, -pix.Size(0)-wxmin);
- pix.Shift(1, -pix.Size(1)-wymin);
- pix.SetSize(0, wxmin);
- pix.SetSize(1, wymin);
- for (Int_t ii=0; ii<nx; ii++) {
- pix.Shift(0, wxmin*2);
- for (Int_t jj=0; jj<ny; jj++) {
- pix.Shift(1, wymin*2);
- pixPtr1 = new AliMUONPixel(pix);
- fPixArray->Add((TObject*)pixPtr1);
- }
+ if (pixPtr->Size(0) - wxmin < 1.e-4) {
+ if (xy0[0] > 9998) xy0[0] = pixPtr->Coord(0); // position of a "normal" pixel
+ if (pixPtr->Size(1) - wymin < 1.e-4) {
+ if (xy0[1] > 9998) xy0[1] = pixPtr->Coord(1); // position of a "normal" pixel
+ continue;
+ } else iOK = 0; // large pixel
+ } else {
+ iOK = 0; // large pixel
+ if (xy0[1] > 9998 && pixPtr->Size(1) - wymin < 1.e-4) xy0[1] = pixPtr->Coord(1); // "normal" pixel
+ }
+ if (xy0[0] < 9998 && xy0[1] < 9998) break;
+ }
+ if (iOK) return;
+
+ wxy[0] = wxmin;
+ wxy[1] = wymin;
+ //cout << xy0[0] << " " << xy0[1] << endl;
+ for (Int_t i = 0; i < nPix; i++) {
+ pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
+ if (pixPtr->Charge() < 1) continue; // discarded pixel
+ n1[0] = n1[1] = 999;
+ n2[0] = n2[1] = 1;
+ for (Int_t j = 0; j < 2; j++) {
+ if (pixPtr->Size(j) - wxy[j] < 1.e-4) continue;
+ dist[j] = (pixPtr->Coord(j) - xy0[j]) / wxy[j] / 2; // normalized distance to "normal" pixel
+ n2[j] = TMath::Nint (pixPtr->Size(j) / wxy[j]);
+ n1[j] = n2[j] == 1 ? TMath::Nint(dist[j]) : (Int_t)dist[j];
+ }
+ if (n1[0] > 998 && n1[1] > 998) continue;
+ if (fDebug) cout << " Different " << pixPtr->Size(0) << " " << wxy[0] << " "
+ << pixPtr->Size(1) << " " << wxy[1] <<endl;
+
+ if (n2[0] > 2 || n2[1] > 2) {
+ //cout << n2[0] << " " << n2[1] << endl;
+ if (n2[0] > 2 && n1[0] < 999) n1[0]--;
+ if (n2[1] > 2 && n1[1] < 999) n1[1]--;
+ }
+ //cout << n1[0] << " " << n2[0] << " " << n1[1] << " " << n2[1] << endl;
+ pix = *pixPtr;
+ pix.SetSize(0, wxy[0]); pix.SetSize(1, wxy[1]);
+ //pixPtr->Print();
+ for (Int_t ii = 0; ii < n2[0]; ii++) {
+ if (n1[0] < 999) pix.SetCoord(0, xy0[0] + (n1[0] + TMath::Sign(1.,dist[0]) * ii) * 2 * wxy[0]);
+ for (Int_t jj = 0; jj < n2[1]; jj++) {
+ if (n1[1] < 999) pix.SetCoord(1, xy0[1] + (n1[1] + TMath::Sign(1.,dist[1]) * jj) * 2 * wxy[1]);
+ fPixArray->Add(new AliMUONPixel(pix));
+ //pix.Print();
}
- pixPtr->SetCharge(0);
}
- } // for (Int_t i=0; i<nPix;
- return;
+ pixPtr->SetCharge(0);
+ } // for (Int_t i = 0; i < nPix;
}
//_____________________________________________________________________________
-Bool_t AliMUONClusterFinderAZ::MainLoop()
+Bool_t AliMUONClusterFinderAZ::MainLoop(Int_t iSimple)
{
// Repeat MLEM algorithm until pixel size becomes sufficiently small
Int_t ix, iy;
//Int_t nn, xList[10], yList[10];
Int_t nPix = fPixArray->GetEntriesFast();
- Int_t npadTot = fnPads[0] + fnPads[1], npadOK = 0;
AliMUONPixel *pixPtr = 0;
Double_t *coef = 0, *probi = 0;
- for (Int_t i=0; i<npadTot; i++) if (fPadIJ[1][i] == 0) npadOK++;
+ AddVirtualPad(); // add virtual pads if necessary
+ Int_t npadTot = fnPads[0] + fnPads[1], npadOK = 0;
+ for (Int_t i = 0; i < npadTot; i++) if (fPadIJ[1][i] == 0) npadOK++;
+ if (fDraw) fDraw->ResetMuon();
while (1) {
mlem = (TH2D*) gROOT->FindObject("mlem");
if (mlem) mlem->Delete();
// Calculate coefficients
- cout << " nPix, npadTot, npadOK " << nPix << " " << npadTot << " " << npadOK << endl;
+ if (fDebug) cout << " nPix, npadTot, npadOK " << nPix << " " << npadTot << " " << npadOK << endl;
// Calculate coefficients and pixel visibilities
coef = new Double_t [npadTot*nPix];
probi = new Double_t [nPix];
- Int_t indx = 0, cath;
- for (Int_t ipix=0; ipix<nPix; ipix++) {
- pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(ipix);
- probi[ipix] = 0;
- for (Int_t j=0; j<npadTot; j++) {
- if (fPadIJ[1][j] < 0) { coef[j*nPix+ipix] = 0; continue; }
+ for (Int_t ipix=0; ipix<nPix; ipix++) probi[ipix] = 0;
+ Int_t indx = 0, indx1 = 0, cath = 0;
+
+ for (Int_t j=0; j<npadTot; j++) {
+ indx = j*nPix;
+ if (fPadIJ[1][j] == 0) {
cath = fPadIJ[0][j];
- fSegmentation[cath]->GetPadI(fXyq[0][j],fXyq[1][j],fZpad,ix,iy);
- fSegmentation[cath]->SetPad(ix,iy);
+ ix = fPadIJ[2][j];
+ iy = fPadIJ[3][j];
+ fSegmentation[cath]->SetPad(ix, iy);
/*
- fSegmentation[cath]->Neighbours(ix,iy,&nn,xList,yList);
+ fSegmentation[cath]->Neighbours(fInput->DetElemId(),ix,iy,&nn,xList,yList);
if (nn != 4) {
cout << nn << ": ";
for (Int_t i=0; i<nn; i++) {cout << xList[i] << " " << yList[i] << ", ";}
cout << endl;
}
*/
- Double_t sum = 0;
- fSegmentation[cath]->SetHit(pixPtr->Coord(0),pixPtr->Coord(1),fZpad);
- sum += fResponse->IntXY(fSegmentation[cath]);
- indx = j*nPix + ipix;
- coef[indx] = sum;
- probi[ipix] += coef[indx];
- //cout << j << " " << ipix << " " << coef[indx] << endl;
- } // for (Int_t j=0;
- //cout << " prob: " << probi[ipix] << endl;
- if (probi[ipix] < 0.01) pixPtr->SetCharge(0); // "invisible" pixel
- } // for (Int_t ipix=0;
+ }
+
+ for (Int_t ipix=0; ipix<nPix; ipix++) {
+ indx1 = indx + ipix;
+ if (fPadIJ[1][j] < 0) { coef[indx1] = 0; continue; }
+ pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(ipix);
+ fSegmentation[cath]->SetHit(pixPtr->Coord(0), pixPtr->Coord(1), fZpad);
+ coef[indx1] = fInput->Mathieson()->IntXY(fInput->DetElemId(),fInput->Segmentation2(cath));
+ probi[ipix] += coef[indx1];
+ } // for (Int_t ipix=0;
+ } // for (Int_t j=0;
+ for (Int_t ipix=0; ipix<nPix; ipix++) if (probi[ipix] < 0.01) pixPtr->SetCharge(0); // "invisible" pixel
// MLEM algorithm
- Mlem(coef, probi);
+ Mlem(coef, probi, 15);
Double_t xylim[4] = {999, 999, 999, 999};
for (Int_t ipix=0; ipix<nPix; ipix++) {
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(ipix);
+ //cout << ipix+1; pixPtr->Print();
for (Int_t i=0; i<4; i++)
xylim[i] = TMath::Min (xylim[i], (i%2 ? -1 : 1)*pixPtr->Coord(i/2));
- //cout << ipix+1; pixPtr->Print();
}
for (Int_t i=0; i<4; i++) {
- xylim[i] -= pixPtr->Size(i/2); cout << (i%2 ? -1 : 1)*xylim[i] << " "; }
- cout << endl;
+ xylim[i] -= pixPtr->Size(i/2); if (fDebug) cout << (i%2 ? -1 : 1)*xylim[i] << " "; }
+ if (fDebug) cout << endl;
- // Ajust histogram to approximately the same limits as for the pads
+ // Adjust histogram to approximately the same limits as for the pads
// (for good presentation)
- //*
- Float_t xypads[4];
- if (fHist[0]) {
- xypads[0] = fHist[0]->GetXaxis()->GetXmin();
- xypads[1] = -fHist[0]->GetXaxis()->GetXmax();
- xypads[2] = fHist[0]->GetYaxis()->GetXmin();
- xypads[3] = -fHist[0]->GetYaxis()->GetXmax();
- for (Int_t i=0; i<4; i++) {
- while(1) {
- if (xylim[i] < xypads[i]) break;
- xylim[i] -= 2*pixPtr->Size(i/2);
- }
- }
- } // if (fHist[0])
- //*/
+ if (fDraw) fDraw->AdjustHist(xylim, pixPtr);
Int_t nx = TMath::Nint ((-xylim[1]-xylim[0])/pixPtr->Size(0)/2);
Int_t ny = TMath::Nint ((-xylim[3]-xylim[2])/pixPtr->Size(1)/2);
+
mlem = new TH2D("mlem","mlem",nx,xylim[0],-xylim[1],ny,xylim[2],-xylim[3]);
for (Int_t ipix=0; ipix<nPix; ipix++) {
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(ipix);
mlem->Fill(pixPtr->Coord(0),pixPtr->Coord(1),pixPtr->Charge());
}
- //gPad->GetCanvas()->cd(3);
- if (fDraw) {
- ((TCanvas*)gROOT->FindObject("c2"))->cd();
- gPad->SetTheta(55);
- gPad->SetPhi(30);
- mlem->Draw("lego1Fb");
- gPad->Update();
- gets((char*)&ix);
- }
+ if (fDraw) fDraw->DrawHist("c2", mlem);
// Check if the total charge of pixels is too low
Double_t qTot = 0;
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
qTot += pixPtr->Charge();
}
- if (qTot < 1.e-4 || npadOK < 3 && qTot < 50) {
+ if (qTot < 1.e-4 || npadOK < 3 && qTot < 7) {
delete [] coef; delete [] probi; coef = 0; probi = 0;
fPixArray->Delete();
+ for (Int_t i=0; i<npadTot; i++) if (fPadIJ[1][i] == 0) fPadIJ[1][i] = -1;
return kFALSE;
}
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
sum1 += pixPtr->Charge()*coef[j*nPix+i];
}
- sum1 = TMath::Min (sum1,(Double_t)fResponse->MaxAdc());
+ sum1 = TMath::Min (sum1,fgkSaturation);
x = fXyq[0][j];
y = fXyq[1][j];
cath = fPadIJ[0][j];
gPad->Modified();
*/
+ if (iSimple) {
+ // Simple cluster - skip further passes thru EM-procedure
+ Simple();
+ delete [] coef; delete [] probi; coef = 0; probi = 0;
+ fPixArray->Delete();
+ return kTRUE;
+ }
+
// Calculate position of the center-of-gravity around the maximum pixel
Double_t xyCOG[2];
FindCOG(mlem, xyCOG);
if (TMath::Min(pixPtr->Size(0),pixPtr->Size(1)) < 0.07 && pixPtr->Size(0) > pixPtr->Size(1)) break;
+ //if (TMath::Min(pixPtr->Size(0),pixPtr->Size(1)) < 0.007 && pixPtr->Size(0) > pixPtr->Size(1)) break;
//if (TMath::Min(pixPtr->Size(0),pixPtr->Size(1)) >= 0.07 || pixPtr->Size(0) < pixPtr->Size(1)) {
// Sort pixels according to the charge
fPixArray->Sort();
thresh = TMath::Min (thresh,50.);
Double_t cmax = -1, charge = 0;
for (Int_t i=0; i<nPix; i++) cmax = TMath::Max (cmax,probi[i]);
+ //cout << thresh << " " << cmax << " " << cmax*0.9 << endl;
// Mark pixels which should be removed
for (Int_t i=0; i<nPix; i++) {
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
charge = pixPtr->Charge();
if (charge < thresh) pixPtr->SetCharge(-charge);
- else if (cmax > 1.91) {
- if (probi[i] < 1.9) pixPtr->SetCharge(-charge);
- }
- else if (probi[i] < cmax*0.9) pixPtr->SetCharge(-charge);
+ //else if (cmax > 1.91) {
+ // if (probi[i] < 1.9) pixPtr->SetCharge(-charge);
+ //}
+ //AZ else if (probi[i] < cmax*0.9) pixPtr->SetCharge(-charge);
+ //18-01-06 else if (probi[i] < cmax*0.8) pixPtr->SetCharge(-charge);
+ //cout << i << " " << pixPtr->Coord(0) << " " << pixPtr->Coord(1) << " " << charge << " " << probi[i] << endl;
}
// Move charge of removed pixels to their nearest neighbour (to keep total charge the same)
Int_t near = 0;
if (charge > 0) continue;
near = FindNearest(pixPtr);
pixPtr->SetCharge(0);
+ probi[i] = 0; // make it "invisible"
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(near);
- pixPtr->SetCharge(pixPtr->Charge() - charge);
+ pixPtr->SetCharge(pixPtr->Charge() + (-charge));
}
+ Mlem(coef,probi,2);
// Update histogram
for (Int_t i=0; i<nPix; i++) {
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
iy = mlem->GetYaxis()->FindBin(pixPtr->Coord(1));
mlem->SetBinContent(ix, iy, pixPtr->Charge());
}
- if (fDraw) {
- ((TCanvas*)gROOT->FindObject("c2"))->cd();
- gPad->SetTheta(55);
- gPad->SetPhi(30);
- mlem->Draw("lego1Fb");
- gPad->Update();
- }
+ if (fDraw) fDraw->DrawHist("c2", mlem);
- fxyMu[0][6] = fxyMu[1][6] = 9999;
// Try to split into clusters
Bool_t ok = kTRUE;
if (mlem->GetSum() < 1) ok = kFALSE;
}
//_____________________________________________________________________________
-void AliMUONClusterFinderAZ::Mlem(Double_t *coef, Double_t *probi)
+void AliMUONClusterFinderAZ::Mlem(Double_t *coef, Double_t *probi, Int_t nIter)
{
// Use MLEM to find pixel charges
Int_t nPix = fPixArray->GetEntriesFast();
Int_t npad = fnPads[0] + fnPads[1];
Double_t *probi1 = new Double_t [nPix];
+ Double_t probMax = 0;
Int_t indx, indx1;
AliMUONPixel *pixPtr;
- for (Int_t iter=0; iter<15; iter++) {
+ for (Int_t ipix=0; ipix<nPix; ipix++) if (probi[ipix] > probMax) probMax = probi[ipix];
+ for (Int_t iter=0; iter<nIter; iter++) {
// Do iterations
for (Int_t ipix=0; ipix<nPix; ipix++) {
// Correct each pixel
if (probi[ipix] < 0.01) continue; // skip "invisible" pixel
Double_t sum = 0;
- probi1[ipix] = probi[ipix];
+ //probi1[ipix] = probi[ipix];
+ probi1[ipix] = probMax;
for (Int_t j=0; j<npad; j++) {
if (fPadIJ[1][j] < 0) continue;
Double_t sum1 = 0;
pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(i);
sum1 += pixPtr->Charge()*coef[indx1+i];
} // for (Int_t i=0;
- if (fXyq[2][j] > fResponse->MaxAdc()-1 && sum1 > fResponse->MaxAdc()) { probi1[ipix] -= coef[indx]; continue; } // correct for pad charge overflows
+ if (fXyq[2][j] > fgkSaturation-1 && sum1 > fXyq[2][j]) { probi1[ipix] -= coef[indx]; continue; } // correct for pad charge overflows
//cout << sum1 << " " << fXyq[2][j] << " " << coef[j*nPix+ipix] << endl;
if (coef[indx] > 1.e-6) sum += fXyq[2][j]*coef[indx]/sum1;
} // for (Int_t j=0;
} // if (nsumx == 1)
xyc[0] = xq/qq; xyc[1] = yq/qq;
- cout << xyc[0] << " " << xyc[1] << " " << qq << " " << nsum << " " << nsumx << " " << nsumy << endl;
+ if (fDebug) cout << xyc[0] << " " << xyc[1] << " " << qq << " " << nsum << " " << nsumx << " " << nsumy << endl;
return;
}
used[indx] = 1;
pix->Add(BinToPix(mlem,j,i));
AddBin(mlem, i, j, 0, used, pix); // recursive call
+ if (nclust >= 200) AliFatal(" Too many clusters !!!");
clusters[nclust++] = pix;
- if (nclust > 200) { cout << " Too many clusters " << endl; ::exit(0); }
} // for (Int_t j=1; j<=nx; j++) {
} // for (Int_t i=1; i<=ny;
- cout << nclust << endl;
+ if (fDebug) cout << nclust << endl;
delete [] used; used = 0;
// Compute couplings between clusters and clusters to pads
Int_t npad = fnPads[0] + fnPads[1];
+ // Write out some information for algorithm development
+ Int_t cath=0, npadx[2]={0}, npady[2]={0};
+ Double_t xlow[2]={9999,9999}, xhig[2]={-9999,-9999};
+ Double_t ylow[2]={9999,9999}, yhig[2]={-9999,-9999};
+ for (Int_t j=0; j<npad; j++) {
+ if (fXyq[3][j] < 0) continue; // exclude virtual pads
+ cath = fPadIJ[0][j];
+ if (fXyq[0][j] < xlow[cath]-0.001) {
+ if (fXyq[0][j]+fXyq[3][j] <= xlow[cath] && npadx[cath]) npadx[cath]++;
+ xlow[cath] = fXyq[0][j];
+ }
+ if (fXyq[0][j] > xhig[cath]+0.001) {
+ if (fXyq[0][j]-fXyq[3][j] >= xhig[cath]) npadx[cath]++;
+ xhig[cath] = fXyq[0][j];
+ }
+ if (fXyq[1][j] < ylow[cath]-0.001) {
+ if (fXyq[1][j]+fXyq[4][j] <= ylow[cath] && npady[cath]) npady[cath]++;
+ ylow[cath] = fXyq[1][j];
+ }
+ if (fXyq[1][j] > yhig[cath]+0.001) {
+ if (fXyq[1][j]-fXyq[4][j] >= yhig[cath]) npady[cath]++;
+ yhig[cath] = fXyq[1][j];
+ }
+ }
+ //if (lun1) fprintf(lun1," %4d %2d %3d %3d %3d %3d \n",gAlice->GetHeader()->GetEvent(),AliMUONClusterInput::Instance()->Chamber(), npadx[0], npadx[1], npady[0], npady[1]);
+
// Exclude pads with overflows
for (Int_t j=0; j<npad; j++) {
- if (fXyq[2][j] > fResponse->MaxAdc()-1) fPadIJ[1][j] = -9;
+ if (fXyq[2][j] > fgkSaturation-1) fPadIJ[1][j] = -5;
else fPadIJ[1][j] = 0;
}
for (Int_t i=0; i<npxclu; i++) {
indx = fPixArray->IndexOf(pix->UncheckedAt(i));
for (Int_t j=0; j<npad; j++) {
- // Exclude overflows
- if (fPadIJ[1][j] < 0) continue;
+ if (fPadIJ[1][j] < 0 && fPadIJ[1][j] != -5) continue;
if (coef[j*nPix+indx] < fgkCouplMin) continue;
(*aijclupad)(iclust,j) += coef[j*nPix+indx];
}
}
}
- if (nclust > 1) aijcluclu->Print();
+ if (fDebug && nclust > 1) aijcluclu->Print();
// Find groups of coupled clusters
used = new Bool_t[nclust];
nCoupled = 1;
// Find group of coupled clusters
AddCluster(igroup, nclust, aijcluclu, used, clustNumb, nCoupled); // recursive
- cout << " nCoupled: " << nCoupled << endl;
- for (Int_t i=0; i<nCoupled; i++) cout << clustNumb[i] << " "; cout << endl;
+ if (fDebug) {
+ cout << " nCoupled: " << nCoupled << endl;
+ for (Int_t i=0; i<nCoupled; i++) cout << clustNumb[i] << " "; cout << endl;
+ }
+ fnCoupled = nCoupled;
while (nCoupled > 0) {
// Flag clusters for fit
nForFit = 0;
while (minGroup[nForFit] >= 0 && nForFit < 3) {
- cout << clustNumb[minGroup[nForFit]] << " ";
+ if (fDebug) cout << clustNumb[minGroup[nForFit]] << " ";
clustFit[nForFit] = clustNumb[minGroup[nForFit]];
clustNumb[minGroup[nForFit]] -= 999;
nForFit++;
}
- cout << nForFit << " " << coupl << endl;
+ if (fDebug) cout << nForFit << " " << coupl << endl;
} // else
// Select pads for fit.
if (SelectPad(nCoupled, nForFit, clustNumb, clustFit, aijclupad) < 3 && nCoupled > 1) {
// Deselect pads
- for (Int_t j=0; j<npad; j++) if (TMath::Abs(fPadIJ[1][j]) == 1) fPadIJ[1][j] = 0;
+ for (Int_t j=0; j<npad; j++) {
+ if (TMath::Abs(fPadIJ[1][j]) == 1) fPadIJ[1][j] = 0;
+ if (TMath::Abs(fPadIJ[1][j]) == -9) fPadIJ[1][j] = -5;
+ }
// Merge the failed cluster candidates (with too few pads to fit) with
// the one with the strongest coupling
Merge(nForFit, nCoupled, clustNumb, clustFit, clusters, aijcluclu, aijclupad);
} else {
// Do the fit
- nfit = Fit(nForFit, clustFit, clusters, parOk);
+ nfit = Fit(0, nForFit, clustFit, clusters, parOk);
}
// Subtract the fitted charges from pads with strong coupling and/or
UpdatePads(nfit, parOk);
// Mark used pads
- for (Int_t j=0; j<npad; j++) {if (fPadIJ[1][j] == 1) fPadIJ[1][j] = -1;}
+ for (Int_t j=0; j<npad; j++) {
+ if (fPadIJ[1][j] == 1) fPadIJ[1][j] = -1;
+ if (fPadIJ[1][j] == -9) fPadIJ[1][j] = -5;
+ }
// Sort the clusters (move to the right the used ones)
Int_t beg = 0, end = nCoupled - 1;
(*aijcluclu)(indx1,indx) = (*aijcluclu)(indx,indx1);
}
}
- fPadIJ[1][j] = -9;
+ fPadIJ[1][j] = -8;
} // for (Int_t j=0; j<npad;
} // if (nCoupled > 3)
} // while (nCoupled > 0)
} // for (Int_t igroup=0; igroup<nclust;
- //delete aij_clu; aij_clu = 0; delete aijclupad; aijclupad = 0;
aijcluclu->Delete(); aijclupad->Delete();
for (Int_t iclust=0; iclust<nclust; iclust++) {
pix = clusters[iclust];
Double_t xc = mlem->GetXaxis()->GetBinCenter(jc);
Int_t nPix = fPixArray->GetEntriesFast();
- AliMUONPixel *pixPtr;
+ AliMUONPixel *pixPtr = NULL;
// Compare pixel and bin positions
for (Int_t i=0; i<nPix; i++) {
if (pixPtr->Charge() < 0.5) continue;
if (TMath::Abs(pixPtr->Coord(0)-xc)<1.e-4 && TMath::Abs(pixPtr->Coord(1)-yc)<1.e-4) return (TObject*) pixPtr;
}
- cout << " Something wrong ??? " << endl;
+ AliError(Form(" Something wrong ??? %f %f ", xc, yc));
return NULL;
}
for (Int_t iclust=0; iclust<nForFit; iclust++) {
indx = clustFit[iclust];
for (Int_t j=0; j<npad; j++) {
- if (fPadIJ[1][j] < 0) continue; // exclude overflows and used pads
if ((*aijclupad)(indx,j) < fgkCouplMin) continue;
- fPadIJ[1][j] = 1; // pad to be used in fit
- nOK++;
+ if (fPadIJ[1][j] == -5) fPadIJ[1][j] = -9; // flag overflow
+ if (fPadIJ[1][j] < 0) continue; // exclude overflows and used pads
+ if (!fPadIJ[1][j]) { fPadIJ[1][j] = 1; nOK++; } // pad to be used in fit
if (nCoupled > 3) {
// Check other clusters
for (Int_t iclust1=0; iclust1<nCoupled; iclust1++) {
Double_t aaa = 0;
for (Int_t j=0; j<npad; j++) {
if (padpix[j] < fgkCouplMin) continue;
- cout << j << " " << padpix[j] << " ";
- cout << fXyq[0][j] << " " << fXyq[1][j] << endl;
+ if (fDebug) cout << j << " " << padpix[j] << " " << fXyq[0][j] << " " << fXyq[1][j] << endl;
aaa += padpix[j];
fPadIJ[1][j] = -1; // exclude pads with strong coupling to the other clusters
nOK--;
npxclu1 = pix1->GetEntriesFast();
// Add pixels
for (Int_t i=0; i<npxclu; i++) { pix1->Add(pix->UncheckedAt(i)); pix->RemoveAt(i); }
- cout << " New number of pixels: " << npxclu1 << " " << pix1->GetEntriesFast() << endl;
+ if (fDebug) cout << " New number of pixels: " << npxclu1 << " " << pix1->GetEntriesFast() << endl;
//Add cluster-to-cluster couplings
//aijcluclu->Print();
for (Int_t icl1=0; icl1<nCoupled; icl1++) {
//aijcluclu->Print();
//Add cluster-to-pad couplings
for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
- if (fPadIJ[1][j] < 0) continue; // exclude overflows and used pads
+ if (fPadIJ[1][j] < 0 && fPadIJ[1][j] != -5) continue; // exclude used pads
(*aijclupad)(imax,j) += (*aijclupad)(indx,j);
(*aijclupad)(indx,j) = 0;
}
}
//_____________________________________________________________________________
-Int_t AliMUONClusterFinderAZ::Fit(Int_t nfit, Int_t *clustFit, TObjArray **clusters, Double_t *parOk)
+Int_t AliMUONClusterFinderAZ::Fit(Int_t iSimple, Int_t nfit, Int_t *clustFit, TObjArray **clusters, Double_t *parOk)
{
// Find selected clusters to selected pad charges
TH2D *mlem = (TH2D*) gROOT->FindObject("mlem");
- //Int_t nx = mlem->GetNbinsX();
- //Int_t ny = mlem->GetNbinsY();
Double_t xmin = mlem->GetXaxis()->GetXmin() - mlem->GetXaxis()->GetBinWidth(1);
Double_t xmax = mlem->GetXaxis()->GetXmax() + mlem->GetXaxis()->GetBinWidth(1);
Double_t ymin = mlem->GetYaxis()->GetXmin() - mlem->GetYaxis()->GetBinWidth(1);
Double_t ymax = mlem->GetYaxis()->GetXmax() + mlem->GetYaxis()->GetBinWidth(1);
- //Double_t qmin = 0, qmax = 1;
- Double_t step[3]={0.01,0.002,0.02};
-
- Double_t cont, cmax = 0, xseed = 0, yseed = 0, errOk[8];
- TObjArray *pix;
- Int_t npxclu;
+ Double_t step[3]={0.01,0.002,0.02}, xPad = 0, yPad = 99999;
- // Number of pads to use
- Int_t npads = 0;
- for (Int_t i=0; i<fnPads[0]+fnPads[1]; i++) {if (fPadIJ[1][i] == 1) npads++;}
- for (Int_t i=0; i<nfit; i++) {cout << i+1 << " " << clustFit[i] << " ";}
- cout << nfit << endl;
- cout << " Number of pads to fit: " << npads << endl;
+ // Number of pads to use and number of virtual pads
+ Int_t npads = 0, nVirtual = 0, nfit0 = nfit;
+ for (Int_t i=0; i<fnPads[0]+fnPads[1]; i++) {
+ if (fXyq[3][i] < 0) nVirtual++;
+ if (fPadIJ[1][i] != 1) continue;
+ if (fXyq[3][i] > 0) {
+ npads++;
+ if (yPad > 9999) {
+ xPad = fXyq[0][i];
+ yPad = fXyq[1][i];
+ } else {
+ if (fXyq[4][i] < fXyq[3][i]) yPad = fXyq[1][i];
+ else xPad = fXyq[0][i];
+ }
+ }
+ }
+ if (fDebug) {
+ for (Int_t i=0; i<nfit; i++) {cout << i+1 << " " << clustFit[i] << " ";}
+ cout << nfit << endl;
+ cout << " Number of pads to fit: " << npads << endl;
+ }
fNpar = 0;
fQtot = 0;
if (npads < 2) return 0;
+
+ Int_t digit = 0;
+ AliMUONDigit *mdig = 0;
+ Int_t tracks[3] = {-1, -1, -1};
+ for (Int_t cath=0; cath<2; cath++) {
+ for (Int_t i=0; i<fnPads[0]+fnPads[1]; i++) {
+ if (fPadIJ[0][i] != cath) continue;
+ if (fPadIJ[1][i] != 1) continue;
+ if (fXyq[3][i] < 0) continue; // exclude virtual pads
+ digit = TMath::Nint (fXyq[5][i]);
+ if (digit >= 0) mdig = fInput->Digit(cath,digit);
+ else mdig = fInput->Digit(TMath::Even(cath),-digit-1);
+ //if (!mdig) mdig = fInput->Digit(TMath::Even(cath),digit);
+ if (!mdig) continue; // protection for cluster display
+ if (mdig->Hit() >= 0) {
+ if (tracks[0] < 0) {
+ tracks[0] = mdig->Hit();
+ tracks[1] = mdig->Track(0);
+ } else if (mdig->Track(0) < tracks[1]) {
+ tracks[0] = mdig->Hit();
+ tracks[1] = mdig->Track(0);
+ }
+ }
+ if (mdig->Track(1) >= 0 && mdig->Track(1) != tracks[1]) {
+ if (tracks[2] < 0) tracks[2] = mdig->Track(1);
+ else tracks[2] = TMath::Min (tracks[2], mdig->Track(1));
+ }
+ //if (!mdig) break;
+ //cout << mdig->Hit() << " " << mdig->Track(0) << " " << mdig->Track(1) <<endl;
+ } // for (Int_t i=0;
+ } // for (Int_t cath=0;
+ //cout << tracks[0] << " " << tracks[1] << " " << tracks[2] <<endl;
+
+ // Get number of pads in X and Y
+ Int_t nInX = 0, nInY;
+ PadsInXandY(nInX, nInY);
+ //cout << " nInX and Y: " << nInX << " " << nInY << endl;
+
+ Int_t nfitMax = 3;
+ nfitMax = TMath::Min (nfitMax, (npads + 1) / 3);
+ if (nfitMax > 1) {
+ if (nInX < 3 && nInY < 3 || nInX == 3 && nInY < 3 || nInX < 3 && nInY == 3) nfitMax = 1; // not enough pads in each direction
+ }
+ if (nfit > nfitMax) nfit = nfitMax;
// Take cluster maxima as fitting seeds
+ TObjArray *pix;
AliMUONPixel *pixPtr;
- Double_t xyseed[3][2], qseed[3];
- for (Int_t ifit=1; ifit<=nfit; ifit++) {
+ Int_t npxclu;
+ Double_t cont, cmax = 0, xseed = 0, yseed = 0, errOk[8], qq = 0;
+ Double_t xyseed[3][2], qseed[3], xyCand[3][2] = {{0},{0}}, sigCand[3][2] = {{0},{0}};
+
+ for (Int_t ifit=1; ifit<=nfit0; ifit++) {
cmax = 0;
pix = clusters[clustFit[ifit-1]];
npxclu = pix->GetEntriesFast();
+ //qq = 0;
for (Int_t clu=0; clu<npxclu; clu++) {
pixPtr = (AliMUONPixel*) pix->UncheckedAt(clu);
cont = pixPtr->Charge();
xseed = pixPtr->Coord(0);
yseed = pixPtr->Coord(1);
}
+ qq += cont;
+ /*
+ xyCand[ifit-1][0] += pixPtr->Coord(0) * cont;
+ xyCand[ifit-1][1] += pixPtr->Coord(1) * cont;
+ sigCand[ifit-1][0] += pixPtr->Coord(0) * pixPtr->Coord(0) * cont;
+ sigCand[ifit-1][1] += pixPtr->Coord(1) * pixPtr->Coord(1) * cont;
+ */
+ xyCand[0][0] += pixPtr->Coord(0) * cont;
+ xyCand[0][1] += pixPtr->Coord(1) * cont;
+ sigCand[0][0] += pixPtr->Coord(0) * pixPtr->Coord(0) * cont;
+ sigCand[0][1] += pixPtr->Coord(1) * pixPtr->Coord(1) * cont;
}
xyseed[ifit-1][0] = xseed;
xyseed[ifit-1][1] = yseed;
qseed[ifit-1] = cmax;
+ /*
+ xyCand[ifit-1][0] /= qq; // <x>
+ xyCand[ifit-1][1] /= qq; // <y>
+ sigCand[ifit-1][0] = sigCand[ifit-1][0]/qq - xyCand[ifit-1][0]*xyCand[ifit-1][0]; // <x^2> - <x>^2
+ sigCand[ifit-1][0] = sigCand[ifit-1][0] > 0 ? TMath::Sqrt (sigCand[ifit-1][0]) : 0;
+ sigCand[ifit-1][1] = sigCand[ifit-1][1]/qq - xyCand[ifit-1][1]*xyCand[ifit-1][1]; // <y^2> - <y>^2
+ sigCand[ifit-1][1] = sigCand[ifit-1][1] > 0 ? TMath::Sqrt (sigCand[ifit-1][1]) : 0;
+ cout << xyCand[ifit-1][0] << " " << xyCand[ifit-1][1] << " " << sigCand[ifit-1][0] << " " << sigCand[ifit-1][1] << endl;
+ */
} // for (Int_t ifit=1;
- Int_t nDof, maxSeed[3];
+ xyCand[0][0] /= qq; // <x>
+ xyCand[0][1] /= qq; // <y>
+ sigCand[0][0] = sigCand[0][0]/qq - xyCand[0][0]*xyCand[0][0]; // <x^2> - <x>^2
+ sigCand[0][0] = sigCand[0][0] > 0 ? TMath::Sqrt (sigCand[0][0]) : 0;
+ sigCand[0][1] = sigCand[0][1]/qq - xyCand[0][1]*xyCand[0][1]; // <y^2> - <y>^2
+ sigCand[0][1] = sigCand[0][1] > 0 ? TMath::Sqrt (sigCand[0][1]) : 0;
+ if (fDebug) cout << xyCand[0][0] << " " << xyCand[0][1] << " " << sigCand[0][0] << " " << sigCand[0][1] << endl;
+
+ Int_t nDof, maxSeed[3], nMax = 0;
Double_t fmin, chi2o = 9999, chi2n;
- // Try to fit with one-track hypothesis, then 2-track. If chi2/dof is
- // lower, try 3-track (if number of pads is sufficient).
-
- TMath::Sort(nfit, qseed, maxSeed, kTRUE); // in decreasing order
- nfit = TMath::Min (nfit, (npads + 1) / 3);
+ TMath::Sort(nfit0, qseed, maxSeed, kTRUE); // in decreasing order
+ /*
+ Int_t itmp[100], localMax[100];
+ Double_t maxVal[100];
+ if (!iSimple && nfit < nfitMax) {
+ // Try to split pixel cluster according to local maxima
+ Int_t nfit1 = nfit;
+ for (Int_t iclus = 0; iclus < nfit1; iclus++) {
+ nMax = FindLocalMaxima (clusters[clustFit[maxSeed[iclus]]], localMax, maxVal);
+ TH2D *hist = (TH2D*) gROOT->FindObject("anode1");
+ if (nMax == 1) { hist->Delete(); continue; }
+ // Add extra fitting seeds from local maxima
+ Int_t ixseed = hist->GetXaxis()->FindBin(xyseed[maxSeed[iclus]][0]);
+ Int_t iyseed = hist->GetYaxis()->FindBin(xyseed[maxSeed[iclus]][1]);
+ Int_t nx = hist->GetNbinsX();
+ TMath::Sort(nMax, maxVal, itmp, kTRUE); // in decreasing order
+ for (Int_t j = 0; j < nMax; j++) {
+ Int_t iyc = localMax[itmp[j]] / nx + 1;
+ Int_t ixc = localMax[itmp[j]] % nx + 1;
+ if (ixc == ixseed && iyc == iyseed) continue; // local max already taken for seeding
+ xyseed[nfit][0] = hist->GetXaxis()->GetBinCenter(ixc);
+ xyseed[nfit][1] = hist->GetYaxis()->GetBinCenter(iyc);
+ qseed[nfit] = maxVal[itmp[j]];
+ maxSeed[nfit] = nfit++;
+ if (nfit >= nfitMax) break;
+ }
+ hist->Delete();
+ if (nfit >= nfitMax) break;
+ } // for (Int_t iclus = 0;
+ //nfit0 = nfit;
+ //TMath::Sort(nfit0, qseed, maxSeed, kTRUE); // in decreasing order
+ } //if (!iSimple && nfit < nfitMax)
+ */
- Double_t *gin = 0, func0, func1, param[8], param0[2][8], deriv[2][8], step0[8];
+ Double_t *gin = 0, func0, func1, param[8], step0[8];
+ Double_t param0[2][8]={{0},{0}}, deriv[2][8]={{0},{0}};
Double_t shift[8], stepMax, derMax, parmin[8], parmax[8], func2[2], shift0;
Double_t delta[8], scMax, dder[8], estim, shiftSave = 0;
Int_t min, max, nCall = 0, memory[8] = {0}, nLoop, idMax = 0, iestMax = 0, nFail;
+ Double_t rad, dist[3] = {0};
+ // Try to fit with one-track hypothesis, then 2-track. If chi2/dof is
+ // lower, try 3-track (if number of pads is sufficient).
for (Int_t iseed=0; iseed<nfit; iseed++) {
+ if (iseed) { for (Int_t j=0; j<fNpar; j++) param[j] = parOk[j]; } // for bounded params
for (Int_t j=0; j<3; j++) step0[fNpar+j] = shift[fNpar+j] = step[j];
- param[fNpar] = xyseed[maxSeed[iseed]][0];
+ if (nfit == 1) param[fNpar] = xyCand[0][0]; // take COG
+ else param[fNpar] = xyseed[maxSeed[iseed]][0];
parmin[fNpar] = xmin;
parmax[fNpar++] = xmax;
- param[fNpar] = xyseed[maxSeed[iseed]][1];
+ if (nfit == 1) param[fNpar] = xyCand[0][1]; // take COG
+ else param[fNpar] = xyseed[maxSeed[iseed]][1];
parmin[fNpar] = ymin;
parmax[fNpar++] = ymax;
if (fNpar > 2) {
parmin[fNpar] = 0;
parmax[fNpar++] = 1;
}
+ if (iseed) { for (Int_t j=0; j<fNpar; j++) param0[1][j] = 0; }
// Try new algorithm
min = nLoop = 1; stepMax = func2[1] = derMax = 999999; nFail = 0;
deriv[max][j] = (func1 - func0) / delta[j] * 10; // first derivative
//cout << j << " " << deriv[max][j] << endl;
dder[j] = param0[0][j] != param0[1][j] ? (deriv[0][j] - deriv[1][j]) /
- (param0[0][j] - param0[1][j]) : 0; // second derivative
+ (param0[0][j] - param0[1][j]) : 0; // second derivative
}
param[fNpar-1] -= delta[fNpar-1] / 10;
- if (nCall > 2000) ::exit(0);
+ if (nCall > 2000) break;
min = func2[0] < func2[1] ? 0 : 1;
nFail = min == max ? 0 : nFail + 1;
if (nLoop == 1) shift[j] = TMath::Sign (step0[j], -deriv[max][j]); // first step
else if (TMath::Abs(deriv[0][j]) < 1.e-3 && TMath::Abs(deriv[1][j]) < 1.e-3) shift[j] = 0;
else if (deriv[min][j]*deriv[!min][j] > 0 && TMath::Abs(deriv[min][j]) > TMath::Abs(deriv[!min][j])
- || TMath::Abs(deriv[0][j]-deriv[1][j]) < 1.e-3) {
+ //|| TMath::Abs(deriv[0][j]-deriv[1][j]) < 1.e-3) {
+ || TMath::Abs(deriv[0][j]-deriv[1][j]) < 1.e-3 || TMath::Abs(dder[j]) < 1.e-6) {
shift[j] = -TMath::Sign (shift[j], (func2[0]-func2[1]) * (param0[0][j]-param0[1][j]));
if (min == max) {
if (memory[j] > 1) { shift[j] *= 2; } //cout << " Memory " << memory[j] << " " << shift[j] << endl; }
memory[j]++;
}
} else {
- shift[j] = -deriv[min][j] / dder[j];
+ shift[j] = dder[j] != 0 ? -deriv[min][j] / dder[j] : 0;
memory[j] = 0;
}
if (TMath::Abs(shift[j])/step0[j] > estim) {
shift[j] = TMath::Sign (shift0*scMax, shift[j]);
}
param[j] += shift[j];
-
+ //AZ Check parameter limits 27-12-2004
+ if (param[j] < parmin[j]) {
+ shift[j] = parmin[j] - param[j];
+ param[j] = parmin[j];
+ } else if (param[j] > parmax[j]) {
+ shift[j] = parmax[j] - param[j];
+ param[j] = parmax[j];
+ }
//cout << " xxx " << j << " " << shift[j] << " " << param[j] << endl;
stepMax = TMath::Max (stepMax, TMath::Abs(shift[j]/step0[j]));
if (TMath::Abs(deriv[min][j]) > derMax) {
}
} // for (Int_t j=0; j<fNpar;
//cout << max << " " << func2[min] << " " << derMax << " " << stepMax << " " << estim << " " << iestMax << " " << nCall << endl;
- if (estim < 1 && derMax < 2 || nLoop > 100) break; // minimum was found
+ if (estim < 1 && derMax < 2 || nLoop > 150) break; // minimum was found
nLoop++;
// Check for small step
} // while (1)
fmin = func2[min];
- nDof = npads - fNpar;
- chi2n = nDof ? fmin/nDof : 0;
+ nDof = npads - fNpar + nVirtual;
+ if (!nDof) nDof++;
+ chi2n = fmin / nDof;
+ if (fDebug) cout << " Chi2 " << chi2n << " " << fNpar << endl;
if (chi2n*1.2+1.e-6 > chi2o ) { fNpar -= 3; break; }
+
// Save parameters and errors
+
+ if (nInX == 1) {
+ // One pad per direction
+ for (Int_t i=0; i<fNpar; i++) if (i == 0 || i == 2 || i == 5) param0[min][i] = xPad;
+ }
+ if (nInY == 1) {
+ // One pad per direction
+ for (Int_t i=0; i<fNpar; i++) if (i == 1 || i == 3 || i == 6) param0[min][i] = yPad;
+ }
+
+ /*
+ if (iseed > 0) {
+ // Find distance to the nearest neighbour
+ dist[0] = dist[1] = TMath::Sqrt ((param0[min][0]-param0[min][2])*
+ (param0[min][0]-param0[min][2])
+ +(param0[min][1]-param0[min][3])*
+ (param0[min][1]-param0[min][3]));
+ if (iseed > 1) {
+ dist[2] = TMath::Sqrt ((param0[min][0]-param0[min][5])*
+ (param0[min][0]-param0[min][5])
+ +(param0[min][1]-param0[min][6])*
+ (param0[min][1]-param0[min][6]));
+ rad = TMath::Sqrt ((param0[min][2]-param0[min][5])*
+ (param0[min][2]-param0[min][5])
+ +(param0[min][3]-param0[min][6])*
+ (param0[min][3]-param0[min][6]));
+ if (dist[2] < dist[0]) dist[0] = dist[2];
+ if (rad < dist[1]) dist[1] = rad;
+ if (rad < dist[2]) dist[2] = rad;
+ }
+ cout << dist[0] << " " << dist[1] << " " << dist[2] << endl;
+ if (dist[TMath::LocMin(iseed+1,dist)] < 1.) { fNpar -= 3; break; }
+ }
+ */
+
for (Int_t i=0; i<fNpar; i++) {
parOk[i] = param0[min][i];
- errOk[i] = fmin;
+ //errOk[i] = fmin;
+ errOk[i] = chi2n;
+ // Bounded params
+ parOk[i] = TMath::Max (parOk[i], parmin[i]);
+ parOk[i] = TMath::Min (parOk[i], parmax[i]);
}
- cout << chi2o << " " << chi2n << endl;
chi2o = chi2n;
if (fmin < 0.1) break; // !!!???
} // for (Int_t iseed=0;
- for (Int_t i=0; i<fNpar; i++) {
- if (i == 4 || i == 7) continue;
- cout << parOk[i] << " " << errOk[i] << endl;
+ if (fDebug) {
+ for (Int_t i=0; i<fNpar; i++) {
+ if (i == 4 || i == 7) {
+ if (i == 7 || i == 4 && fNpar < 7) cout << parOk[i] << endl;
+ else cout << parOk[i] * (1-parOk[7]) << endl;
+ continue;
+ }
+ cout << parOk[i] << " " << errOk[i] << endl;
+ }
}
nfit = (fNpar + 1) / 3;
- Double_t rad;
- Int_t indx, imax;
- if (fReco) {
- for (Int_t j=0; j<nfit; j++) {
- indx = j<2 ? j*2 : j*2+1;
- AddRawCluster (parOk[indx], parOk[indx+1], errOk[indx]);
+ dist[0] = dist[1] = dist[2] = 0;
+
+ if (nfit > 1) {
+ // Find distance to the nearest neighbour
+ dist[0] = dist[1] = TMath::Sqrt ((parOk[0]-parOk[2])*
+ (parOk[0]-parOk[2])
+ +(parOk[1]-parOk[3])*
+ (parOk[1]-parOk[3]));
+ if (nfit > 2) {
+ dist[2] = TMath::Sqrt ((parOk[0]-parOk[5])*
+ (parOk[0]-parOk[5])
+ +(parOk[1]-parOk[6])*
+ (parOk[1]-parOk[6]));
+ rad = TMath::Sqrt ((parOk[2]-parOk[5])*
+ (parOk[2]-parOk[5])
+ +(parOk[3]-parOk[6])*
+ (parOk[3]-parOk[6]));
+ if (dist[2] < dist[0]) dist[0] = dist[2];
+ if (rad < dist[1]) dist[1] = rad;
+ if (rad < dist[2]) dist[2] = rad;
}
- return nfit;
- }
- for (Int_t i=0; i<fnMu; i++) {
- cmax = fxyMu[i][6];
- for (Int_t j=0; j<nfit; j++) {
- indx = j<2 ? j*2 : j*2+1;
- rad = (fxyMu[i][0]-parOk[indx])*(fxyMu[i][0]-parOk[indx]) +
- (fxyMu[i][1]-parOk[indx+1])*(fxyMu[i][1]-parOk[indx+1]);
- if (rad < cmax) {
- cmax = rad;
- imax = indx;
- fxyMu[i][6] = cmax;
- fxyMu[i][2] = parOk[imax] - fxyMu[i][0];
- fxyMu[i][4] = parOk[imax+1] - fxyMu[i][1];
- fxyMu[i][3] = errOk[imax];
- fxyMu[i][5] = errOk[imax+1];
- }
- }
}
+
+ Int_t indx;
+ fnPads[1] -= nVirtual;
+ if (!fDraw) {
+ Double_t coef = 0;
+ if (iSimple) fnCoupled = 0;
+ //for (Int_t j=0; j<nfit; j++) {
+ for (Int_t j=nfit-1; j>=0; j--) {
+ indx = j<2 ? j*2 : j*2+1;
+ if (nfit == 1) coef = 1;
+ else coef = j==nfit-1 ? parOk[indx+2] : 1-coef;
+ coef = TMath::Max (coef, 0.);
+ if (nfit == 3 && j < 2) coef = j==1 ? coef*parOk[indx+2] : coef - parOk[7];
+ coef = TMath::Max (coef, 0.);
+ AddRawCluster (parOk[indx], parOk[indx+1], coef*fQtot, errOk[indx], nfit0+10*nfit+100*nMax+10000*fnCoupled, tracks,
+ //sigCand[maxSeed[j]][0], sigCand[maxSeed[j]][1]);
+ //sigCand[0][0], sigCand[0][1], dist[j]);
+ sigCand[0][0], sigCand[0][1], dist[TMath::LocMin(nfit,dist)]);
+ }
+ } else fDraw->FillMuon(nfit, parOk, errOk);
return nfit;
}
void AliMUONClusterFinderAZ::Fcn1(Int_t & /*npar*/, Double_t * /*gin*/, Double_t &f, Double_t *par, Int_t /*iflag*/)
{
// Fit for one track
- AliMUONClusterFinderAZ& c = *(AliMUONClusterFinderAZ::fgClusterFinder);
+ //AZ for Muinuit AliMUONClusterFinderAZ& c = *(AliMUONClusterFinderAZ::fgClusterFinder);
+ AliMUONClusterFinderAZ& c = *this; //AZ
Int_t cath, ix, iy, indx, npads=0;
- Double_t charge, delta, coef=0, chi2=0;
+ Double_t charge, delta, coef=0, chi2=0, qTot = 0;
for (Int_t j=0; j<c.fnPads[0]+c.fnPads[1]; j++) {
if (c.fPadIJ[1][j] != 1) continue;
cath = c.fPadIJ[0][j];
- npads++;
- c.fSegmentation[cath]->GetPadI(c.fXyq[0][j],c.fXyq[1][j],c.fZpad,ix,iy);
- c.fSegmentation[cath]->SetPad(ix,iy);
+ if (c.fXyq[3][j] > 0) npads++; // exclude virtual pads
+ qTot += c.fXyq[2][j];
+ ix = c.fPadIJ[2][j];
+ iy = c.fPadIJ[3][j];
+ c.fSegmentation[cath]->SetPad(ix, iy);
charge = 0;
for (Int_t i=c.fNpar/3; i>=0; i--) { // sum over tracks
indx = i<2 ? 2*i : 2*i+1;
- c.fSegmentation[cath]->SetHit(par[indx],par[indx+1],c.fZpad);
- //charge += c.fResponse->IntXY(c.fSegmentation[cath])*par[icl*3+2];
+ c.fSegmentation[cath]->SetHit(par[indx], par[indx+1], c.fZpad);
if (c.fNpar == 2) coef = 1;
else coef = i==c.fNpar/3 ? par[indx+2] : 1-coef;
- //coef = TMath::Max (coef, 0.);
+ coef = TMath::Max (coef, 0.);
if (c.fNpar == 8 && i < 2) coef = i==1 ? coef*par[indx+2] : coef - par[7];
- //coef = TMath::Max (coef, 0.);
- charge += c.fResponse->IntXY(c.fSegmentation[cath])*coef;
+ coef = TMath::Max (coef, 0.);
+ charge += c.fInput->Mathieson()->IntXY(fInput->DetElemId(), c.fInput->Segmentation2(cath))*coef;
}
charge *= c.fQtot;
- //if (c.fXyq[2][j] > c.fResponse->MaxAdc()-1 && charge >
- // c.fResponse->MaxAdc()) charge = c.fResponse->MaxAdc();
delta = charge - c.fXyq[2][j];
- delta /= TMath::Sqrt ((Double_t)c.fXyq[2][j]);
- //chi2 += TMath::Abs(delta);
- chi2 += delta*delta;
+ delta *= delta;
+ delta /= c.fXyq[2][j];
+ //if (cath) delta /= 5; // just for test
+ chi2 += delta;
} // for (Int_t j=0;
f = chi2;
- Double_t qAver = c.fQtot/npads; //(c.fnPads[0]+c.fnPads[1]);
+ Double_t qAver = qTot/npads; //(c.fnPads[0]+c.fnPads[1]);
f = chi2/qAver;
}
if (fPadIJ[1][j] != -1) continue;
if (fNpar != 0) {
cath = fPadIJ[0][j];
- fSegmentation[cath]->GetPadI(fXyq[0][j],fXyq[1][j],fZpad,ix,iy);
- fSegmentation[cath]->SetPad(ix,iy);
+ ix = fPadIJ[2][j];
+ iy = fPadIJ[3][j];
+ fSegmentation[cath]->SetPad(ix, iy);
charge = 0;
for (Int_t i=fNpar/3; i>=0; i--) { // sum over tracks
indx = i<2 ? 2*i : 2*i+1;
- fSegmentation[cath]->SetHit(par[indx],par[indx+1],fZpad);
+ fSegmentation[cath]->SetHit(par[indx], par[indx+1], fZpad);
if (fNpar == 2) coef = 1;
else coef = i==fNpar/3 ? par[indx+2] : 1-coef;
+ coef = TMath::Max (coef, 0.);
if (fNpar == 8 && i < 2) coef = i==1 ? coef*par[indx+2] : coef - par[7];
- charge += fResponse->IntXY(fSegmentation[cath])*coef;
+ coef = TMath::Max (coef, 0.);
+ charge += fInput->Mathieson()->IntXY(fInput->DetElemId(),fInput->Segmentation2(cath))*coef;
}
charge *= fQtot;
fXyq[2][j] -= charge;
} // if (fNpar != 0)
- if (fXyq[2][j] > fResponse->ZeroSuppression()) fPadIJ[1][j] = 0; // return pad for further using
+ if (fXyq[2][j] > fgkZeroSuppression) fPadIJ[1][j] = 0; // return pad for further using
} // for (Int_t j=0;
}
}
//_____________________________________________________________________________
-void AliMUONClusterFinderAZ::AddRawCluster(Double_t x, Double_t y, Double_t fmin)
+void AliMUONClusterFinderAZ::AddRawCluster(Double_t x, Double_t y, Double_t qTot, Double_t fmin, Int_t nfit, Int_t *tracks, Double_t /*sigx*/, Double_t /*sigy*/, Double_t /*dist*/)
{
//
// Add a raw cluster copy to the list
//
+ if (qTot <= 0.501) return;
AliMUONRawCluster cnew;
- AliMUON *pMUON=(AliMUON*)gAlice->GetModule("MUON");
- //pMUON->AddRawCluster(fInput->Chamber(),c);
- Int_t cath;
+ Int_t cath, npads[2] = {0}, nover[2] = {0};
+ for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
+ cath = fPadIJ[0][j];
+ // There was an overflow
+ if (fPadIJ[1][j] == -9) nover[cath]++;
+ if (fPadIJ[1][j] != 1 && fPadIJ[1][j] != -9) continue;
+ cnew.SetMultiplicity(cath,cnew.GetMultiplicity(cath)+1);
+ if (fXyq[2][j] > cnew.GetPeakSignal(cath)) cnew.SetPeakSignal(cath,TMath::Nint (fXyq[2][j]));
+ //cnew.SetCharge(cath,cnew.GetCharge(cath) + TMath::Nint (fXyq[2][j]));
+ cnew.SetContrib(npads[cath],cath,fXyq[2][j]);
+ cnew.SetIndex(npads[cath],cath,TMath::Nint (fXyq[5][j]));
+ cnew.SetDetElemId(fInput->DetElemId());
+ npads[cath]++;
+ }
+
+ cnew.SetClusterType(nover[0] + nover[1] * 100);
+ for (Int_t j=0; j<3; j++) cnew.SetTrack(j,tracks[j]);
+
+ Double_t xg, yg, zg;
for (cath=0; cath<2; cath++) {
- cnew.SetX(cath, x);
- cnew.SetY(cath, y);
- cnew.SetZ(cath, fZpad);
- cnew.SetCharge(cath, 100);
- cnew.SetPeakSignal(cath,20);
- cnew.SetMultiplicity(cath, 5);
- cnew.SetNcluster(cath, 1);
- cnew.SetChi2(cath, fmin); //0.1;
- /*
- cnew.fMultiplicity[cath]=c->fMultiplicity[cath];
- for (i=0; i<fMul[cath]; i++) {
- cnew.fIndexMap[i][cath]=c->fIndexMap[i][cath];
- fSeg[cath]->SetPad(fIx[i][cath], fIy[i][cath]);
- }
- fprintf(stderr,"\nRawCluster %d cath %d\n",ico,cath);
- fprintf(stderr,"mult_av %d\n",c->fMultiplicity[cath]);
- FillCluster(&cnew,cath);
- */
+ // Perform local-to-global transformation
+ fInput->Segmentation2(cath)->GetTransformer()->Local2Global(fInput->DetElemId(), x, y, fZpad, xg, yg, zg);
+ cnew.SetX(cath, xg);
+ cnew.SetY(cath, yg);
+ cnew.SetZ(cath, zg);
+ cnew.SetCharge(cath, TMath::Nint(qTot));
+ //cnew.SetPeakSignal(cath,20);
+ //cnew.SetMultiplicity(cath, 5);
+ cnew.SetNcluster(cath, nfit);
+ cnew.SetChi2(cath, fmin); //0.;1
}
+ // Evaluate measurement errors
+ //AZ Errors(&cnew);
+
+ cnew.SetGhost(nfit); //cnew.SetX(1,sigx); cnew.SetY(1,sigy); cnew.SetZ(1,dist);
//cnew.fClusterType=cnew.PhysicsContribution();
- pMUON->GetMUONData()->AddRawCluster(AliMUONClusterInput::Instance()->Chamber(),cnew);
+ new((*fRawClusters)[fNRawClusters++]) AliMUONRawCluster(cnew);
+ if (fDebug) cout << fNRawClusters << " " << fInput->Chamber() << endl;
//fNPeaks++;
}
//_____________________________________________________________________________
-Int_t AliMUONClusterFinderAZ::FindLocalMaxima(Int_t *localMax, Double_t *maxVal)
+Int_t AliMUONClusterFinderAZ::FindLocalMaxima(TObjArray *pixArray, Int_t *localMax, Double_t *maxVal)
{
// Find local maxima in pixel space for large preclusters in order to
// try to split them into smaller pieces (to speed up the MLEM procedure)
+ // or to find additional fitting seeds if clusters were not completely resolved
- TH2D *hist = (TH2D*) gROOT->FindObject("anode");
- if (hist) hist->Delete();
+ TH2D *hist = NULL;
+ //if (pixArray == fPixArray) hist = (TH2D*) gROOT->FindObject("anode");
+ //else { hist = (TH2D*) gROOT->FindObject("anode1"); cout << hist << endl; }
+ //if (hist) hist->Delete();
Double_t xylim[4] = {999, 999, 999, 999};
- Int_t nPix = fPixArray->GetEntriesFast();
+ Int_t nPix = pixArray->GetEntriesFast();
AliMUONPixel *pixPtr = 0;
for (Int_t ipix=0; ipix<nPix; ipix++) {
- pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(ipix);
+ pixPtr = (AliMUONPixel*) pixArray->UncheckedAt(ipix);
for (Int_t i=0; i<4; i++)
xylim[i] = TMath::Min (xylim[i], (i%2 ? -1 : 1)*pixPtr->Coord(i/2));
}
Int_t nx = TMath::Nint ((-xylim[1]-xylim[0])/pixPtr->Size(0)/2);
Int_t ny = TMath::Nint ((-xylim[3]-xylim[2])/pixPtr->Size(1)/2);
- hist = new TH2D("anode","anode",nx,xylim[0],-xylim[1],ny,xylim[2],-xylim[3]);
+ if (pixArray == fPixArray) hist = new TH2D("anode","anode",nx,xylim[0],-xylim[1],ny,xylim[2],-xylim[3]);
+ else hist = new TH2D("anode1","anode1",nx,xylim[0],-xylim[1],ny,xylim[2],-xylim[3]);
for (Int_t ipix=0; ipix<nPix; ipix++) {
- pixPtr = (AliMUONPixel*) fPixArray->UncheckedAt(ipix);
+ pixPtr = (AliMUONPixel*) pixArray->UncheckedAt(ipix);
hist->Fill(pixPtr->Coord(0), pixPtr->Coord(1), pixPtr->Charge());
}
- if (fDraw) {
- ((TCanvas*)gROOT->FindObject("c2"))->cd();
- gPad->SetTheta(55);
- gPad->SetPhi(30);
- hist->Draw("lego1Fb");
- gPad->Update();
- int ia;
- cin >> ia;
- }
+ if (fDraw && pixArray == fPixArray) fDraw->DrawHist("c2", hist);
Int_t nMax = 0, indx;
Int_t *isLocalMax = new Int_t[ny*nx];
if (isLocalMax[indx+j-1] > 0) {
localMax[nMax] = indx + j - 1;
maxVal[nMax++] = hist->GetCellContent(j,i);
+ if (nMax > 99) AliFatal(" Too many local maxima !!!");
}
- if (nMax > 99) { cout << " Too many local maxima !!!" << endl; ::exit(0); }
}
}
- cout << " Local max: " << nMax << endl;
+ if (fDebug) cout << " Local max: " << nMax << endl;
delete [] isLocalMax; isLocalMax = 0;
return nMax;
}
Int_t nx = hist->GetNbinsX();
Int_t ny = hist->GetNbinsY();
Int_t cont = TMath::Nint (hist->GetCellContent(j,i));
- Int_t cont1 = 0;
+ Int_t cont1 = 0, indx = (i-1)*nx+j-1, indx1 = 0, indx2 = 0;
for (Int_t i1=i-1; i1<i+2; i1++) {
if (i1 < 1 || i1 > ny) continue;
+ indx1 = (i1 - 1) * nx;
for (Int_t j1=j-1; j1<j+2; j1++) {
if (j1 < 1 || j1 > nx) continue;
if (i == i1 && j == j1) continue;
+ indx2 = indx1 + j1 - 1;
cont1 = TMath::Nint (hist->GetCellContent(j1,i1));
- if (cont < cont1) { isLocalMax[(i-1)*nx+j-1] = -1; return; }
- else if (cont > cont1) isLocalMax[(i1-1)*nx+j1-1] = -1;
+ if (cont < cont1) { isLocalMax[indx] = -1; return; }
+ else if (cont > cont1) isLocalMax[indx2] = -1;
else { // the same charge
- isLocalMax[(i-1)*nx+j-1] = 1;
- if (isLocalMax[(i1-1)*nx+j1-1] == 0) {
+ isLocalMax[indx] = 1;
+ if (isLocalMax[indx2] == 0) {
FlagLocalMax(hist, i1, j1, isLocalMax);
- if (isLocalMax[(i1-1)*nx+j1-1] < 0) { isLocalMax[(i-1)*nx+j-1] = -1; return; }
- else isLocalMax[(i1-1)*nx+j1-1] = -1;
+ if (isLocalMax[indx2] < 0) { isLocalMax[indx] = -1; return; }
+ else isLocalMax[indx2] = -1;
}
}
}
}
- isLocalMax[(i-1)*nx+j-1] = 1; // local maximum
+ isLocalMax[indx] = 1; // local maximum
}
//_____________________________________________________________________________
((AliMUONPixel*)fPixArray->UncheckedAt(i))->SetSize(0,wx);
((AliMUONPixel*)fPixArray->UncheckedAt(i))->SetSize(1,wy);
}
- cout << iMax << " " << nPix << endl;
+ if (fDebug) cout << iMax << " " << nPix << endl;
Float_t xy[4], xy12[4];
// Pick up pads which overlap with found pixels
return *this;
}
+//_____________________________________________________________________________
+void AliMUONClusterFinderAZ::AddVirtualPad()
+{
+ // Add virtual pad (with small charge) to improve fit for some
+ // clusters (when pad with max charge is at the extreme of the cluster)
+
+ // Get number of pads in X and Y-directions
+ Int_t nInX = -1, nInY;
+ PadsInXandY(nInX, nInY);
+ //return;
+
+ // Add virtual pad only if number of pads per direction == 2
+ if (nInX != 2 && nInY != 2) return;
+
+ // Find pads with max charge
+ Int_t maxpad[2][2] = {{-1, -1}, {-1, -1}}, cath;
+ Double_t sigmax[2] = {0}, aamax[2] = {0};
+ for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
+ if (fPadIJ[1][j] != 0) continue;
+ cath = fPadIJ[0][j];
+ if (fXyq[2][j] > sigmax[cath]) {
+ maxpad[cath][1] = maxpad[cath][0];
+ aamax[cath] = sigmax[cath];
+ sigmax[cath] = fXyq[2][j];
+ maxpad[cath][0] = j;
+ }
+ }
+ if (maxpad[0][0] >= 0 && maxpad[0][1] < 0 || maxpad[1][0] >= 0 && maxpad[1][1] < 0) {
+ for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
+ if (fPadIJ[1][j] != 0) continue;
+ cath = fPadIJ[0][j];
+ if (j == maxpad[cath][0] || j == maxpad[cath][1]) continue;
+ if (fXyq[2][j] > aamax[cath]) {
+ aamax[cath] = fXyq[2][j];
+ maxpad[cath][1] = j;
+ }
+ }
+ }
+ // Check for mirrors (side X on cathode 0)
+ Bool_t mirror = kFALSE;
+ if (maxpad[0][0] >= 0 && maxpad[1][0] >= 0) {
+ mirror = fXyq[3][maxpad[0][0]] < fXyq[4][maxpad[0][0]];
+ if (!mirror && TMath::Abs(fXyq[3][maxpad[0][0]]-fXyq[3][maxpad[1][0]]) < 0.001) {
+ // Special case when pads on both cathodes have the same size
+ Int_t yud[2] = {0};
+ for (Int_t j = 0; j < fnPads[0]+fnPads[1]; j++) {
+ cath = fPadIJ[0][j];
+ if (j == maxpad[cath][0]) continue;
+ if (fPadIJ[2][j] != fPadIJ[2][maxpad[cath][0]]) continue;
+ if (fPadIJ[3][j] + 1 == fPadIJ[3][maxpad[cath][0]] ||
+ fPadIJ[3][j] - 1 == fPadIJ[3][maxpad[cath][0]]) yud[cath]++;
+ }
+ if (!yud[0]) mirror = kTRUE; // take the other cathode
+ } // if (!mirror &&...
+ } // if (maxpad[0][0] >= 0 && maxpad[1][0] >= 0)
+
+ // Find neughbours of pads with max charges
+ Int_t nn, xList[10], yList[10], ix0, iy0, ix, iy, neighb;
+ for (cath=0; cath<2; cath++) {
+ if (!cath && maxpad[0][0] < 0) continue; // one-sided cluster - cathode 1
+ if (cath && maxpad[1][0] < 0) break; // one-sided cluster - cathode 0
+ if (maxpad[1][0] >= 0) {
+ if (!mirror) {
+ if (!cath && nInY != 2) continue;
+ if (cath && nInX != 2 && (maxpad[0][0] >= 0 || nInY != 2)) continue;
+ } else {
+ if (!cath && nInX != 2) continue;
+ if (cath && nInY != 2 && (maxpad[0][0] >= 0 || nInX != 2)) continue;
+ }
+ }
+
+ Int_t iAddX = 0, iAddY = 0, ix1 = 0, iy1 = 0, iPad = 0;
+ if (maxpad[0][0] < 0) iPad = 1;
+
+ for (iPad=0; iPad<2; iPad++) {
+ if (maxpad[cath][iPad] < 0) continue;
+ if (iPad && !iAddX && !iAddY) break;
+ if (iPad && fXyq[2][maxpad[cath][1]] / sigmax[cath] < 0.5) break;
+
+ Int_t neighbx = 0, neighby = 0;
+ ix0 = fPadIJ[2][maxpad[cath][iPad]];
+ iy0 = fPadIJ[3][maxpad[cath][iPad]];
+ fSegmentation[cath]->Neighbours(ix0, iy0, &nn, xList, yList);
+ Float_t zpad;
+ for (Int_t j=0; j<nn; j++) {
+ if (TMath::Abs(xList[j]-ix0) == 1 || xList[j]*ix0 == -1) neighbx++;
+ if (TMath::Abs(yList[j]-iy0) == 1 || yList[j]*iy0 == -1) neighby++;
+ }
+ if (!mirror) {
+ if (cath) neighb = neighbx;
+ else neighb = neighby;
+ if (maxpad[0][0] < 0) neighb += neighby;
+ else if (maxpad[1][0] < 0) neighb += neighbx;
+ } else {
+ if (!cath) neighb = neighbx;
+ else neighb = neighby;
+ if (maxpad[0][0] < 0) neighb += neighbx;
+ else if (maxpad[1][0] < 0) neighb += neighby;
+ }
+
+ for (Int_t j=0; j<fnPads[0]+fnPads[1]; j++) {
+ if (fPadIJ[0][j] != cath) continue;
+ ix = fPadIJ[2][j];
+ iy = fPadIJ[3][j];
+ if (iy == iy0 && ix == ix0) continue;
+ for (Int_t k=0; k<nn; k++) {
+ if (xList[k] != ix || yList[k] != iy) continue;
+ if (!mirror) {
+ if ((!cath || maxpad[0][0] < 0) &&
+ (TMath::Abs(iy-iy0) == 1 || iy*iy0 == -1)) {
+ if (!iPad && TMath::Abs(ix-ix0) == 1 || ix*ix0 == -1) ix1 = xList[k]; //19-12-05
+ xList[k] = yList[k] = 0;
+ neighb--;
+ break;
+ }
+ if ((cath || maxpad[1][0] < 0) &&
+ (TMath::Abs(ix-ix0) == 1 || ix*ix0 == -1)) {
+ if (!iPad) ix1 = xList[k]; //19-12-05
+ xList[k] = yList[k] = 0;
+ neighb--;
+ }
+ } else {
+ if ((!cath || maxpad[0][0] < 0) &&
+ (TMath::Abs(ix-ix0) == 1 || ix*ix0 == -1)) {
+ if (!iPad) ix1 = xList[k]; //19-12-05
+ xList[k] = yList[k] = 0;
+ neighb--;
+ break;
+ }
+ if ((cath || maxpad[1][0] < 0) &&
+ (TMath::Abs(iy-iy0) == 1 || iy*iy0 == -1)) {
+ xList[k] = yList[k] = 0;
+ neighb--;
+ }
+ }
+ break;
+ } // for (Int_t k=0; k<nn;
+ if (!neighb) break;
+ } // for (Int_t j=0; j<fnPads[0]+fnPads[1];
+ if (!neighb) continue;
+
+ // Add virtual pad
+ Int_t npads, isec;
+ isec = 0;
+ for (Int_t j=0; j<nn; j++) {
+ if (xList[j] == 0 && yList[j] == 0) continue;
+ npads = fnPads[0] + fnPads[1];
+ fPadIJ[0][npads] = cath;
+ fPadIJ[1][npads] = 0;
+ ix = xList[j];
+ iy = yList[j];
+ if (TMath::Abs(ix-ix0) == 1 || ix*ix0 == -1) {
+ if (iy != iy0) continue; // new segmentation - check
+ if (nInX != 2) continue; // new
+ if (!mirror) {
+ if (!cath && maxpad[1][0] >= 0) continue;
+ } else {
+ if (cath && maxpad[0][0] >= 0) continue;
+ }
+ if (iPad && !iAddX) continue;
+ fSegmentation[cath]->GetPadC(ix, iy, fXyq[0][npads], fXyq[1][npads], zpad);
+ if (fXyq[0][npads] > 1.e+5) continue; // temporary fix
+ if (ix == ix1) continue; //19-12-05
+ if (ix1 == ix0) continue;
+ if (maxpad[1][0] < 0 || mirror && maxpad[0][0] >= 0) {
+ if (!iPad) fXyq[2][npads] = TMath::Min (sigmax[0]/100, 5.);
+ else fXyq[2][npads] = TMath::Min (aamax[0]/100, 5.);
+ }
+ else {
+ if (!iPad) fXyq[2][npads] = TMath::Min (sigmax[1]/100, 5.);
+ else fXyq[2][npads] = TMath::Min (aamax[1]/100, 5.);
+ }
+ fXyq[2][npads] = TMath::Max (fXyq[2][npads], (float)1);
+ fXyq[3][npads] = -2; // flag
+ fPadIJ[2][npads] = ix;
+ fPadIJ[3][npads] = iy;
+ fnPads[1]++;
+ iAddX = npads;
+ if (fDebug) printf(" ***** Add virtual pad in X ***** %f %f %f %3d %3d \n", fXyq[2][npads],
+ fXyq[0][npads], fXyq[1][npads], ix, iy);
+ ix1 = ix0;
+ continue;
+ }
+ if (nInY != 2) continue;
+ if (!mirror && cath && maxpad[0][0] >= 0) continue;
+ if (mirror && !cath && maxpad[1][0] >= 0) continue;
+ if (TMath::Abs(iy-iy0) == 1 || TMath::Abs(iy*iy0) == 1) {
+ if (ix != ix0) continue; // new segmentation - check
+ if (iPad && !iAddY) continue;
+ fSegmentation[cath]->GetPadC(ix, iy, fXyq[0][npads], fXyq[1][npads], zpad);
+ if (iy1 == iy0) continue;
+ //if (iPad && iy1 == iy0) continue;
+ if (maxpad[0][0] < 0 || mirror && maxpad[1][0] >= 0) {
+ if (!iPad) fXyq[2][npads] = TMath::Min (sigmax[1]/15, fgkZeroSuppression);
+ else fXyq[2][npads] = TMath::Min (aamax[1]/15, fgkZeroSuppression);
+ }
+ else {
+ if (!iPad) fXyq[2][npads] = TMath::Min (sigmax[0]/15, fgkZeroSuppression);
+ else fXyq[2][npads] = TMath::Min (aamax[0]/15, fgkZeroSuppression);
+ }
+ fXyq[2][npads] = TMath::Max (fXyq[2][npads], (float)1);
+ fXyq[3][npads] = -2; // flag
+ fPadIJ[2][npads] = ix;
+ fPadIJ[3][npads] = iy;
+ fnPads[1]++;
+ iAddY = npads;
+ if (fDebug) printf(" ***** Add virtual pad in Y ***** %f %f %f %3d %3d \n", fXyq[2][npads],
+ fXyq[0][npads], fXyq[1][npads], ix, iy);
+ iy1 = iy0;
+ }
+ } // for (Int_t j=0; j<nn;
+ } // for (Int_t iPad=0;
+ } // for (cath=0; cath<2;
+ return;
+}
+
+//_____________________________________________________________________________
+void AliMUONClusterFinderAZ::PadsInXandY(Int_t &nInX, Int_t &nInY)
+{
+ // Find number of pads in X and Y-directions (excluding virtual ones and
+ // overflows)
+
+ static Int_t nXsaved = 0, nYsaved = 0;
+ nXsaved = nYsaved = 0;
+ //if (nInX >= 0) {nInX = nXsaved; nInY = nYsaved; return; }
+ Float_t *xPad0 = NULL, *yPad0 = NULL, *xPad1 = NULL, *yPad1 = NULL;
+ Float_t wMinX[2] = {99, 99}, wMinY[2] = {99, 99};
+ Int_t *nPad0 = NULL, *nPad1 = NULL;
+ Int_t nPads = fnPads[0] + fnPads[1];
+ if (fnPads[0]) {
+ xPad0 = new Float_t[nPads];
+ yPad0 = new Float_t[nPads];
+ nPad0 = new Int_t[nPads];
+ }
+ if (fnPads[1]) {
+ xPad1 = new Float_t[nPads];
+ yPad1 = new Float_t[nPads];
+ nPad1 = new Int_t[nPads];
+ }
+ Int_t n0 = 0, n1 = 0, cath, npadx[2] = {1, 1}, npady[2] = {1, 1};
+ for (Int_t j = 0; j < nPads; j++) {
+ if (nInX < 0 && fPadIJ[1][j] != 0) continue; // before fit
+ else if (nInX == 0 && fPadIJ[1][j] != 1) continue; // fit - exclude overflows
+ else if (nInX > 0 && fPadIJ[1][j] != 1 && fPadIJ[1][j] != -9) continue; // exclude non-marked
+ if (nInX <= 0 && fXyq[2][j] > fgkSaturation-1) continue; // skip overflows
+ cath = fPadIJ[0][j];
+ if (fXyq[3][j] > 0) { // exclude virtual pads
+ wMinX[cath] = TMath::Min (wMinX[cath], fXyq[3][j]);
+ wMinY[cath] = TMath::Min (wMinY[cath], fXyq[4][j]);
+ //20-12-05 }
+ if (cath) { xPad1[n1] = fXyq[0][j]; yPad1[n1++] = fXyq[1][j]; }
+ else { xPad0[n0] = fXyq[0][j]; yPad0[n0++] = fXyq[1][j]; }
+ }
+ }
+
+ // Sort
+ if (n0) {
+ TMath::Sort (n0, xPad0, nPad0); // in X
+ for (Int_t i = 1; i < n0; i++)
+ if (xPad0[nPad0[i]] - xPad0[nPad0[i-1]] < -0.01) npadx[0]++;
+ TMath::Sort (n0, yPad0, nPad0); // in Y
+ for (Int_t i = 1; i < n0; i++)
+ if (yPad0[nPad0[i]] - yPad0[nPad0[i-1]] < -0.01) npady[0]++;
+ }
+
+ if (n1) {
+ TMath::Sort (n1, xPad1, nPad1); // in X
+ for (Int_t i = 1; i < n1; i++)
+ if (xPad1[nPad1[i]] - xPad1[nPad1[i-1]] < -0.01) npadx[1]++;
+ TMath::Sort (n1, yPad1, nPad1); // in Y
+ for (Int_t i = 1; i < n1; i++)
+ if (yPad1[nPad1[i]] - yPad1[nPad1[i-1]] < -0.01) npady[1]++;
+ }
+ if (fnPads[0]) { delete [] xPad0; delete [] yPad0; delete [] nPad0; }
+ if (fnPads[1]) { delete [] xPad1; delete [] yPad1; delete [] nPad1; }
+ if (TMath::Abs (wMinY[0] - wMinY[1]) < 1.e-3) nInY = TMath::Max (npady[0], npady[1]);
+ else nInY = wMinY[0] < wMinY[1] ? npady[0] : npady[1];
+ if (TMath::Abs (wMinX[0] - wMinX[1]) < 1.e-3) nInX = TMath::Max (npadx[0], npadx[1]);
+ else nInX = wMinX[0] < wMinX[1] ? npadx[0] : npadx[1];
+}
+
+//_____________________________________________________________________________
+void AliMUONClusterFinderAZ::Simple()
+{
+ // Process simple cluster (small number of pads) without EM-procedure
+
+ Int_t nForFit = 1, clustFit[1] = {0}, nfit;
+ Double_t parOk[3] = {0.};
+ TObjArray *clusters[1];
+ clusters[0] = fPixArray;
+ for (Int_t i = 0; i < fnPads[0]+fnPads[1]; i++) {
+ if (fXyq[2][i] > fgkSaturation-1) fPadIJ[1][i] = -9;
+ else fPadIJ[1][i] = 1;
+ }
+ nfit = Fit(1, nForFit, clustFit, clusters, parOk);
+}
+
+//_____________________________________________________________________________
+void AliMUONClusterFinderAZ::Errors(AliMUONRawCluster *clus)
+{
+ // Correct reconstructed coordinates for some clusters and evaluate errors
+
+ Double_t qTot = clus->GetCharge(0), fmin = clus->GetChi2(0);
+ Double_t xreco = clus->GetX(0), yreco = clus->GetY(0), zreco = clus->GetZ(0);
+ Double_t sigmax[2] = {0};
+
+ Int_t nInX = 1, nInY, maxdig[2] ={-1, -1}, digit, cath1, isec;
+ PadsInXandY(nInX, nInY);
+
+ // Find pad with maximum signal
+ for (Int_t cath = 0; cath < 2; cath++) {
+ for (Int_t j = 0; j < clus->GetMultiplicity(cath); j++) {
+ cath1 = cath;
+ digit = clus->GetIndex(j, cath);
+ if (digit < 0) { cath1 = TMath::Even(cath); digit = -digit - 1; } // from the other cathode
+
+ if (clus->GetContrib(j,cath) > sigmax[cath1]) {
+ sigmax[cath1] = clus->GetContrib(j,cath);
+ maxdig[cath1] = digit;
+ }
+ }
+ }
+
+ // Size of pad with maximum signal and reco coordinate distance from the pad center
+ AliMUONDigit *mdig = 0;
+ Double_t wx[2], wy[2], dxc[2], dyc[2];
+ Float_t xpad, ypad, zpad;
+ Int_t ix, iy;
+ for (Int_t cath = 0; cath < 2; cath++) {
+ if (maxdig[cath] < 0) continue;
+ mdig = fInput->Digit(cath,maxdig[cath]);
+ isec = fSegmentation[cath]->Sector(mdig->PadX(), mdig->PadY());
+ wx[cath] = fSegmentation[cath]->Dpx(isec);
+ wy[cath] = fSegmentation[cath]->Dpy(isec);
+ fSegmentation[cath]->GetPadI(xreco, yreco, zreco, ix, iy);
+ isec = fSegmentation[cath]->Sector(ix, iy);
+ if (isec > 0) {
+ fSegmentation[cath]->GetPadC(ix, iy, xpad, ypad, zpad);
+ dxc[cath] = xreco - xpad;
+ dyc[cath] = yreco - ypad;
+ }
+ }
+
+ // Check if pad with max charge at the edge (number of neughbours)
+ Int_t nn, xList[10], yList[10], neighbx[2][2] = {{0,0}, {0,0}}, neighby[2][2]= {{0,0}, {0,0}};
+ for (Int_t cath = 0; cath < 2; cath++) {
+ if (maxdig[cath] < 0) continue;
+ mdig = fInput->Digit(cath,maxdig[cath]);
+ fSegmentation[cath]->Neighbours(mdig->PadX(), mdig->PadY(), &nn, xList, yList);
+ isec = fSegmentation[cath]->Sector(mdig->PadX(), mdig->PadY());
+ /*??
+ Float_t sprX = fResponse->SigmaIntegration() * fResponse->ChargeSpreadX();
+ Float_t sprY = fResponse->SigmaIntegration() * fResponse->ChargeSpreadY();
+ //fSegmentation[cath]->FirstPad(fInput->DetElemId(),muons[ihit][1], muons[ihit][2], muons[ihit][3], sprX, sprY);
+ //fSegmentation[cath]->FirstPad(fInput->DetElemId(),xreco, yreco, zreco, sprX, sprY);
+ fSegmentation[cath]->FirstPad(xreco, yreco, zreco, sprX, sprY);
+ Int_t border = 0;
+ //if (fSegmentation[cath]->Sector(fInput->DetElemId(),fSegmentation[cath]->Ix(),fSegmentation[cath]->Iy()) <= 0) {
+ if (fSegmentation[cath]->Sector(fSegmentation[cath]->Ix(), fSegmentation[cath]->Iy()) <= 0) {
+ //fSegmentation[cath]->NextPad(fInput->DetElemId());
+ fSegmentation[cath]->NextPad();
+ border = 1;
+ }
+ */
+ for (Int_t j=0; j<nn; j++) {
+ //if (border && yList[j] < fSegmentation[cath]->Iy()) continue;
+ fSegmentation[cath]->GetPadC(xList[j], yList[j], xpad, ypad, zpad);
+ //cout << ch << " " << xList[j] << " " << yList[j] << " " << border << " " << x << " " << y << " " << xpad << " " << ypad << endl;
+ if (TMath::Abs(xpad) < 1 && TMath::Abs(ypad) < 1) continue;
+ if (xList[j] == mdig->PadX()-1 || mdig->PadX() == 1 &&
+ xList[j] == -1) neighbx[cath][0] = 1;
+ else if (xList[j] == mdig->PadX()+1 || mdig->PadX() == -1 &&
+ xList[j] == 1) neighbx[cath][1] = 1;
+ if (yList[j] == mdig->PadY()-1 || mdig->PadY() == 1 &&
+ yList[j] == -1) neighby[cath][0] = 1;
+ else if (yList[j] == mdig->PadY()+1 || mdig->PadY() == -1 &&
+ yList[j] == 1) neighby[cath][1] = 1;
+ } // for (Int_t j=0; j<nn;
+ if (neighbx[cath][0] && neighbx[cath][1]) neighbx[cath][0] = 0;
+ else if (neighbx[cath][1]) neighbx[cath][0] = -1;
+ else neighbx[cath][0] = 1;
+ if (neighby[cath][0] && neighby[cath][1]) neighby[cath][0] = 0;
+ else if (neighby[cath][1]) neighby[cath][0] = -1;
+ else neighby[cath][0] = 1;
+ }
+
+ Int_t iOver = clus->GetClusterType();
+ // One-sided cluster
+ if (!clus->GetMultiplicity(0)) {
+ neighby[0][0] = neighby[1][0];
+ wy[0] = wy[1];
+ if (iOver < 99) iOver += 100 * iOver;
+ dyc[0] = dyc[1];
+ } else if (!clus->GetMultiplicity(1)) {
+ neighbx[1][0] = neighbx[0][0];
+ wx[1] = wx[0];
+ if (iOver < 99) iOver += 100 * iOver;
+ dxc[1] = dxc[0];
+ }
+
+ // Apply corrections and evaluate errors
+ Double_t errY, errX;
+ Errors(nInY, nInX, neighby[0][0],neighbx[1][0], fmin, wy[0]*10, wx[1]*10, iOver,
+ dyc[0], dxc[1], qTot, yreco, xreco, errY, errX);
+ errY = TMath::Max (errY, 0.01);
+ //errY = 0.01;
+ //errX = TMath::Max (errX, 0.144);
+ clus->SetX(0, xreco); clus->SetY(0, yreco);
+ clus->SetErrX(errX); clus->SetErrY(errY);
+}
+
+//_____________________________________________________________________________
+void AliMUONClusterFinderAZ::Errors(Int_t ny, Int_t nx, Int_t iby, Int_t ibx, Double_t fmin,
+ Double_t wy, Double_t wx, Int_t iover,
+ Double_t dyc, Double_t /*dxc*/, Double_t qtot,
+ Double_t &yrec, Double_t &xrec, Double_t &erry, Double_t &errx)
+{
+ // Correct reconstructed coordinates for some clusters and evaluate errors
+
+ erry = 0.01;
+ errx = 0.144;
+ Int_t iovery = iover % 100;
+ Double_t corr = 0;
+
+/* ---> Ny = 1 */
+ if (ny == 1) {
+ if (iby != 0) {
+ // edge effect
+ yrec += iby * (0.1823+0.2008)/2;
+ erry = 0.04587;
+ } else {
+ // Find "effective pad width"
+ Double_t width = 0.218 / (1.31e-4 * TMath::Exp (2.688 * TMath::Log(qtot)) + 1) * 2;
+ width = TMath::Min (width, 0.4);
+ erry = width / TMath::Sqrt(12.);
+ erry = TMath::Max (erry, 0.01293);
+ }
+ goto x; //return;
+ }
+
+/* ---> "Bad" fit */
+ if (fmin > 0.4) {
+ erry = 0.1556;
+ if (ny == 5) erry = 0.06481;
+ goto x; //return;
+ }
+
+/* ---> By != 0 */
+ if (iby != 0) {
+ if (ny > 2) {
+ erry = 0.00417; //0.01010
+ } else {
+ // ny = 2
+ if (dyc * iby > -0.05) {
+ Double_t dyc2 = dyc * dyc;
+ if (iby < 0) {
+ corr = 0.019 - 0.602 * dyc + 8.739 * dyc2 - 44.209 * dyc2 * dyc;
+ corr = TMath::Min (corr, TMath::Abs(-0.25-dyc));
+ yrec -= corr;
+ //dyc -= corr;
+ erry = 0.00814;
+ } else {
+ corr = 0.006 + 0.300 * dyc + 6.147 * dyc2 + 42.039 * dyc2 * dyc;
+ corr = TMath::Min (corr, 0.25-dyc);
+ yrec += corr;
+ //dyc += corr;
+ erry = 0.01582;
+ }
+ } else {
+ erry = (0.00303 + 0.00296) / 2;
+ }
+ }
+ goto x; //return;
+ }
+
+/* ---> Overflows */
+ if (iovery != 0) {
+ if (qtot < 3000) {
+ erry = 0.0671;
+ } else {
+ if (iovery > 1) {
+ erry = 0.09214;
+ } else if (TMath::Abs(wy - 5) < 0.1) {
+ erry = 0.061; //0.06622
+ } else {
+ erry = 0.00812; // 0.01073
+ }
+ }
+ goto x; //return;
+ }
+
+/* ---> "Good" but very high signal */
+ if (qtot > 4000) {
+ if (TMath::Abs(wy - 4) < 0.1) {
+ erry = 0.00117;
+ } else if (fmin < 0.03 && qtot < 6000) {
+ erry = 0.01003;
+ } else {
+ erry = 0.1931;
+ }
+ goto x; //return;
+ }
+
+/* ---> "Good" clusters */
+ if (ny > 3) {
+ if (TMath::Abs(wy - 5) < 0.1) {
+ erry = 0.0011; //0.00304
+ } else if (qtot < 400.) {
+ erry = 0.0165;
+ } else {
+ erry = 0.00135; // 0.00358
+ }
+ } else if (ny == 3) {
+ if (TMath::Abs(wy - 4) < 0.1) {
+ erry = 35.407 / (1 + TMath::Exp(5.511*TMath::Log(qtot/265.51))) + 11.564;
+ //erry = 83.512 / (1 + TMath::Exp(3.344*TMath::Log(qtot/211.58))) + 12.260;
+ } else {
+ erry = 147.03 / (1 + TMath::Exp(1.713*TMath::Log(qtot/73.151))) + 9.575;
+ //erry = 91.743 / (1 + TMath::Exp(2.332*TMath::Log(qtot/151.67))) + 11.453;
+ }
+ erry *= 1.e-4;
+ } else {
+ // ny = 2
+ if (TMath::Abs(wy - 4) < 0.1) {
+ erry = 60.800 / (1 + TMath::Exp(3.305*TMath::Log(qtot/104.53))) + 11.702;
+ //erry = 73.128 / (1 + TMath::Exp(5.676*TMath::Log(qtot/120.93))) + 17.839;
+ } else {
+ erry = 117.98 / (1 + TMath::Exp(2.005*TMath::Log(qtot/37.649))) + 21.431;
+ //erry = 99.066 / (1 + TMath::Exp(4.900*TMath::Log(qtot/107.57))) + 25.315;
+ }
+ erry *= 1.e-4;
+ }
+ //return;
+
+ x:
+/* ---> X-coordinate */
+/* ---> Y-side */
+ if (wx > 11) {
+ errx = 0.0036;
+ xrec -= 0.1385;
+ return;
+ }
+/* ---> Nx = 1 */
+ if (nx == 1) {
+ if (TMath::Abs(wx - 6) < 0.1) {
+ if (qtot < 40) errx = 0.1693;
+ else errx = 0.06241;
+ } else if (TMath::Abs(wx - 7.5) < 0.1) {
+ if (qtot < 40) errx = 0.2173;
+ else errx = 0.07703;
+ } else if (TMath::Abs(wx - 10) < 0.1) {
+ if (ibx == 0) {
+ if (qtot < 40) errx = 0.2316;
+ else errx = 0.1426;
+ } else {
+ xrec += (0.2115 + 0.1942) / 2 * ibx;
+ errx = 0.1921;
+ }
+ }
+ return;
+ }
+/* ---> "Bad" fit */
+ if (fmin > 0.5) {
+ errx = 0.1591;
+ return;
+ }
+/* ---> Bx != 0 */
+ if (ibx != 0) {
+ if (ibx > 0) { errx = 0.06761; xrec -= 0.03832; }
+ else { errx = 0.06653; xrec += 0.02581; }
+ return;
+ }
+/* ---> Overflows */
+ if (iover != 0) {
+ if (TMath::Abs(wx - 6) < 0.1) errx = 0.06979;
+ else if (TMath::Abs(wx - 7.5) < 0.1) errx = 0.1089;
+ else if (TMath::Abs(wx - 10) < 0.1) errx = 0.09847;
+ return;
+ }
+/* ---> Good */
+ if (TMath::Abs(wx - 6) < 0.1) errx = 0.06022;
+ else if (TMath::Abs(wx - 7.5) < 0.1) errx = 0.07247;
+ else if (TMath::Abs(wx - 10) < 0.1) errx = 0.07359;
+}
+