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[u/mrichter/AliRoot.git] / HMPID / AliHMPIDRecon.cxx
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d3da6dc4 1/**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
3 * *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
6 * *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
15
16//////////////////////////////////////////////////////////////////////////
17// //
18// AliHMPIDRecon //
19// //
20// HMPID class to perfom pattern recognition based on Hough transfrom //
21// for single chamber //
22//////////////////////////////////////////////////////////////////////////
23
a591e55f 24#include "AliHMPIDRecon.h" //class header
25#include "AliHMPIDParam.h" //CkovAngle()
d3da6dc4 26#include "AliHMPIDCluster.h" //CkovAngle()
43400d2d 27#include <TMinuit.h> //FitEllipse()
a591e55f 28#include <TRotation.h> //TracePhot()
29#include <TH1D.h> //HoughResponse()
30#include <TClonesArray.h> //CkovAngle()
31#include <AliESDtrack.h> //CkovAngle()
d3da6dc4 32
33const Double_t AliHMPIDRecon::fgkRadThick=1.5;
34const Double_t AliHMPIDRecon::fgkWinThick=0.5;
35const Double_t AliHMPIDRecon::fgkGapThick=8.0;
d3da6dc4 36const Double_t AliHMPIDRecon::fgkWinIdx =1.5787;
37const Double_t AliHMPIDRecon::fgkGapIdx =1.0005;
38
d3da6dc4 39//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
40AliHMPIDRecon::AliHMPIDRecon():TTask("RichRec","RichPat"),
abb5f786 41 fRadNmean(1.292),
d3da6dc4 42 fPhotCnt(-1),
43 fCkovSigma2(0),
44 fIsWEIGHT(kFALSE),
45 fDTheta(0.001),
46 fWindowWidth(0.045),
47 fTrkDir(TVector3(0,0,1)),fTrkPos(TVector2(30,40))
48{
49// main ctor
50 for (Int_t i=0; i<3000; i++) {
51 fPhotFlag[i] = 0;
52 fPhotCkov[i] = -1;
53 fPhotPhi [i] = -1;
54 fPhotWei [i] = 0;
55 }
611e810d 56//hidden algorithm
5b2b2013 57 fMipX=fMipY=fThTrkFit=fPhTrkFit=fCkovFit=fMipQ=fRadX=fRadY=-999;
611e810d 58 fIdxMip=fNClu=0;
3b49956b 59 fCkovSig2=0;
5b2b2013 60 for (Int_t i=0; i<100; i++) {
611e810d 61 fXClu[i] = fYClu[i] = 0;
5b2b2013 62 fClCk[i] = kTRUE;
611e810d 63 }
d3da6dc4 64}
65//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
a591e55f 66void AliHMPIDRecon::CkovAngle(AliESDtrack *pTrk,TClonesArray *pCluLst,Double_t nmean)
d3da6dc4 67{
68// Pattern recognition method based on Hough transform
59280a5a 69// Arguments: pTrk - track for which Ckov angle is to be found
70// pCluLst - list of clusters for this chamber
71// Returns: - track ckov angle, [rad],
a591e55f 72
73 AliHMPIDParam *pParam=AliHMPIDParam::Instance();
d3da6dc4 74
a591e55f 75 if(pCluLst->GetEntries()>pParam->MultCut()) fIsWEIGHT = kTRUE; // offset to take into account bkg in reconstruction
76 else fIsWEIGHT = kFALSE;
d3da6dc4 77
611e810d 78 Float_t xRa,yRa,th,ph;
a591e55f 79 pTrk->GetHMPIDtrk(xRa,yRa,th,ph); //initialize this track: th and ph angles at middle of RAD
a591e55f 80 SetTrack(xRa,yRa,th,ph);
611e810d 81
abb5f786 82 fRadNmean=nmean;
d3da6dc4 83
59280a5a 84 Float_t dMin=999,mipX=-1,mipY=-1;Int_t chId=-1,mipId=-1,mipQ=-1;
d3da6dc4 85 fPhotCnt=0;
86 for (Int_t iClu=0; iClu<pCluLst->GetEntriesFast();iClu++){//clusters loop
87 AliHMPIDCluster *pClu=(AliHMPIDCluster*)pCluLst->UncheckedAt(iClu); //get pointer to current cluster
59280a5a 88 chId=pClu->Ch();
a591e55f 89 if(pClu->Q()>pParam->QCut()){ //charge compartible with MIP clusters
90 Float_t dX=fPc.X()-pClu->X(),dY=fPc.Y()-pClu->Y(),d =TMath::Sqrt(dX*dX+dY*dY); //distance between current cluster and intersection point
91 if( d < dMin) {mipId=iClu; dMin=d;mipX=pClu->X();mipY=pClu->Y();mipQ=(Int_t)pClu->Q();} //current cluster is closer, overwrite data for min cluster
92 }else{ //charge compatible with photon cluster
93 Double_t thetaCer,phiCer;
94 if(FindPhotCkov(pClu->X(),pClu->Y(),thetaCer,phiCer)){ //find ckov angle for this photon candidate
95 fPhotCkov[fPhotCnt]=thetaCer; //actual theta Cerenkov (in TRS)
b4ad85e9 96 fPhotPhi [fPhotCnt]=phiCer; //actual phi Cerenkov (in TRS): -pi to come back to "unusual" ref system (X,Y,-Z)
28500fe1 97 //PH Printf("photon n. %i reconstructed theta = %f",fPhotCnt,fPhotCkov[fPhotCnt]);
a591e55f 98 fPhotCnt++; //increment counter of photon candidates
99 }
59280a5a 100 }
d3da6dc4 101 }//clusters loop
76fd1a96 102 if(fPhotCnt<=3) pTrk->SetHMPIDsignal(kNoPhotAccept); //no reconstruction with <=3 photon candidates
a591e55f 103 Int_t iNacc=FlagPhot(HoughResponse()); //flag photons according to individual theta ckov with respect to most probable
104 pTrk->SetHMPIDmip(mipX,mipY,mipQ,iNacc); //store mip info
59280a5a 105
a591e55f 106 if(mipId==-1) {pTrk->SetHMPIDsignal(kMipQdcCut); return;} //no clusters with QDC more the threshold at all
107 if(dMin>pParam->DistCut()) {pTrk->SetHMPIDsignal(kMipDistCut); return;} //closest cluster with enough charge is still too far from intersection
108 pTrk->SetHMPIDcluIdx(chId,mipId); //set index of cluster
76fd1a96 109 if(iNacc<1){
110 pTrk->SetHMPIDsignal(kNoPhotAccept); //no photon candidates is accepted
111 }
112 else {
113 pTrk->SetHMPIDsignal(FindRingCkov(pCluLst->GetEntries())); //find best Theta ckov for ring i.e. track
114 pTrk->SetHMPIDchi2(fCkovSigma2); //errors squared
115 }
d3da6dc4 116
43400d2d 117}//CkovAngle()
d3da6dc4 118//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
a591e55f 119Bool_t AliHMPIDRecon::FindPhotCkov(Double_t cluX,Double_t cluY,Double_t &thetaCer,Double_t &phiCer)
d3da6dc4 120{
121// Finds Cerenkov angle for this photon candidate
122// Arguments: cluX,cluY - position of cadidate's cluster
a591e55f 123// Returns: Cerenkov angle
d3da6dc4 124
a591e55f 125 TVector3 dirCkov;
126
67a1c24c 127 Double_t zRad= -0.5*fgkRadThick-0.5*fgkWinThick; //z position of middle of RAD
128 TVector3 rad(fTrkPos.X(),fTrkPos.Y(),zRad); //impact point at middle of RAD
129 TVector3 pc(cluX,cluY,0.5*fgkWinThick+fgkGapIdx); //mip at PC
a591e55f 130 Double_t cluR = TMath::Sqrt((cluX-fTrkPos.X())*(cluX-fTrkPos.X())+
131 (cluY-fTrkPos.Y())*(cluY-fTrkPos.Y()));//ref. distance impact RAD-CLUSTER
67a1c24c 132 Double_t phi=(pc-rad).Phi(); //phi of photon
a591e55f 133
b4ad85e9 134 Double_t ckov1=0;
67a1c24c 135 Double_t ckov2=0.75+fTrkDir.Theta(); //start to find theta cerenkov in DRS
b4ad85e9 136 const Double_t kTol=0.01;
d3da6dc4 137 Int_t iIterCnt = 0;
138 while(1){
a591e55f 139 if(iIterCnt>=50) return kFALSE;
d3da6dc4 140 Double_t ckov=0.5*(ckov1+ckov2);
67a1c24c 141 dirCkov.SetMagThetaPhi(1,ckov,phi);
a591e55f 142 TVector2 posC=TraceForward(dirCkov); //trace photon with actual angles
143 Double_t dist=cluR-(posC-fTrkPos).Mod(); //get distance between trial point and cluster position
144 if(posC.X()==-999) dist = - 999; //total reflection problem
145 iIterCnt++; //counter step
b4ad85e9 146 if (dist> kTol) ckov1=ckov; //cluster @ larger ckov
d3da6dc4 147 else if(dist<-kTol) ckov2=ckov; //cluster @ smaller ckov
a591e55f 148 else{ //precision achived: ckov in DRS found
149 dirCkov.SetMagThetaPhi(1,ckov,phi); //
150 RecPhot(dirCkov,thetaCer,phiCer); //find ckov (in TRS:the effective Cherenkov angle!)
151 return kTRUE;
152 }
d3da6dc4 153 }
154}//FindPhotTheta()
155//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
a591e55f 156TVector2 AliHMPIDRecon::TraceForward(TVector3 dirCkov)const
d3da6dc4 157{
a591e55f 158 //Trace forward a photon from (x,y) up to PC
159 // Arguments: dirCkov photon vector in LORS
160 // Returns: pos of traced photon at PC
161 TVector2 pos(-999,-999);
67a1c24c 162 Double_t thetaCer = dirCkov.Theta();
163 if(thetaCer > TMath::ASin(1./fRadNmean)) return pos; //total refraction on WIN-GAP boundary
164 Double_t zRad= -0.5*fgkRadThick-0.5*fgkWinThick; //z position of middle of RAD
165 TVector3 posCkov(fTrkPos.X(),fTrkPos.Y(),zRad); //RAD: photon position is track position @ middle of RAD
166 Propagate(dirCkov,posCkov, -0.5*fgkWinThick); //go to RAD-WIN boundary
167 Refract (dirCkov, fRadNmean,fgkWinIdx); //RAD-WIN refraction
168 Propagate(dirCkov,posCkov, 0.5*fgkWinThick); //go to WIN-GAP boundary
169 Refract (dirCkov, fgkWinIdx,fgkGapIdx); //WIN-GAP refraction
170 Propagate(dirCkov,posCkov,0.5*fgkWinThick+fgkGapThick); //go to PC
a591e55f 171 pos.Set(posCkov.X(),posCkov.Y());
172 return pos;
173}//TraceForward()
174//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
175void AliHMPIDRecon::RecPhot(TVector3 dirCkov,Double_t &thetaCer,Double_t &phiCer)
176{
177 //Theta Cerenkov reconstruction
178 // Arguments: (x,y) of initial point in LORS, dirCkov photon vector in LORS
179 // Returns: thetaCer theta cerenkov reconstructed
180// TVector3 dirTrk;
181// dirTrk.SetMagThetaPhi(1,fTrkDir.Theta(),fTrkDir.Phi());
182// Double_t thetaCer = TMath::ACos(dirCkov*dirTrk);
183 TRotation mtheta; mtheta.RotateY(- fTrkDir.Theta());
184 TRotation mphi; mphi.RotateZ(- fTrkDir.Phi());
185 TRotation mrot=mtheta*mphi;
186 TVector3 dirCkovTRS;
187 dirCkovTRS=mrot*dirCkov;
188 phiCer = dirCkovTRS.Phi(); //actual value of the phi of the photon
189 thetaCer= dirCkovTRS.Theta(); //actual value of thetaCerenkov of the photon
d3da6dc4 190}
191//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
192Double_t AliHMPIDRecon::FindRingArea(Double_t ckovAng)const
193{
194// Find area inside the cerenkov ring which lays inside PCs
a591e55f 195// Arguments: ckovAng - cerenkov angle
d3da6dc4 196// Returns: area of the ring in cm^2 for given theta ckov
197
d3da6dc4 198 const Int_t kN=100;
199 Double_t area=0;
200 for(Int_t i=0;i<kN;i++){
a591e55f 201 TVector2 pos1=TracePhot(ckovAng,Double_t(TMath::TwoPi()*i /kN));//trace this photon
202 TVector2 pos2=TracePhot(ckovAng,Double_t(TMath::TwoPi()*(i+1)/kN));//trace the next photon
203 area+=(pos1-fTrkPos)*(pos2-fTrkPos); //add area of the triangle...
d3da6dc4 204 }
205 return area;
206}//FindRingArea()
207//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
208Double_t AliHMPIDRecon::FindRingCkov(Int_t)
209{
210// Loops on all Ckov candidates and estimates the best Theta Ckov for a ring formed by those candidates. Also estimates an error for that Theat Ckov
211// collecting errors for all single Ckov candidates thetas. (Assuming they are independent)
212// Arguments: iNclus- total number of clusters in chamber for background estimation
213// Return: best estimation of track Theta ckov
214
215 Double_t wei = 0.;
216 Double_t weightThetaCerenkov = 0.;
217
218 Double_t ckovMin=9999.,ckovMax=0.;
219 Double_t sigma2 = 0; //to collect error squared for this ring
220
221 for(Int_t i=0;i<fPhotCnt;i++){//candidates loop
222 if(fPhotFlag[i] == 2){
a591e55f 223 if(fPhotCkov[i]<ckovMin) ckovMin=fPhotCkov[i]; //find max and min Theta ckov from all candidates within probable window
d3da6dc4 224 if(fPhotCkov[i]>ckovMax) ckovMax=fPhotCkov[i];
a591e55f 225 weightThetaCerenkov += fPhotCkov[i]*fPhotWei[i];
226 wei += fPhotWei[i]; //collect weight as sum of all candidate weghts
d3da6dc4 227
d3da6dc4 228 sigma2 += 1./Sigma2(fPhotCkov[i],fPhotPhi[i]);
229 }
230 }//candidates loop
231
232 if(sigma2>0) fCkovSigma2=1./sigma2;
233 else fCkovSigma2=1e10;
234
b4ad85e9 235 if(wei != 0.) weightThetaCerenkov /= wei; else weightThetaCerenkov = 0.;
d3da6dc4 236 return weightThetaCerenkov;
237}//FindCkovRing()
238//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
239Int_t AliHMPIDRecon::FlagPhot(Double_t ckov)
240{
241// Flag photon candidates if their individual ckov angle is inside the window around ckov angle returned by HoughResponse()
242// Arguments: ckov- value of most probable ckov angle for track as returned by HoughResponse()
243// Returns: number of photon candidates happened to be inside the window
244
a591e55f 245// Photon Flag: Flag = 0 initial set;
246// Flag = 1 good candidate (charge compatible with photon);
247// Flag = 2 photon used for the ring;
d3da6dc4 248
249 Int_t steps = (Int_t)((ckov )/ fDTheta); //how many times we need to have fDTheta to fill the distance between 0 and thetaCkovHough
250
251 Double_t tmin = (Double_t)(steps - 1)*fDTheta;
252 Double_t tmax = (Double_t)(steps)*fDTheta;
253 Double_t tavg = 0.5*(tmin+tmax);
254
255 tmin = tavg - 0.5*fWindowWidth; tmax = tavg + 0.5*fWindowWidth;
256
257 Int_t iInsideCnt = 0; //count photons which Theta ckov inside the window
258 for(Int_t i=0;i<fPhotCnt;i++){//photon candidates loop
259 if(fPhotCkov[i] >= tmin && fPhotCkov[i] <= tmax) {
260 fPhotFlag[i]=2;
261 iInsideCnt++;
262 }
263 }
264 return iInsideCnt;
265}//FlagPhot()
266//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
a591e55f 267TVector2 AliHMPIDRecon::TracePhot(Double_t ckovThe,Double_t ckovPhi)const
d3da6dc4 268{
269// Trace a single Ckov photon from emission point somewhere in radiator up to photocathode taking into account ref indexes of materials it travereses
a591e55f 270// Arguments: ckovThe,ckovPhi- photon ckov angles in DRS, [rad]
d3da6dc4 271// Returns: distance between photon point on PC and track projection
272 TRotation mtheta; mtheta.RotateY(fTrkDir.Theta());
273 TRotation mphi; mphi.RotateZ(fTrkDir.Phi());
274 TRotation mrot=mphi*mtheta;
a591e55f 275 TVector3 dirCkov,dirCkovTors;
276
277 dirCkovTors.SetMagThetaPhi(1,ckovThe,ckovPhi); //initially photon is directed according to requested ckov angle
278 dirCkov=mrot*dirCkovTors; //now we know photon direction in LORS
279 return TraceForward(dirCkov);
280}//TracePhot()
d3da6dc4 281//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
a591e55f 282void AliHMPIDRecon::Propagate(const TVector3 dir,TVector3 &pos,Double_t z)const
d3da6dc4 283{
284// Finds an intersection point between a line and XY plane shifted along Z.
285// Arguments: dir,pos - vector along the line and any point of the line
286// z - z coordinate of plain
287// Returns: none
288// On exit: pos is the position if this intesection if any
289 static TVector3 nrm(0,0,1);
290 TVector3 pnt(0,0,z);
291
292 TVector3 diff=pnt-pos;
293 Double_t sint=(nrm*diff)/(nrm*dir);
294 pos+=sint*dir;
295}//Propagate()
296//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
297void AliHMPIDRecon::Refract(TVector3 &dir,Double_t n1,Double_t n2)const
298{
299// Refract direction vector according to Snell law
300// Arguments:
301// n1 - ref idx of first substance
302// n2 - ref idx of second substance
303// Returns: none
304// On exit: dir is new direction
67a1c24c 305 Double_t sinref=(n1/n2)*TMath::Sin(dir.Theta());
76fd1a96 306 if(TMath::Abs(sinref)>1.) dir.SetXYZ(-999,-999,-999);
67a1c24c 307 else dir.SetTheta(TMath::ASin(sinref));
d3da6dc4 308}//Refract()
309//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
310Double_t AliHMPIDRecon::HoughResponse()
311{
312//
611e810d 313// fIdxMip = mipId;
314
d3da6dc4 315//
316 Double_t kThetaMax=0.75;
317 Int_t nChannels = (Int_t)(kThetaMax/fDTheta+0.5);
318 TH1D *phots = new TH1D("Rphot" ,"phots" ,nChannels,0,kThetaMax);
319 TH1D *photsw = new TH1D("RphotWeighted" ,"photsw" ,nChannels,0,kThetaMax);
320 TH1D *resultw = new TH1D("resultw","resultw" ,nChannels,0,kThetaMax);
321 Int_t nBin = (Int_t)(kThetaMax/fDTheta);
322 Int_t nCorrBand = (Int_t)(fWindowWidth/(2*fDTheta));
323
324 for (Int_t i=0; i< fPhotCnt; i++){//photon cadidates loop
325 Double_t angle = fPhotCkov[i]; if(angle<0||angle>kThetaMax) continue;
326 phots->Fill(angle);
327 Int_t bin = (Int_t)(0.5+angle/(fDTheta));
328 Double_t weight=1.;
329 if(fIsWEIGHT){
330 Double_t lowerlimit = ((Double_t)bin)*fDTheta - 0.5*fDTheta; Double_t upperlimit = ((Double_t)bin)*fDTheta + 0.5*fDTheta;
331 Double_t diffArea = FindRingArea(upperlimit)-FindRingArea(lowerlimit);
332 if(diffArea>0) weight = 1./diffArea;
333 }
334 photsw->Fill(angle,weight);
335 fPhotWei[i]=weight;
336 }//photon candidates loop
337
338 for (Int_t i=1; i<=nBin;i++){
339 Int_t bin1= i-nCorrBand;
340 Int_t bin2= i+nCorrBand;
341 if(bin1<1) bin1=1;
342 if(bin2>nBin)bin2=nBin;
343 Double_t sumPhots=phots->Integral(bin1,bin2);
344 if(sumPhots<3) continue; // if less then 3 photons don't trust to this ring
345 Double_t sumPhotsw=photsw->Integral(bin1,bin2);
346 resultw->Fill((Double_t)((i+0.5)*fDTheta),sumPhotsw);
347 }
348// evaluate the "BEST" theta ckov as the maximum value of histogramm
349 Double_t *pVec = resultw->GetArray();
350 Int_t locMax = TMath::LocMax(nBin,pVec);
3ebd8038 351 delete phots;delete photsw;delete resultw; // Reset and delete objects
d3da6dc4 352
353 return (Double_t)(locMax*fDTheta+0.5*fDTheta); //final most probable track theta ckov
354}//HoughResponse()
355//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
356Double_t AliHMPIDRecon::Sigma2(Double_t ckovTh, Double_t ckovPh)const
357{
358// Analithical calculation of total error (as a sum of localization, geometrical and chromatic errors) on Cerenkov angle for a given Cerenkov photon
359// created by a given MIP. Fromulae according to CERN-EP-2000-058
360// Arguments: Cerenkov and azimuthal angles for Cerenkov photon, [radians]
361// dip and azimuthal angles for MIP taken at the entrance to radiator, [radians]
362// MIP beta
363// Returns: absolute error on Cerenkov angle, [radians]
364
365 TVector3 v(-999,-999,-999);
abb5f786 366 Double_t trkBeta = 1./(TMath::Cos(ckovTh)*fRadNmean);
d3498bf5 367
368 if(trkBeta > 1) trkBeta = 1; //protection against bad measured thetaCer
369 if(trkBeta < 0) trkBeta = 0.0001; //
d3da6dc4 370
371 v.SetX(SigLoc (ckovTh,ckovPh,trkBeta));
372 v.SetY(SigGeom(ckovTh,ckovPh,trkBeta));
373 v.SetZ(SigCrom(ckovTh,ckovPh,trkBeta));
374
375 return v.Mag2();
376}
377//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
378Double_t AliHMPIDRecon::SigLoc(Double_t thetaC, Double_t phiC,Double_t betaM)const
379{
380// Analithical calculation of localization error (due to finite segmentation of PC) on Cerenkov angle for a given Cerenkov photon
381// created by a given MIP. Fromulae according to CERN-EP-2000-058
382// Arguments: Cerenkov and azimuthal angles for Cerenkov photon, [radians]
383// dip and azimuthal angles for MIP taken at the entrance to radiator, [radians]
384// MIP beta
385// Returns: absolute error on Cerenkov angle, [radians]
d3498bf5 386
d3da6dc4 387 Double_t phiDelta = phiC - fTrkDir.Phi();
388
d3498bf5 389 Double_t sint = TMath::Sin(fTrkDir.Theta());
390 Double_t cost = TMath::Cos(fTrkDir.Theta());
391 Double_t sinf = TMath::Sin(fTrkDir.Phi());
392 Double_t cosf = TMath::Cos(fTrkDir.Phi());
393 Double_t sinfd = TMath::Sin(phiDelta);
394 Double_t cosfd = TMath::Cos(phiDelta);
395 Double_t tantheta = TMath::Tan(thetaC);
396
397 Double_t alpha =cost-tantheta*cosfd*sint; // formula (11)
398 Double_t k = 1.-fRadNmean*fRadNmean+alpha*alpha/(betaM*betaM); // formula (after 8 in the text)
d3da6dc4 399 if (k<0) return 1e10;
d3498bf5 400 Double_t mu =sint*sinf+tantheta*(cost*cosfd*sinf+sinfd*cosf); // formula (10)
401 Double_t e =sint*cosf+tantheta*(cost*cosfd*cosf-sinfd*sinf); // formula (9)
d3da6dc4 402
d3498bf5 403 Double_t kk = betaM*TMath::Sqrt(k)/(fgkGapThick*alpha); // formula (6) and (7)
404 Double_t dtdxc = kk*(k*(cosfd*cosf-cost*sinfd*sinf)-(alpha*mu/(betaM*betaM))*sint*sinfd); // formula (6)
405 Double_t dtdyc = kk*(k*(cosfd*sinf+cost*sinfd*cosf)+(alpha* e/(betaM*betaM))*sint*sinfd); // formula (7) pag.4
d3da6dc4 406
d3498bf5 407 Double_t errX = 0.2,errY=0.25; //end of page 7
408 return TMath::Sqrt(errX*errX*dtdxc*dtdxc + errY*errY*dtdyc*dtdyc);
d3da6dc4 409}
410//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
411Double_t AliHMPIDRecon::SigCrom(Double_t thetaC, Double_t phiC,Double_t betaM)const
412{
413// Analithical calculation of chromatic error (due to lack of knowledge of Cerenkov photon energy) on Cerenkov angle for a given Cerenkov photon
414// created by a given MIP. Fromulae according to CERN-EP-2000-058
415// Arguments: Cerenkov and azimuthal angles for Cerenkov photon, [radians]
416// dip and azimuthal angles for MIP taken at the entrance to radiator, [radians]
417// MIP beta
418// Returns: absolute error on Cerenkov angle, [radians]
d3498bf5 419
d3da6dc4 420 Double_t phiDelta = phiC - fTrkDir.Phi();
d3da6dc4 421
d3498bf5 422 Double_t sint = TMath::Sin(fTrkDir.Theta());
423 Double_t cost = TMath::Cos(fTrkDir.Theta());
424 Double_t cosfd = TMath::Cos(phiDelta);
425 Double_t tantheta = TMath::Tan(thetaC);
426
427 Double_t alpha =cost-tantheta*cosfd*sint; // formula (11)
428 Double_t dtdn = cost*fRadNmean*betaM*betaM/(alpha*tantheta); // formula (12)
d3da6dc4 429
d3498bf5 430// Double_t f = 0.00928*(7.75-5.635)/TMath::Sqrt(12.);
431 Double_t f = 0.0172*(7.75-5.635)/TMath::Sqrt(24.);
d3da6dc4 432
433 return f*dtdn;
434}//SigCrom()
435//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
436Double_t AliHMPIDRecon::SigGeom(Double_t thetaC, Double_t phiC,Double_t betaM)const
437{
438// Analithical calculation of geometric error (due to lack of knowledge of creation point in radiator) on Cerenkov angle for a given Cerenkov photon
439// created by a given MIP. Formulae according to CERN-EP-2000-058
440// Arguments: Cerenkov and azimuthal angles for Cerenkov photon, [radians]
441// dip and azimuthal angles for MIP taken at the entrance to radiator, [radians]
442// MIP beta
443// Returns: absolute error on Cerenkov angle, [radians]
444
445 Double_t phiDelta = phiC - fTrkDir.Phi();
d3da6dc4 446
d3498bf5 447 Double_t sint = TMath::Sin(fTrkDir.Theta());
448 Double_t cost = TMath::Cos(fTrkDir.Theta());
449 Double_t sinf = TMath::Sin(fTrkDir.Phi());
450 Double_t cosfd = TMath::Cos(phiDelta);
451 Double_t costheta = TMath::Cos(thetaC);
452 Double_t tantheta = TMath::Tan(thetaC);
453
454 Double_t alpha =cost-tantheta*cosfd*sint; // formula (11)
455
456 Double_t k = 1.-fRadNmean*fRadNmean+alpha*alpha/(betaM*betaM); // formula (after 8 in the text)
d3da6dc4 457 if (k<0) return 1e10;
458
d3498bf5 459 Double_t eTr = 0.5*fgkRadThick*betaM*TMath::Sqrt(k)/(fgkGapThick*alpha); // formula (14)
460 Double_t lambda = 1.-sint*sint*sinf*sinf; // formula (15)
d3da6dc4 461
d3498bf5 462 Double_t c1 = 1./(1.+ eTr*k/(alpha*alpha*costheta*costheta)); // formula (13.a)
463 Double_t c2 = betaM*TMath::Power(k,1.5)*tantheta*lambda/(fgkGapThick*alpha*alpha); // formula (13.b)
464 Double_t c3 = (1.+eTr*k*betaM*betaM)/((1+eTr)*alpha*alpha); // formula (13.c)
465 Double_t c4 = TMath::Sqrt(k)*tantheta*(1-lambda)/(fgkGapThick*betaM); // formula (13.d)
466 Double_t dtdT = c1 * (c2+c3*c4);
467 Double_t trErr = fgkRadThick/(TMath::Sqrt(12.)*cost);
d3da6dc4 468
d3498bf5 469 return trErr*dtdT;
d3da6dc4 470}//SigGeom()
471//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
43400d2d 472//
611e810d 473// From here HTA....
43400d2d 474//
475//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
5b2b2013 476Bool_t AliHMPIDRecon::CkovHiddenTrk(AliESDtrack *pTrk,TClonesArray *pCluLst,Double_t nmean)
43400d2d 477{
611e810d 478// Pattern recognition method without any infos from tracking:HTA (Hidden Track Algorithm)...
43400d2d 479// The method finds in the chmber the cluster with the highest charge
480// compatibile with a MIP, then the strategy is applied
611e810d 481// Arguments: pTrk - pointer to ESD track
482// pCluLs - list of clusters for a given chamber
483// nmean - mean freon ref. index
484// Returns: - 0=ok,1=not fitted
485
486 AliHMPIDParam *pParam=AliHMPIDParam::Instance();
43400d2d 487
488 fRadNmean=nmean;
489
3b49956b 490 if(pCluLst->GetEntriesFast()>100) return kFALSE; //boundary check for CluX,CluY...
43400d2d 491 Float_t mipX=-1,mipY=-1;Int_t mipId=-1,mipQ=-1;
43400d2d 492 Double_t qRef = 0;
3b49956b 493 Int_t nCh=0;
5b2b2013 494 for (Int_t iClu=0;iClu<pCluLst->GetEntriesFast();iClu++){ //clusters loop
43400d2d 495 AliHMPIDCluster *pClu=(AliHMPIDCluster*)pCluLst->UncheckedAt(iClu); //get pointer to current cluster
3b49956b 496 nCh = pClu->Ch();
43400d2d 497 fXClu[iClu] = pClu->X();fYClu[iClu] = pClu->Y(); //store x,y for fitting procedure
5b2b2013 498 fClCk[iClu] = kTRUE; //all cluster are accepted at this stage to be reconstructed
43400d2d 499 if(pClu->Q()>qRef){ //searching the highest charge to select a MIP
500 qRef = pClu->Q();
501 mipId=iClu; mipX=pClu->X();mipY=pClu->Y();mipQ=(Int_t)pClu->Q();
502 }
503 }//clusters loop
43400d2d 504
5b2b2013 505 fNClu = pCluLst->GetEntriesFast();
3b49956b 506 if(qRef>pParam->QCut()){ //charge compartible with MIP clusters
611e810d 507 fIdxMip = mipId;
5b2b2013 508 fClCk[mipId] = kFALSE;
611e810d 509 fMipX = mipX; fMipY=mipY; fMipQ = qRef;
3b49956b 510 if(!DoRecHiddenTrk(pCluLst)) {
511 pTrk->SetHMPIDsignal(kNoPhotAccept);
512 return kFALSE;
513 } //Do track and ring reconstruction,if problems returns 1
514 pTrk->SetHMPIDtrk(fRadX,fRadY,fThTrkFit,fPhTrkFit); //store track intersection info
515 pTrk->SetHMPIDmip(fMipX,fMipY,(Int_t)fMipQ,fNClu); //store mip info
516 pTrk->SetHMPIDcluIdx(nCh,fIdxMip); //set cham number and index of cluster
517 pTrk->SetHMPIDsignal(fCkovFit); //find best Theta ckov for ring i.e. track
518 pTrk->SetHMPIDchi2(fCkovSig2); //errors squared
519// Printf(" n clusters tot %i accepted %i",pCluLst->GetEntriesFast(),fNClu);
5b2b2013 520 return kTRUE;
611e810d 521 }
3b49956b 522
5b2b2013 523 return kFALSE;
43400d2d 524}//CkovHiddenTrk()
525//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
5b2b2013 526Bool_t AliHMPIDRecon::DoRecHiddenTrk(TClonesArray *pCluLst)
43400d2d 527{
528// Pattern recognition method without any infos from tracking...
611e810d 529// First a preclustering filter to avoid part of the noise
43400d2d 530// Then only ellipsed-rings are fitted (no possibility,
611e810d 531// for the moment, to reconstruct very inclined tracks)
532// Finally a fitting with (th,ph) free, starting by very close values
43400d2d 533// previously evaluated.
534// Arguments: none
535// Returns: none
536 Double_t phiRec;
5b2b2013 537 if(!CluPreFilter(pCluLst)) {return kFALSE;}
611e810d 538 if(!FitEllipse(phiRec)) {return kFALSE;}
5b2b2013 539 Int_t nClTmp1 = pCluLst->GetEntriesFast()-1; //minus MIP...
540 Int_t nClTmp2 = 0;
541 while(nClTmp1 != nClTmp2){
542 SetNClu(pCluLst->GetEntriesFast());
543 if(!FitFree(phiRec)) {return kFALSE;}
544 nClTmp2 = NClu();
545 if(nClTmp2!=nClTmp1) {nClTmp1=nClTmp2;nClTmp2=0;}
546 }
547 fNClu = nClTmp2;
548 return kTRUE;
549}//DoRecHiddenTrk()
43400d2d 550//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
5b2b2013 551Bool_t AliHMPIDRecon::CluPreFilter(TClonesArray *pCluLst)
43400d2d 552{
553// Filter of bkg clusters
554// based on elliptical-shapes...
555//
5b2b2013 556 if(pCluLst->GetEntriesFast()>50||pCluLst->GetEntriesFast()<4) return kFALSE;
557 else return kTRUE;
43400d2d 558}
559//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
560Bool_t AliHMPIDRecon::FitEllipse(Double_t &phiRec)
561{
562//Fit a set of clusters with an analitical conical section function:
563 //
564 // Ax^2 + B*y^2 + 2Hxy + 2Gx + 2Fy + 1 = 0 ---> conical section
565 //
566 // H*H - A*B > 0 hyperbola
567 // < 0 ellipse
568 // = 0 parabola
569 //
570 // tan 2alfa = 2H/(A-B) alfa=angle of rotation
571 //
572 // coordinate of the centre of the conical section:
573 // x = x' + a
574 // y = y' + b
575 //
576 // HF - BG
577 // a = ---------
578 // AB - H^2
579 //
580 // HG - AF
581 // b = --------
582 // AB - H^2
43400d2d 583 Double_t cA,cB,cF,cG,cH;
611e810d 584 Double_t aArg=-1; Int_t iErrFlg; //tmp vars for TMinuit
43400d2d 585
611e810d 586 if(!gMinuit) gMinuit = new TMinuit(5); //init MINUIT with this number of parameters (5 params)
43400d2d 587 gMinuit->mncler(); // reset Minuit list of paramters
588 gMinuit->SetObjectFit((TObject*)this); gMinuit->SetFCN(AliHMPIDRecon::FunMinEl); //set fit function
c0d7adf8 589 gMinuit->mnexcm("SET PRI",&aArg,1,iErrFlg); //suspend all printout from TMinuit
590 gMinuit->mnexcm("SET NOW",&aArg,0,iErrFlg); //suspend all warning printout from TMinuit
43400d2d 591
592 Double_t d1,d2,d3;
593 TString sName;
594
611e810d 595 gMinuit->mnparm(0," A ",1,0.01,0,0,iErrFlg);
596 gMinuit->mnparm(1," B ",1,0.01,0,0,iErrFlg);
597 gMinuit->mnparm(2," H ",1,0.01,0,0,iErrFlg);
598 gMinuit->mnparm(3," G ",1,0.01,0,0,iErrFlg);
599 gMinuit->mnparm(4," F ",1,0.01,0,0,iErrFlg);
43400d2d 600
3b49956b 601 gMinuit->mnexcm("SIMPLEX",&aArg,0,iErrFlg);
43400d2d 602 gMinuit->mnexcm("MIGRAD" ,&aArg,0,iErrFlg);
603 gMinuit->mnpout(0,sName,cA,d1,d2,d3,iErrFlg);
604 gMinuit->mnpout(1,sName,cB,d1,d2,d3,iErrFlg);
605 gMinuit->mnpout(2,sName,cH,d1,d2,d3,iErrFlg);
606 gMinuit->mnpout(3,sName,cG,d1,d2,d3,iErrFlg);
607 gMinuit->mnpout(4,sName,cF,d1,d2,d3,iErrFlg);
608 delete gMinuit;
609
610 Double_t i2 = cA*cB-cH*cH; //quartic invariant : i2 > 0 ellipse, i2 < 0 hyperbola
096ddc3f 611 if(i2<=0) return kFALSE;
43400d2d 612 Double_t aX = (cH*cF-cB*cG)/i2; //x centre of the canonical section
613 Double_t bY = (cH*cG-cA*cF)/i2; //y centre of the canonical section
614 Double_t alfa1 = TMath::ATan(2*cH/(cA-cB)); //alpha = angle of rotation of the conical section
615 if(alfa1<0) alfa1+=TMath::Pi();
616 alfa1*=0.5;
3b49956b 617// Double_t alfa2 = alfa1+TMath::Pi();
618 Double_t phiref = TMath::ATan2(bY-fMipY,aX-fMipX); //evaluate in a unique way the angle of rotation comparing it
619 if(phiref<0) phiref+=TMath::TwoPi(); //with the vector that points to the centre from the mip
43400d2d 620 if(i2<0) phiref+=TMath::Pi();
621 if(phiref>TMath::TwoPi()) phiref-=TMath::TwoPi();
622
623// Printf(" alfa1 %f",alfa1*TMath::RadToDeg());
624// Printf(" alfa2 %f",alfa2*TMath::RadToDeg());
625// Printf(" firef %f",phiref*TMath::RadToDeg());
3b49956b 626// if(TMath::Abs(alfa1-phiref)<TMath::Abs(alfa2-phiref)) phiRec = alfa1; else phiRec = alfa2;
43400d2d 627
3b49956b 628// Printf("FitEllipse: phi reconstructed %f",phiRec*TMath::RadToDeg());
629 phiRec=phiref;
096ddc3f 630 return kTRUE;
43400d2d 631//
632}
633//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
611e810d 634Bool_t AliHMPIDRecon::FitFree(Double_t phiRec)
43400d2d 635{
636// Fit performed by minimizing RMS/sqrt(n) of the
637// photons reconstructed. First phi is fixed and theta
638// is fouond, then (th,ph) of the track
639// as free parameters
640// Arguments: PhiRec phi of the track
641// Returns: none
611e810d 642 Double_t aArg=-1; Int_t iErrFlg; //tmp vars for TMinuit
643 if(!gMinuit) gMinuit = new TMinuit(2); //init MINUIT with this number of parameters (5 params)
43400d2d 644 gMinuit->mncler(); // reset Minuit list of paramters
645 gMinuit->SetObjectFit((TObject*)this); gMinuit->SetFCN(AliHMPIDRecon::FunMinPhot); //set fit function
646 gMinuit->mnexcm("SET PRI",&aArg,1,iErrFlg); //suspend all printout from TMinuit
647 gMinuit->mnexcm("SET NOW",&aArg,0,iErrFlg); //suspend all warning printout from TMinuit
648
649 Double_t d1,d2,d3;
650 TString sName;
651 Double_t th,ph;
652
611e810d 653 gMinuit->mnparm(0," theta ", 0.01,0.01,0,TMath::PiOver2(),iErrFlg);
654 gMinuit->mnparm(1," phi ",phiRec,0.01,0,TMath::TwoPi() ,iErrFlg);
43400d2d 655
656 gMinuit->FixParameter(1);
657 gMinuit->mnexcm("SIMPLEX" ,&aArg,0,iErrFlg);
658 gMinuit->mnexcm("MIGRAD" ,&aArg,0,iErrFlg);
659 gMinuit->Release(1);
660 gMinuit->mnexcm("MIGRAD" ,&aArg,0,iErrFlg);
661
662 gMinuit->mnpout(0,sName,th,d1,d2,d3,iErrFlg);
663 gMinuit->mnpout(1,sName,ph,d1,d2,d3,iErrFlg);
611e810d 664
665 Double_t outPar[2] = {th,ph}; Double_t g; Double_t f;Int_t flag = 3;
666 gMinuit->Eval(2, &g, f, outPar,flag);
667
668 SetTrkFit(th,ph);
43400d2d 669
611e810d 670 return kTRUE;
43400d2d 671}
672//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
673Double_t AliHMPIDRecon::FunConSect(Double_t *c,Double_t x,Double_t y)
674{
675 return c[0]*x*x+c[1]*y*y+2*c[2]*x*y+2*c[3]*x+2*c[4]*y+1;
676}
677//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
678void AliHMPIDRecon::FunMinEl(Int_t &/* */,Double_t* /* */,Double_t &f,Double_t *par,Int_t /* */)
679{
680 AliHMPIDRecon *pRec=(AliHMPIDRecon*)gMinuit->GetObjectFit();
681 Double_t minFun = 0;
682 Int_t np = pRec->NClu();
683 for(Int_t i=0;i<np;i++) {
684 if(i==pRec->IdxMip()) continue;
685 Double_t el = pRec->FunConSect(par,pRec->XClu(i),pRec->YClu(i));
686 minFun +=el*el;
687 }
688 f = minFun;
689}
690//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
611e810d 691void AliHMPIDRecon::FunMinPhot(Int_t &/* */,Double_t* /* */,Double_t &f,Double_t *par,Int_t iflag)
43400d2d 692{
693 AliHMPIDRecon *pRec=(AliHMPIDRecon*)gMinuit->GetObjectFit();
611e810d 694 Double_t sizeCh = 0.5*fgkRadThick+fgkWinThick+fgkGapThick;
43400d2d 695 Double_t thTrk = par[0];
696 Double_t phTrk = par[1];
697 Double_t xrad = pRec->MipX() - sizeCh*TMath::Tan(thTrk)*TMath::Cos(phTrk);
698 Double_t yrad = pRec->MipY() - sizeCh*TMath::Tan(thTrk)*TMath::Sin(phTrk);
611e810d 699 pRec->SetRadXY(xrad,yrad);
43400d2d 700 pRec->SetTrack(xrad,yrad,thTrk,phTrk);
701
5b2b2013 702 Double_t meanCkov =0;
43400d2d 703 Double_t meanCkov2=0;
704 Double_t thetaCer,phiCer;
5b2b2013 705 Int_t nClAcc = 0;
706 Int_t nClTot=pRec->NClu();
707
708 for(Int_t i=0;i<nClTot;i++) {
709 if(!(pRec->ClCk(i))) continue;
43400d2d 710 pRec->FindPhotCkov(pRec->XClu(i),pRec->YClu(i),thetaCer,phiCer);
43400d2d 711 meanCkov += thetaCer;
712 meanCkov2 += thetaCer*thetaCer;
5b2b2013 713 nClAcc++;
43400d2d 714 }
096ddc3f 715 if(nClAcc==0) {f=999;return;}
5b2b2013 716 meanCkov/=nClAcc;
096ddc3f 717 Double_t rms = (meanCkov2 - meanCkov*meanCkov*nClAcc)/nClAcc;
718 if(rms<0) Printf(" rms2 = %f, strange!!!",rms);
719 rms = TMath::Sqrt(rms);
5b2b2013 720 f = rms/TMath::Sqrt(nClAcc);
611e810d 721
5b2b2013 722
723 if(iflag==3) {
724 Printf("FunMinPhot before: photons candidates %i used %i",nClTot,nClAcc);
725 nClAcc = 0;
726 Double_t meanCkov1=0;
3b49956b 727 Double_t meanCkov2=0;
5b2b2013 728 for(Int_t i=0;i<nClTot;i++) {
729 if(!(pRec->ClCk(i))) continue;
730 pRec->FindPhotCkov(pRec->XClu(i),pRec->YClu(i),thetaCer,phiCer);
731 if(TMath::Abs(thetaCer-meanCkov)<2*rms) {
3b49956b 732 meanCkov1 += thetaCer;
733 meanCkov2 += thetaCer*thetaCer;
5b2b2013 734 nClAcc++;
735 } else pRec->SetClCk(i,kFALSE);
736 }
737 meanCkov1/=nClAcc;
3b49956b 738 Double_t rms2 = (meanCkov2 - meanCkov*meanCkov*nClAcc)/nClAcc;
5b2b2013 739 Printf("FunMinPhot after: photons candidates %i used %i thetaCer %f",nClTot,nClAcc,meanCkov1);
740 pRec->SetCkovFit(meanCkov1);
3b49956b 741 pRec->SetCkovSig2(rms2);
5b2b2013 742 pRec->SetNClu(nClAcc);
743 }
43400d2d 744}//FunMinPhot()
611e810d 745//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
746//
747// ended Hidden track algorithm....
748//
749//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++