bug fixed
[u/mrichter/AliRoot.git] / MUON / AliMUONClusterSplitterMLEM.cxx
CommitLineData
c0a16418 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
a9c259b2 16/* $Id$ */
c0a16418 17
3d1463c8 18//-----------------------------------------------------------------------------
c0a16418 19/// \class AliMUONClusterSplitterMLEM
20///
a9c259b2 21/// Splitter class for the MLEM algorithm. Performs fitting procedure
22/// with up to 3 hit candidates and tries to split clusters if the number
23/// of candidates exceeds 3.
c0a16418 24///
25/// \author Laurent Aphecetche (for the "new" C++ structure) and
26/// Alexander Zinchenko, JINR Dubna, for the hardcore of it ;-)
3d1463c8 27//-----------------------------------------------------------------------------
c0a16418 28
29#include "AliMUONClusterSplitterMLEM.h"
a9c259b2 30#include "AliMUONClusterFinderMLEM.h" // for status flag constants
c0a16418 31
c0a16418 32#include "AliMUONCluster.h"
33#include "AliMUONPad.h"
34#include "AliMUONPad.h"
c0a16418 35#include "AliMUONConstants.h"
36#include "AliMpDEManager.h"
37#include "AliMUONMathieson.h"
38
168e9c4d 39#include "AliMpEncodePair.h"
40
866c3232 41#include "AliLog.h"
42
43#include <TClonesArray.h>
44#include <TH2.h>
45#include <TMath.h>
46#include <TMatrixD.h>
47#include <TObjArray.h>
866c3232 48#include <TRandom.h>
9bbd7f60 49#include <Riostream.h>
866c3232 50
78649106 51/// \cond CLASSIMP
c0a16418 52ClassImp(AliMUONClusterSplitterMLEM)
78649106 53/// \endcond
c0a16418 54
a9c259b2 55//const Double_t AliMUONClusterSplitterMLEM::fgkCouplMin = 1.e-3; // threshold on coupling
56const Double_t AliMUONClusterSplitterMLEM::fgkCouplMin = 1.e-2; // threshold on coupling
c0a16418 57
58//_____________________________________________________________________________
59AliMUONClusterSplitterMLEM::AliMUONClusterSplitterMLEM(Int_t detElemId,
110edb51 60 TObjArray* pixArray,
61 Double_t lowestPixelCharge,
62 Double_t lowestPadCharge,
63 Double_t lowestClusterCharge)
c0a16418 64: TObject(),
bf0d3528 65fPixArray(pixArray),
c0a16418 66fMathieson(0x0),
67fDetElemId(detElemId),
68fNpar(0),
69fQtot(0),
9bbd7f60 70fnCoupled(0),
110edb51 71fDebug(0),
72fLowestPixelCharge(lowestPixelCharge),
73fLowestPadCharge(lowestPadCharge),
74fLowestClusterCharge(lowestClusterCharge)
c0a16418 75{
76 /// Constructor
77
4e51cfd2 78 AliMq::Station12Type stationType = AliMpDEManager::GetStation12Type(fDetElemId);
c0a16418 79
80 Float_t kx3 = AliMUONConstants::SqrtKx3();
81 Float_t ky3 = AliMUONConstants::SqrtKy3();
82 Float_t pitch = AliMUONConstants::Pitch();
83
4e51cfd2 84 if ( stationType == AliMq::kStation1 )
c0a16418 85 {
86 kx3 = AliMUONConstants::SqrtKx3St1();
87 ky3 = AliMUONConstants::SqrtKy3St1();
88 pitch = AliMUONConstants::PitchSt1();
89 }
90
91 fMathieson = new AliMUONMathieson;
92
93 fMathieson->SetPitch(pitch);
94 fMathieson->SetSqrtKx3AndDeriveKx2Kx4(kx3);
95 fMathieson->SetSqrtKy3AndDeriveKy2Ky4(ky3);
96
97}
98
99//_____________________________________________________________________________
100AliMUONClusterSplitterMLEM::~AliMUONClusterSplitterMLEM()
101{
71a2d3aa 102 /// Destructor
103
c0a16418 104 delete fMathieson;
105}
106
107//_____________________________________________________________________________
108void
109AliMUONClusterSplitterMLEM::AddBin(TH2 *mlem,
110 Int_t ic, Int_t jc, Int_t mode,
111 Bool_t *used, TObjArray *pix)
112{
113 /// Add a bin to the cluster
114
115 Int_t nx = mlem->GetNbinsX();
116 Int_t ny = mlem->GetNbinsY();
117 Double_t cont1, cont = mlem->GetCellContent(jc,ic);
118 AliMUONPad *pixPtr = 0;
119
2abdae6e 120 Int_t ie = TMath::Min(ic+1,ny), je = TMath::Min(jc+1,nx);
121 for (Int_t i = TMath::Max(ic-1,1); i <= ie; ++i) {
122 for (Int_t j = TMath::Max(jc-1,1); j <= je; ++j) {
c0a16418 123 if (i != ic && j != jc) continue;
124 if (used[(i-1)*nx+j-1]) continue;
125 cont1 = mlem->GetCellContent(j,i);
126 if (mode && cont1 > cont) continue;
127 used[(i-1)*nx+j-1] = kTRUE;
110edb51 128 if (cont1 < fLowestPixelCharge) continue;
c0a16418 129 if (pix) pix->Add(BinToPix(mlem,j,i));
130 else {
131 pixPtr = new AliMUONPad (mlem->GetXaxis()->GetBinCenter(j),
a9c259b2 132 mlem->GetYaxis()->GetBinCenter(i), 0, 0, cont1);
2abdae6e 133 fPixArray->Add(pixPtr);
c0a16418 134 }
135 AddBin(mlem, i, j, mode, used, pix); // recursive call
136 }
137 }
138}
139
140//_____________________________________________________________________________
141void
142AliMUONClusterSplitterMLEM::AddCluster(Int_t ic, Int_t nclust,
143 TMatrixD& aijcluclu,
144 Bool_t *used, Int_t *clustNumb, Int_t &nCoupled)
145{
146 /// Add a cluster to the group of coupled clusters
147
2abdae6e 148 for (Int_t i = 0; i < nclust; ++i) {
c0a16418 149 if (used[i]) continue;
150 if (aijcluclu(i,ic) < fgkCouplMin) continue;
151 used[i] = kTRUE;
152 clustNumb[nCoupled++] = i;
153 AddCluster(i, nclust, aijcluclu, used, clustNumb, nCoupled);
154 }
155}
156
157//_____________________________________________________________________________
158TObject*
159AliMUONClusterSplitterMLEM::BinToPix(TH2 *mlem,
160 Int_t jc, Int_t ic)
161{
162 /// Translate histogram bin to pixel
163
164 Double_t yc = mlem->GetYaxis()->GetBinCenter(ic);
165 Double_t xc = mlem->GetXaxis()->GetBinCenter(jc);
166
167 Int_t nPix = fPixArray->GetEntriesFast();
168 AliMUONPad *pixPtr = NULL;
169
170 // Compare pixel and bin positions
2abdae6e 171 for (Int_t i = 0; i < nPix; ++i) {
c0a16418 172 pixPtr = (AliMUONPad*) fPixArray->UncheckedAt(i);
110edb51 173 if (pixPtr->Charge() < fLowestPixelCharge) continue;
c0a16418 174 if (TMath::Abs(pixPtr->Coord(0)-xc)<1.e-4 && TMath::Abs(pixPtr->Coord(1)-yc)<1.e-4)
175 {
2abdae6e 176 //return (TObject*) pixPtr;
177 return pixPtr;
c0a16418 178 }
179 }
180 AliError(Form(" Something wrong ??? %f %f ", xc, yc));
181 return NULL;
182}
183
184//_____________________________________________________________________________
185Float_t
186AliMUONClusterSplitterMLEM::ChargeIntegration(Double_t x, Double_t y,
187 const AliMUONPad& pad)
188{
189 /// Compute the Mathieson integral on pad area, assuming the center
190 /// of the Mathieson is at (x,y)
191
192 TVector2 lowerLeft(TVector2(x,y)-pad.Position()-pad.Dimensions());
193 TVector2 upperRight(lowerLeft + pad.Dimensions()*2.0);
194
195 return fMathieson->IntXY(lowerLeft.X(),lowerLeft.Y(),
196 upperRight.X(),upperRight.Y());
197}
198
199//_____________________________________________________________________________
200void
201AliMUONClusterSplitterMLEM::Fcn1(const AliMUONCluster& cluster,
202 Int_t & /*fNpar*/, Double_t * /*gin*/,
a9c259b2 203 Double_t &f, Double_t *par, Int_t iflag)
c0a16418 204{
a9c259b2 205 /// Computes the functional to be minimized
c0a16418 206
207 Int_t indx, npads=0;
208 Double_t charge, delta, coef=0, chi2=0, qTot = 0;
a9c259b2 209 static Double_t qAver = 0;
c0a16418 210
a9c259b2 211 Int_t mult = cluster.Multiplicity(), iend = fNpar / 3;
2abdae6e 212 for (Int_t j = 0; j < mult; ++j)
c0a16418 213 {
214 AliMUONPad* pad = cluster.Pad(j);
a9c259b2 215 //if ( pad->Status() !=1 || pad->IsSaturated() ) continue;
50205ffb 216 if ( pad->Status() != AliMUONClusterFinderMLEM::GetUseForFitFlag() ||
217 pad->Charge() == 0 ) continue;
a9c259b2 218 if (iflag == 0) {
219 if ( pad->IsReal() ) npads++; // exclude virtual pads
220 qTot += pad->Charge();
221 }
c0a16418 222 charge = 0;
a9c259b2 223 for (Int_t i = 0; i <= iend; ++i)
224 {
225 // sum over hits
226 indx = 3 * i;
227 coef = Param2Coef(i, coef, par);
9bbd7f60 228 charge += ChargeIntegration(par[indx],par[indx+1],*pad) * coef;
c0a16418 229 }
230 charge *= fQtot;
a9c259b2 231 delta = charge - pad->Charge();
c0a16418 232 delta *= delta;
a9c259b2 233 delta /= pad->Charge();
c0a16418 234 chi2 += delta;
235 } // for (Int_t j=0;
a9c259b2 236 if (iflag == 0) qAver = qTot / npads;
237 f = chi2 / qAver;
238}
239
240//_____________________________________________________________________________
9ee1d6ff 241Double_t AliMUONClusterSplitterMLEM::Param2Coef(Int_t icand, Double_t coef, Double_t *par) const
a9c259b2 242{
243 /// Extract hit contribution scale factor from fit parameters
244
245 if (fNpar == 2) return 1.;
246 if (fNpar == 5) return icand==0 ? par[2] : TMath::Max(1.-par[2],0.);
247 if (icand == 0) return par[2];
248 if (icand == 1) return TMath::Max((1.-par[2])*par[5], 0.);
249 return TMath::Max(1.-par[2]-coef,0.);
c0a16418 250}
251
252//_____________________________________________________________________________
253Int_t
254AliMUONClusterSplitterMLEM::Fit(const AliMUONCluster& cluster,
255 Int_t iSimple, Int_t nfit,
57e2ad1a 256 const Int_t *clustFit, TObjArray **clusters,
c0a16418 257 Double_t *parOk,
b161da28 258 TObjArray& clusterList, TH2 *mlem)
c0a16418 259{
a9c259b2 260 /// Steering function and fitting procedure for the fit of pad charge distribution
c0a16418 261
262 // AliDebug(2,Form("iSimple=%d nfit=%d",iSimple,nfit));
263
c0a16418 264 Double_t xmin = mlem->GetXaxis()->GetXmin() - mlem->GetXaxis()->GetBinWidth(1);
265 Double_t xmax = mlem->GetXaxis()->GetXmax() + mlem->GetXaxis()->GetBinWidth(1);
266 Double_t ymin = mlem->GetYaxis()->GetXmin() - mlem->GetYaxis()->GetBinWidth(1);
267 Double_t ymax = mlem->GetYaxis()->GetXmax() + mlem->GetYaxis()->GetBinWidth(1);
a9c259b2 268 Double_t xPad = 0, yPad = 99999;
c0a16418 269
270 // Number of pads to use and number of virtual pads
271 Int_t npads = 0, nVirtual = 0, nfit0 = nfit;
9bbd7f60 272 //cluster.Print("full");
2abdae6e 273 Int_t mult = cluster.Multiplicity();
274 for (Int_t i = 0; i < mult; ++i )
c0a16418 275 {
276 AliMUONPad* pad = cluster.Pad(i);
9bbd7f60 277 if ( !pad->IsReal() ) ++nVirtual;
a9c259b2 278 //if ( pad->Status() !=1 || pad->IsSaturated() ) continue;
05542040 279 if ( pad->Status() != AliMUONClusterFinderMLEM::GetUseForFitFlag() ) continue;
9bbd7f60 280 if ( pad->IsReal() )
c0a16418 281 {
282 ++npads;
283 if (yPad > 9999)
284 {
a9c259b2 285 xPad = pad->X();
286 yPad = pad->Y();
c0a16418 287 }
288 else
289 {
a9c259b2 290 if (pad->DY() < pad->DX() )
c0a16418 291 {
a9c259b2 292 yPad = pad->Y();
c0a16418 293 }
294 else
295 {
a9c259b2 296 xPad = pad->X();
c0a16418 297 }
298 }
299 }
300 }
301
302 fNpar = 0;
303 fQtot = 0;
304
305 if (npads < 2) return 0;
306
307 // FIXME : AliWarning("Reconnect the following code for hit/track passing ?");
308
309 // Int_t tracks[3] = {-1, -1, -1};
310
311 /*
312 Int_t digit = 0;
313 AliMUONDigit *mdig = 0;
314 for (Int_t cath=0; cath<2; cath++) {
315 for (Int_t i=0; i<fnPads[0]+fnPads[1]; i++) {
316 if (fPadIJ[0][i] != cath) continue;
317 if (fPadIJ[1][i] != 1) continue;
318 if (fXyq[3][i] < 0) continue; // exclude virtual pads
319 digit = TMath::Nint (fXyq[5][i]);
320 if (digit >= 0) mdig = fInput->Digit(cath,digit);
321 else mdig = fInput->Digit(TMath::Even(cath),-digit-1);
322 //if (!mdig) mdig = fInput->Digit(TMath::Even(cath),digit);
323 if (!mdig) continue; // protection for cluster display
324 if (mdig->Hit() >= 0) {
325 if (tracks[0] < 0) {
326 tracks[0] = mdig->Hit();
327 tracks[1] = mdig->Track(0);
328 } else if (mdig->Track(0) < tracks[1]) {
329 tracks[0] = mdig->Hit();
330 tracks[1] = mdig->Track(0);
331 }
332 }
333 if (mdig->Track(1) >= 0 && mdig->Track(1) != tracks[1]) {
334 if (tracks[2] < 0) tracks[2] = mdig->Track(1);
335 else tracks[2] = TMath::Min (tracks[2], mdig->Track(1));
336 }
337 } // for (Int_t i=0;
338 } // for (Int_t cath=0;
339 */
340
341 // Get number of pads in X and Y
a9c259b2 342 //const Int_t kStatusToTest(1);
05542040 343 const Int_t kStatusToTest(AliMUONClusterFinderMLEM::GetUseForFitFlag());
c0a16418 344
168e9c4d 345 Long_t nofPads = cluster.NofPads(kStatusToTest);
346 Int_t nInX = AliMp::PairFirst(nofPads);
347 Int_t nInY = AliMp::PairSecond(nofPads);
9bbd7f60 348
349 if (fDebug) {
350 Int_t npadOK = 0;
351 for (Int_t j = 0; j < cluster.Multiplicity(); ++j) {
352 AliMUONPad *pad = cluster.Pad(j);
a9c259b2 353 //if (pad->Status() == 1 && !pad->IsSaturated()) npadOK++;
05542040 354 if (pad->Status() == AliMUONClusterFinderMLEM::GetUseForFitFlag() && !pad->IsSaturated()) npadOK++;
9bbd7f60 355 }
356 cout << " Number of pads to fit: " << npadOK << endl;
357 cout << " nInX and Y: " << nInX << " " << nInY << endl;
358 }
c0a16418 359
360 Int_t nfitMax = 3;
361 nfitMax = TMath::Min (nfitMax, (npads + 1) / 3);
362 if (nfitMax > 1) {
94bf739c 363 if (((nInX < 3) && (nInY < 3)) || ((nInX == 3) && (nInY < 3)) || ((nInX < 3) && (nInY == 3))) nfitMax = 1; // not enough pads in each direction
c0a16418 364 }
365 if (nfit > nfitMax) nfit = nfitMax;
366
367 // Take cluster maxima as fitting seeds
368 TObjArray *pix;
369 AliMUONPad *pixPtr;
370 Int_t npxclu;
371 Double_t cont, cmax = 0, xseed = 0, yseed = 0, errOk[8], qq = 0;
8c14ac2e 372
373 for ( int i = 0; i < 8; ++i ) errOk[i]=0.0;
374
c0a16418 375 Double_t xyseed[3][2], qseed[3], xyCand[3][2] = {{0},{0}}, sigCand[3][2] = {{0},{0}};
376
2abdae6e 377 for (Int_t ifit = 1; ifit <= nfit0; ++ifit)
c0a16418 378 {
379 cmax = 0;
380 pix = clusters[clustFit[ifit-1]];
381 npxclu = pix->GetEntriesFast();
382 //qq = 0;
2abdae6e 383 for (Int_t clu = 0; clu < npxclu; ++clu)
c0a16418 384 {
385 pixPtr = (AliMUONPad*) pix->UncheckedAt(clu);
386 cont = pixPtr->Charge();
387 fQtot += cont;
388 if (cont > cmax)
389 {
390 cmax = cont;
391 xseed = pixPtr->Coord(0);
392 yseed = pixPtr->Coord(1);
393 }
394 qq += cont;
395 xyCand[0][0] += pixPtr->Coord(0) * cont;
396 xyCand[0][1] += pixPtr->Coord(1) * cont;
397 sigCand[0][0] += pixPtr->Coord(0) * pixPtr->Coord(0) * cont;
398 sigCand[0][1] += pixPtr->Coord(1) * pixPtr->Coord(1) * cont;
399 }
400 xyseed[ifit-1][0] = xseed;
401 xyseed[ifit-1][1] = yseed;
402 qseed[ifit-1] = cmax;
403 } // for (Int_t ifit=1;
404
405 xyCand[0][0] /= qq; // <x>
406 xyCand[0][1] /= qq; // <y>
407 sigCand[0][0] = sigCand[0][0]/qq - xyCand[0][0]*xyCand[0][0]; // <x^2> - <x>^2
408 sigCand[0][0] = sigCand[0][0] > 0 ? TMath::Sqrt (sigCand[0][0]) : 0;
409 sigCand[0][1] = sigCand[0][1]/qq - xyCand[0][1]*xyCand[0][1]; // <y^2> - <y>^2
410 sigCand[0][1] = sigCand[0][1] > 0 ? TMath::Sqrt (sigCand[0][1]) : 0;
9bbd7f60 411 if (fDebug) cout << xyCand[0][0] << " " << xyCand[0][1] << " " << sigCand[0][0] << " " << sigCand[0][1] << endl;
c0a16418 412
413 Int_t nDof, maxSeed[3];//, nMax = 0;
1e875d50 414
415 if ( nfit0 < 0 || nfit0 > 3 ) {
416 AliErrorStream() << "Wrong nfit0 value: " << nfit0 << endl;
417 return nfit;
418 }
a9c259b2 419 TMath::Sort(nfit0, qseed, maxSeed, kTRUE); // in decreasing order
c0a16418 420
a9c259b2 421 Double_t step[3]={0.01,0.002,0.02}, fmin, chi2o = 9999, chi2n;
422 Double_t *gin = 0, func0, func1, param[8], step0[8];
423 Double_t param0[2][8]={{0},{0}}, deriv[2][8]={{0},{0}};
424 Double_t shift[8], stepMax, derMax, parmin[8], parmax[8], func2[2], shift0;
425 Double_t delta[8], scMax, dder[8], estim, shiftSave = 0;
426 Int_t min, max, nCall = 0, nLoop, idMax = 0, iestMax = 0, nFail;
427 Double_t rad, dist[3] = {0};
c0a16418 428
a9c259b2 429 // Try to fit with one-track hypothesis, then 2-track. If chi2/dof is
430 // lower, try 3-track (if number of pads is sufficient).
431 Int_t iflag = 0; // for the first call of fcn1
432 for (Int_t iseed = 0; iseed < nfit; ++iseed)
433 {
c0a16418 434
a9c259b2 435 Int_t memory[8] = {0};
436 if (iseed)
437 {
438 for (Int_t j = 0; j < fNpar; ++j)
c0a16418 439 {
a9c259b2 440 param[j] = parOk[j];
c0a16418 441 }
a9c259b2 442 param[fNpar] = 0.6;
443 parmin[fNpar] = 0;
444 parmax[fNpar++] = 1;
445 }
c0a16418 446
a9c259b2 447 if (nfit == 1)
448 {
449 param[fNpar] = xyCand[0][0]; // take COG
450 }
451 else
452 {
453 param[fNpar] = xyseed[maxSeed[iseed]][0];
454 //param[fNpar] = fNpar==0 ? -16.1651 : -15.2761;
455 }
456 parmin[fNpar] = xmin;
457 parmax[fNpar++] = xmax;
458 if (nfit == 1)
459 {
460 param[fNpar] = xyCand[0][1]; // take COG
461 }
462 else
463 {
464 param[fNpar] = xyseed[maxSeed[iseed]][1];
465 //param[fNpar] = fNpar==1 ? -15.1737 : -15.8487;
466 }
467 parmin[fNpar] = ymin;
468 parmax[fNpar++] = ymax;
469
470 for (Int_t j = 0; j < fNpar; ++j)
471 {
472 step0[j] = shift[j] = step[j%3];
473 }
474
475 if (iseed)
476 {
477 for (Int_t j = 0; j < fNpar; ++j)
c0a16418 478 {
a9c259b2 479 param0[1][j] = 0;
2abdae6e 480 }
a9c259b2 481 }
482 if (fDebug) {
483 for (Int_t j = 0; j < fNpar; ++j) cout << param[j] << " ";
484 cout << endl;
485 }
c0a16418 486
a9c259b2 487 // Try new algorithm
488 min = nLoop = 1; stepMax = func2[1] = derMax = 999999; nFail = 0;
489
490 while (1)
491 {
492 max = !min;
493 Fcn1(cluster,fNpar, gin, func0, param, iflag); nCall++;
494 iflag = 1;
495 //cout << " Func: " << func0 << endl;
c0a16418 496
a9c259b2 497 func2[max] = func0;
498 for (Int_t j = 0; j < fNpar; ++j)
c0a16418 499 {
a9c259b2 500 param0[max][j] = param[j];
501 delta[j] = step0[j];
502 param[j] += delta[j] / 10;
503 if (j > 0) param[j-1] -= delta[j-1] / 10;
504 Fcn1(cluster,fNpar, gin, func1, param, iflag); nCall++;
505 deriv[max][j] = (func1 - func0) / delta[j] * 10; // first derivative
506 //cout << j << " " << deriv[max][j] << endl;
507 dder[j] = param0[0][j] != param0[1][j] ? (deriv[0][j] - deriv[1][j]) /
508 (param0[0][j] - param0[1][j]) : 0; // second derivative
509 }
510 param[fNpar-1] -= delta[fNpar-1] / 10;
511 if (nCall > 2000) break;
c0a16418 512
a9c259b2 513 min = func2[0] < func2[1] ? 0 : 1;
514 nFail = min == max ? 0 : nFail + 1;
c0a16418 515
a9c259b2 516 stepMax = derMax = estim = 0;
517 for (Int_t j = 0; j < fNpar; ++j)
518 {
519 // Estimated distance to minimum
520 shift0 = shift[j];
521 if (nLoop == 1)
522 {
523 shift[j] = TMath::Sign (step0[j], -deriv[max][j]); // first step
524 }
525 else if (TMath::Abs(deriv[0][j]) < 1.e-3 && TMath::Abs(deriv[1][j]) < 1.e-3)
526 {
527 shift[j] = 0;
528 }
94bf739c 529 else if (((deriv[min][j]*deriv[!min][j] > 0) && (TMath::Abs(deriv[min][j]) > TMath::Abs(deriv[!min][j])))
530 || (TMath::Abs(deriv[0][j]-deriv[1][j]) < 1.e-3) || (TMath::Abs(dder[j]) < 1.e-6))
a9c259b2 531 {
532 shift[j] = -TMath::Sign (shift[j], (func2[0]-func2[1]) * (param0[0][j]-param0[1][j]));
533 if (min == max)
534 {
535 if (memory[j] > 1)
9bbd7f60 536 {
a9c259b2 537 shift[j] *= 2;
538 }
539 memory[j]++;
9bbd7f60 540 }
a9c259b2 541 }
542 else
543 {
544 shift[j] = dder[j] != 0 ? -deriv[min][j] / dder[j] : 0;
545 memory[j] = 0;
546 }
c0a16418 547
a9c259b2 548 Double_t es = TMath::Abs(shift[j]) / step0[j];
549 if (es > estim)
550 {
551 estim = es;
552 iestMax = j;
553 }
c0a16418 554
a9c259b2 555 // Too big step
556 if (TMath::Abs(shift[j])/step0[j] > 10) shift[j] = TMath::Sign(10.,shift[j]) * step0[j]; //
557
558 // Failed to improve minimum
559 if (min != max)
560 {
561 memory[j] = 0;
562 param[j] = param0[min][j];
563 if (TMath::Abs(shift[j]+shift0) > 0.1*step0[j])
c0a16418 564 {
a9c259b2 565 shift[j] = (shift[j] + shift0) / 2;
566 }
567 else
c0a16418 568 {
a9c259b2 569 shift[j] /= -2;
570 }
571 }
c0a16418 572
a9c259b2 573 // Too big step
574 if (TMath::Abs(shift[j]*deriv[min][j]) > func2[min])
575 {
576 shift[j] = TMath::Sign (func2[min]/deriv[min][j], shift[j]);
577 }
578
579 // Introduce step relaxation factor
580 if (memory[j] < 3)
581 {
582 scMax = 1 + 4 / TMath::Max(nLoop/2.,1.);
583 if (TMath::Abs(shift0) > 0 && TMath::Abs(shift[j]/shift0) > scMax)
c0a16418 584 {
a9c259b2 585 shift[j] = TMath::Sign (shift0*scMax, shift[j]);
586 }
587 }
588 param[j] += shift[j];
589 // Check parameter limits
590 if (param[j] < parmin[j])
591 {
592 shift[j] = parmin[j] - param[j];
593 param[j] = parmin[j];
594 }
595 else if (param[j] > parmax[j])
596 {
597 shift[j] = parmax[j] - param[j];
598 param[j] = parmax[j];
599 }
600 //cout << " xxx " << j << " " << shift[j] << " " << param[j] << endl;
601 stepMax = TMath::Max (stepMax, TMath::Abs(shift[j]/step0[j]));
602 if (TMath::Abs(deriv[min][j]) > derMax)
603 {
604 idMax = j;
605 derMax = TMath::Abs (deriv[min][j]);
606 }
607 } // for (Int_t j=0; j<fNpar;
c0a16418 608
94bf739c 609 if (((estim < 1) && (derMax < 2)) || nLoop > 150) break; // minimum was found
c0a16418 610
a9c259b2 611 nLoop++;
c0a16418 612
a9c259b2 613 // Check for small step
614 if (shift[idMax] == 0)
615 {
616 shift[idMax] = step0[idMax]/10;
617 param[idMax] += shift[idMax];
618 continue;
619 }
c0a16418 620
a9c259b2 621 if (!memory[idMax] && derMax > 0.5 && nLoop > 10)
622 {
623 if (dder[idMax] != 0 && TMath::Abs(deriv[min][idMax]/dder[idMax]/shift[idMax]) > 10)
c0a16418 624 {
a9c259b2 625 if (min == max) dder[idMax] = -dder[idMax];
626 shift[idMax] = -deriv[min][idMax] / dder[idMax] / 10;
627 param[idMax] += shift[idMax];
628 stepMax = TMath::Max (stepMax, TMath::Abs(shift[idMax])/step0[idMax]);
629 if (min == max) shiftSave = shift[idMax];
630 }
631 if (nFail > 10)
632 {
633 param[idMax] -= shift[idMax];
634 shift[idMax] = 4 * shiftSave * (gRandom->Rndm(0) - 0.5);
635 param[idMax] += shift[idMax];
636 }
637 }
638 } // while (1)
c0a16418 639
a9c259b2 640 fmin = func2[min];
641
642 nDof = npads - fNpar + nVirtual;
643 if (!nDof) nDof++;
644 chi2n = fmin / nDof;
645 if (fDebug) cout << " Chi2 " << chi2n << " " << fNpar << endl;
c0a16418 646
a9c259b2 647 //if (fNpar > 2) cout << param0[min][fNpar-3] << " " << chi2n * (1+TMath::Min(1-param0[min][fNpar-3],0.25)) << endl;
648 //if (chi2n*1.2+1.e-6 > chi2o )
94bf739c 649 if (fNpar > 2 && (chi2n > chi2o || ((iseed == nfit-1)
650 && (chi2n * (1+TMath::Min(1-param0[min][fNpar-3],0.25)) > chi2o))))
a9c259b2 651 { fNpar -= 3; break; }
c0a16418 652
a9c259b2 653 // Save parameters and errors
c0a16418 654
a9c259b2 655 if (nInX == 1) {
656 // One pad per direction
657 //for (Int_t i=0; i<fNpar; ++i) if (i == 0 || i == 2 || i == 5) param0[min][i] = xPad;
658 for (Int_t i=0; i<fNpar; ++i) if (i == 0 || i == 2 || i == 5)
659 param0[min][i] = xyCand[0][0];
660 }
661 if (nInY == 1) {
662 // One pad per direction
663 //for (Int_t i=0; i<fNpar; ++i) if (i == 1 || i == 3 || i == 6) param0[min][i] = yPad;
664 for (Int_t i=0; i<fNpar; ++i) if (i == 1 || i == 3 || i == 6)
665 param0[min][i] = xyCand[0][1];
666 }
c0a16418 667
a9c259b2 668 /*
669 if (iseed > 0) {
670 // Find distance to the nearest neighbour
671 dist[0] = dist[1] = TMath::Sqrt ((param0[min][0]-param0[min][2])*
672 (param0[min][0]-param0[min][2])
673 +(param0[min][1]-param0[min][3])*
674 (param0[min][1]-param0[min][3]));
675 if (iseed > 1) {
676 dist[2] = TMath::Sqrt ((param0[min][0]-param0[min][5])*
677 (param0[min][0]-param0[min][5])
678 +(param0[min][1]-param0[min][6])*
679 (param0[min][1]-param0[min][6]));
680 rad = TMath::Sqrt ((param0[min][2]-param0[min][5])*
681 (param0[min][2]-param0[min][5])
682 +(param0[min][3]-param0[min][6])*
683 (param0[min][3]-param0[min][6]));
684 if (dist[2] < dist[0]) dist[0] = dist[2];
685 if (rad < dist[1]) dist[1] = rad;
686 if (rad < dist[2]) dist[2] = rad;
c0a16418 687 }
a9c259b2 688 cout << dist[0] << " " << dist[1] << " " << dist[2] << endl;
689 if (dist[TMath::LocMin(iseed+1,dist)] < 1.) { fNpar -= 3; break; }
c0a16418 690 }
a9c259b2 691 */
c0a16418 692
a9c259b2 693 for (Int_t i = 0; i < fNpar; ++i) {
694 parOk[i] = param0[min][i];
695 //errOk[i] = fmin;
696 errOk[i] = chi2n;
697 // Bounded params
698 parOk[i] = TMath::Max (parOk[i], parmin[i]);
699 parOk[i] = TMath::Min (parOk[i], parmax[i]);
700 }
c0a16418 701
a9c259b2 702 chi2o = chi2n;
703 if (fmin < 0.1) break; // !!!???
704 } // for (Int_t iseed=0;
9bbd7f60 705
a9c259b2 706 if (fDebug) {
707 for (Int_t i=0; i<fNpar; ++i) {
708 if (i == 4 || i == 7) {
94bf739c 709 if ((i == 7) || ((i == 4) && (fNpar < 7))) cout << parOk[i] << endl;
a9c259b2 710 else cout << parOk[i] * (1-parOk[7]) << endl;
711 continue;
9bbd7f60 712 }
a9c259b2 713 cout << parOk[i] << " " << errOk[i] << endl;
9bbd7f60 714 }
a9c259b2 715 }
716 nfit = (fNpar + 1) / 3;
717 dist[0] = dist[1] = dist[2] = 0;
718
719 if (nfit > 1) {
720 // Find distance to the nearest neighbour
721 dist[0] = dist[1] = TMath::Sqrt ((parOk[0]-parOk[2])*
722 (parOk[0]-parOk[2])
723 +(parOk[1]-parOk[3])*
724 (parOk[1]-parOk[3]));
725 if (nfit > 2) {
726 dist[2] = TMath::Sqrt ((parOk[0]-parOk[5])*
727 (parOk[0]-parOk[5])
728 +(parOk[1]-parOk[6])*
729 (parOk[1]-parOk[6]));
730 rad = TMath::Sqrt ((parOk[2]-parOk[5])*
731 (parOk[2]-parOk[5])
732 +(parOk[3]-parOk[6])*
733 (parOk[3]-parOk[6]));
734 if (dist[2] < dist[0]) dist[0] = dist[2];
735 if (rad < dist[1]) dist[1] = rad;
736 if (rad < dist[2]) dist[2] = rad;
c0a16418 737 }
a9c259b2 738 }
c0a16418 739
a9c259b2 740 Int_t indx;
741
742 Double_t coef = 0;
743 if (iSimple) fnCoupled = 0;
744 for (Int_t j = 0; j < nfit; ++j) {
745 indx = 3 * j;
746 coef = Param2Coef(j, coef, parOk);
747
748 //void AliMUONClusterFinderMLEM::AddRawCluster(Double_t x, Double_t y,
749 // Double_t qTot, Double_t fmin,
750 // Int_t nfit, Int_t *tracks,
751 // Double_t /*sigx*/,
752 // Double_t /*sigy*/,
753 // Double_t /*dist*/)
c0a16418 754
110edb51 755 if ( coef*fQtot >= fLowestClusterCharge )
a9c259b2 756 {
757 //AZ AliMUONCluster* cluster1 = new AliMUONCluster();
758 AliMUONCluster* cluster1 = new AliMUONCluster(cluster);
c0a16418 759
a9c259b2 760 cluster1->SetCharge(coef*fQtot,coef*fQtot);
761 cluster1->SetPosition(TVector2(parOk[indx],parOk[indx+1]),TVector2(sigCand[0][0],sigCand[0][1]));
ad30b53f 762 //cluster1->SetChi2(dist[TMath::LocMin(nfit,dist)]);
763 Int_t idx = TMath::LocMin(nfit,dist);
764 if ( idx < 0 || idx > 2 ) {
765 AliErrorStream() << "Wrong index value: " << idx << endl;
766 return nfit;
767 }
768 cluster1->SetChi2(dist[idx]);
c0a16418 769
a9c259b2 770 // FIXME: we miss some information in this cluster, as compared to
771 // the original AddRawCluster code.
772
773 AliDebug(2,Form("Adding RawCluster detElemId %4d mult %2d charge %5d (xl,yl)=(%9.6g,%9.6g)",
774 fDetElemId,cluster1->Multiplicity(),(Int_t)cluster1->Charge(),
775 cluster1->Position().X(),cluster1->Position().Y()));
c0a16418 776
a9c259b2 777 clusterList.Add(cluster1);
c0a16418 778 }
a9c259b2 779 // AddRawCluster (parOk[indx], // double x
780 // parOk[indx+1], // double y
781 // coef*qTot, // double charge
782 // errOk[indx], // double fmin
783 // nfit0+10*nfit+100*nMax+10000*fnCoupled, // int nfit
784 // tracks, // int* tracks
785 // sigCand[0][0], // double sigx
786 // sigCand[0][1], // double sigy
787 // dist[TMath::LocMin(nfit,dist)] // double dist
788 // );
789 }
790 return nfit;
791}
c0a16418 792
793
794//_____________________________________________________________________________
795void
796AliMUONClusterSplitterMLEM::Split(const AliMUONCluster& cluster,
a9c259b2 797 TH2 *mlem, Double_t *coef,
c0a16418 798 TObjArray& clusterList)
799{
800 /// The main steering function to work with clusters of pixels in anode
801 /// plane (find clusters, decouple them from each other, merge them (if
802 /// necessary), pick up coupled pads, call the fitting function)
803
804 Int_t nx = mlem->GetNbinsX();
805 Int_t ny = mlem->GetNbinsY();
806 Int_t nPix = fPixArray->GetEntriesFast();
807
c0a16418 808 Double_t cont;
a9c259b2 809 Int_t nclust = 0, indx, indx1, nxy = ny * nx;
810 Bool_t *used = new Bool_t[nxy];
c0a16418 811
a9c259b2 812 for (Int_t j = 0; j < nxy; ++j) used[j] = kFALSE;
c0a16418 813
814 TObjArray *clusters[200]={0};
815 TObjArray *pix;
816
817 // Find clusters of histogram bins (easier to work in 2-D space)
2abdae6e 818 for (Int_t i = 1; i <= ny; ++i)
c0a16418 819 {
2abdae6e 820 for (Int_t j = 1; j <= nx; ++j)
c0a16418 821 {
822 indx = (i-1)*nx + j - 1;
823 if (used[indx]) continue;
824 cont = mlem->GetCellContent(j,i);
110edb51 825 if (cont < fLowestPixelCharge) continue;
c0a16418 826 pix = new TObjArray(20);
827 used[indx] = 1;
828 pix->Add(BinToPix(mlem,j,i));
829 AddBin(mlem, i, j, 0, used, pix); // recursive call
830 if (nclust >= 200) AliFatal(" Too many clusters !!!");
831 clusters[nclust++] = pix;
832 } // for (Int_t j=1; j<=nx; j++) {
a9c259b2 833 } // for (Int_t i=1; i<=ny;
834 if (fDebug) cout << nclust << endl;
2abdae6e 835 delete [] used;
c0a16418 836
837 // Compute couplings between clusters and clusters to pads
838 Int_t npad = cluster.Multiplicity();
839
840 // Exclude pads with overflows
a9c259b2 841 /*
2abdae6e 842 for (Int_t j = 0; j < npad; ++j)
c0a16418 843 {
844 AliMUONPad* pad = cluster.Pad(j);
845 if ( pad->IsSaturated() )
846 {
847 pad->SetStatus(-5);
848 }
849 else
850 {
851 pad->SetStatus(0);
852 }
853 }
a9c259b2 854 */
c0a16418 855
a9c259b2 856 // Compute couplings of clusters to pads (including overflows)
c0a16418 857 TMatrixD aijclupad(nclust,npad);
858 aijclupad = 0;
859 Int_t npxclu;
2abdae6e 860 for (Int_t iclust = 0; iclust < nclust; ++iclust)
c0a16418 861 {
862 pix = clusters[iclust];
863 npxclu = pix->GetEntriesFast();
2abdae6e 864 for (Int_t i = 0; i < npxclu; ++i)
c0a16418 865 {
866 indx = fPixArray->IndexOf(pix->UncheckedAt(i));
2abdae6e 867 for (Int_t j = 0; j < npad; ++j)
c0a16418 868 {
a9c259b2 869 //AliMUONPad* pad = cluster.Pad(j);
870 //if ( pad->Status() < 0 && pad->Status() != -5) continue;
c0a16418 871 if (coef[j*nPix+indx] < fgkCouplMin) continue;
872 aijclupad(iclust,j) += coef[j*nPix+indx];
873 }
874 }
875 }
876
a9c259b2 877 // Compute couplings between clusters (exclude overflows)
c0a16418 878 TMatrixD aijcluclu(nclust,nclust);
879 aijcluclu = 0;
2abdae6e 880 for (Int_t iclust = 0; iclust < nclust; ++iclust)
c0a16418 881 {
2abdae6e 882 for (Int_t j = 0; j < npad; ++j)
c0a16418 883 {
884 // Exclude overflows
a9c259b2 885 //if ( cluster.Pad(j)->Status() < 0) continue;
886 if ( cluster.Pad(j)->IsSaturated()) continue;
c0a16418 887 if (aijclupad(iclust,j) < fgkCouplMin) continue;
888 for (Int_t iclust1=iclust+1; iclust1<nclust; iclust1++)
889 {
890 if (aijclupad(iclust1,j) < fgkCouplMin) continue;
891 aijcluclu(iclust,iclust1) +=
892 TMath::Sqrt (aijclupad(iclust,j)*aijclupad(iclust1,j));
893 }
894 }
895 }
2abdae6e 896 for (Int_t iclust = 0; iclust < nclust; ++iclust)
c0a16418 897 {
2abdae6e 898 for (Int_t iclust1 = iclust+1; iclust1 < nclust; ++iclust1)
c0a16418 899 {
900 aijcluclu(iclust1,iclust) = aijcluclu(iclust,iclust1);
901 }
902 }
903
2abdae6e 904 if (fDebug && nclust > 1) aijcluclu.Print();
905
c0a16418 906 // Find groups of coupled clusters
907 used = new Bool_t[nclust];
a9c259b2 908 for (Int_t j = 0; j < nclust; ++j) used[j] = kFALSE;
2abdae6e 909
c0a16418 910 Int_t *clustNumb = new Int_t[nclust];
911 Int_t nCoupled, nForFit, minGroup[3], clustFit[3], nfit = 0;
2abdae6e 912 //Double_t parOk[8];
913 Double_t parOk[8] = {0}; //AZ
c0a16418 914
2abdae6e 915 for (Int_t igroup = 0; igroup < nclust; ++igroup)
c0a16418 916 {
917 if (used[igroup]) continue;
918 used[igroup] = kTRUE;
919 clustNumb[0] = igroup;
920 nCoupled = 1;
921 // Find group of coupled clusters
922 AddCluster(igroup, nclust, aijcluclu, used, clustNumb, nCoupled); // recursive
923
2abdae6e 924 if (fDebug) {
925 cout << " nCoupled: " << nCoupled << endl;
926 for (Int_t i=0; i<nCoupled; ++i) cout << clustNumb[i] << " "; cout << endl;
927 }
c0a16418 928
929 fnCoupled = nCoupled;
930
931 while (nCoupled > 0)
932 {
933 if (nCoupled < 4)
934 {
935 nForFit = nCoupled;
2abdae6e 936 for (Int_t i = 0; i < nCoupled; ++i) clustFit[i] = clustNumb[i];
c0a16418 937 }
938 else
939 {
940 // Too many coupled clusters to fit - try to decouple them
941 // Find the lowest coupling of 1, 2, min(3,nLinks/2) pixels with
942 // all the others in the group
2abdae6e 943 for (Int_t j = 0; j < 3; ++j) minGroup[j] = -1;
944 Double_t coupl = MinGroupCoupl(nCoupled, clustNumb, aijcluclu, minGroup);
c0a16418 945
946 // Flag clusters for fit
947 nForFit = 0;
948 while (minGroup[nForFit] >= 0 && nForFit < 3)
949 {
2abdae6e 950 if (fDebug) cout << clustNumb[minGroup[nForFit]] << " ";
c0a16418 951 clustFit[nForFit] = clustNumb[minGroup[nForFit]];
952 clustNumb[minGroup[nForFit]] -= 999;
953 nForFit++;
954 }
2abdae6e 955 if (fDebug) cout << " nForFit " << nForFit << " " << coupl << endl;
c0a16418 956 } // else
957
958 // Select pads for fit.
959 if (SelectPad(cluster,nCoupled, nForFit, clustNumb, clustFit, aijclupad) < 3 && nCoupled > 1)
960 {
961 // Deselect pads
2abdae6e 962 for (Int_t j = 0; j < npad; ++j)
c0a16418 963 {
964 AliMUONPad* pad = cluster.Pad(j);
a9c259b2 965 //if ( pad->Status()==1 ) pad->SetStatus(0);
966 //if ( pad->Status()==-9) pad->SetStatus(-5);
05542040 967 if ( pad->Status() == AliMUONClusterFinderMLEM::GetUseForFitFlag() ||
968 pad->Status() == AliMUONClusterFinderMLEM::GetCoupledFlag())
969 pad->SetStatus(AliMUONClusterFinderMLEM::GetZeroFlag());
c0a16418 970 }
971 // Merge the failed cluster candidates (with too few pads to fit) with
972 // the one with the strongest coupling
973 Merge(cluster,nForFit, nCoupled, clustNumb, clustFit, clusters, aijcluclu, aijclupad);
974 }
975 else
976 {
977 // Do the fit
b161da28 978 nfit = Fit(cluster,0, nForFit, clustFit, clusters, parOk, clusterList, mlem);
2abdae6e 979 if (nfit == 0) {
a9c259b2 980 //cout << " (nfit == 0) " << fNpar << " " << cluster.Multiplicity() << endl;
981 fNpar = 0; // should be 0 by itself but just in case ...
2abdae6e 982 }
c0a16418 983 }
984
985 // Subtract the fitted charges from pads with strong coupling and/or
986 // return pads for further use
987 UpdatePads(cluster,nfit, parOk);
988
989 // Mark used pads
2abdae6e 990 for (Int_t j = 0; j < npad; ++j)
c0a16418 991 {
992 AliMUONPad* pad = cluster.Pad(j);
a9c259b2 993 //if ( pad->Status()==1 ) pad->SetStatus(-2);
994 //if ( pad->Status()==-9) pad->SetStatus(-5);
05542040 995 if ( pad->Status() == AliMUONClusterFinderMLEM::GetUseForFitFlag() )
996 pad->SetStatus(AliMUONClusterFinderMLEM::GetModifiedFlag());
c0a16418 997 }
998
999 // Sort the clusters (move to the right the used ones)
1000 Int_t beg = 0, end = nCoupled - 1;
1001 while (beg < end)
1002 {
1003 if (clustNumb[beg] >= 0) { ++beg; continue; }
2abdae6e 1004 for (Int_t j = end; j > beg; --j)
c0a16418 1005 {
1006 if (clustNumb[j] < 0) continue;
1007 end = j - 1;
1008 indx = clustNumb[beg];
1009 clustNumb[beg] = clustNumb[j];
1010 clustNumb[j] = indx;
1011 break;
1012 }
1013 ++beg;
1014 }
1015
1016 nCoupled -= nForFit;
1017 if (nCoupled > 3)
1018 {
1019 // Remove couplings of used clusters
2abdae6e 1020 for (Int_t iclust = nCoupled; iclust < nCoupled+nForFit; ++iclust)
c0a16418 1021 {
1022 indx = clustNumb[iclust] + 999;
2abdae6e 1023 for (Int_t iclust1 = 0; iclust1 < nCoupled; ++iclust1)
c0a16418 1024 {
1025 indx1 = clustNumb[iclust1];
1026 aijcluclu(indx,indx1) = aijcluclu(indx1,indx) = 0;
1027 }
1028 }
1029
a9c259b2 1030 // Update the remaining clusters couplings (subtract couplings from
1031 // the used pads) - overflows excluded
2abdae6e 1032 for (Int_t j = 0; j < npad; ++j)
c0a16418 1033 {
1034 AliMUONPad* pad = cluster.Pad(j);
a9c259b2 1035 //if ( pad->Status() != -2) continue;
05542040 1036 if ( pad->Status() != AliMUONClusterFinderMLEM::GetModifiedFlag()) continue;
c0a16418 1037 for (Int_t iclust=0; iclust<nCoupled; ++iclust)
1038 {
1039 indx = clustNumb[iclust];
1040 if (aijclupad(indx,j) < fgkCouplMin) continue;
2abdae6e 1041 for (Int_t iclust1 = iclust+1; iclust1 < nCoupled; ++iclust1)
c0a16418 1042 {
1043 indx1 = clustNumb[iclust1];
1044 if (aijclupad(indx1,j) < fgkCouplMin) continue;
1045 // Check this
1046 aijcluclu(indx,indx1) -=
1047 TMath::Sqrt (aijclupad(indx,j)*aijclupad(indx1,j));
1048 aijcluclu(indx1,indx) = aijcluclu(indx,indx1);
1049 }
1050 }
a9c259b2 1051 //pad->SetStatus(-8);
05542040 1052 pad->SetStatus(AliMUONClusterFinderMLEM::GetOverFlag());
c0a16418 1053 } // for (Int_t j=0; j<npad;
1054 } // if (nCoupled > 3)
1055 } // while (nCoupled > 0)
1056 } // for (Int_t igroup=0; igroup<nclust;
1057
2abdae6e 1058 for (Int_t iclust = 0; iclust < nclust; ++iclust)
c0a16418 1059 {
1060 pix = clusters[iclust];
1061 pix->Clear();
1062 delete pix;
c0a16418 1063 }
1064 delete [] clustNumb;
c0a16418 1065 delete [] used;
c0a16418 1066
1067}
1068
1069//_____________________________________________________________________________
1070void
1071AliMUONClusterSplitterMLEM::Merge(const AliMUONCluster& cluster,
1072 Int_t nForFit, Int_t nCoupled,
57e2ad1a 1073 const Int_t *clustNumb, const Int_t *clustFit,
c0a16418 1074 TObjArray **clusters,
1075 TMatrixD& aijcluclu, TMatrixD& aijclupad)
1076{
1077 /// Merge the group of clusters with the one having the strongest coupling with them
1078
1079 Int_t indx, indx1, npxclu, npxclu1, imax=0;
1080 TObjArray *pix, *pix1;
1081 Double_t couplMax;
1082
2abdae6e 1083 for (Int_t icl = 0; icl < nForFit; ++icl)
c0a16418 1084 {
1085 indx = clustFit[icl];
1086 pix = clusters[indx];
1087 npxclu = pix->GetEntriesFast();
1088 couplMax = -1;
2abdae6e 1089 for (Int_t icl1 = 0; icl1 < nCoupled; ++icl1)
c0a16418 1090 {
1091 indx1 = clustNumb[icl1];
1092 if (indx1 < 0) continue;
1093 if ( aijcluclu(indx,indx1) > couplMax)
1094 {
1095 couplMax = aijcluclu(indx,indx1);
1096 imax = indx1;
1097 }
1098 } // for (Int_t icl1=0;
1099 // Add to it
1100 pix1 = clusters[imax];
1101 npxclu1 = pix1->GetEntriesFast();
1102 // Add pixels
2abdae6e 1103 for (Int_t i = 0; i < npxclu; ++i)
c0a16418 1104 {
1105 pix1->Add(pix->UncheckedAt(i));
1106 pix->RemoveAt(i);
1107 }
1108
1109 //Add cluster-to-cluster couplings
2abdae6e 1110 for (Int_t icl1 = 0; icl1 < nCoupled; ++icl1)
c0a16418 1111 {
1112 indx1 = clustNumb[icl1];
1113 if (indx1 < 0 || indx1 == imax) continue;
1114 aijcluclu(indx1,imax) += aijcluclu(indx,indx1);
1115 aijcluclu(imax,indx1) = aijcluclu(indx1,imax);
1116 }
1117 aijcluclu(indx,imax) = aijcluclu(imax,indx) = 0;
1118
1119 //Add cluster-to-pad couplings
2abdae6e 1120 Int_t mult = cluster.Multiplicity();
1121 for (Int_t j = 0; j < mult; ++j)
c0a16418 1122 {
1123 AliMUONPad* pad = cluster.Pad(j);
a9c259b2 1124 //if ( pad->Status() < 0 && pad->Status() != -5 ) continue;// exclude used pads
05542040 1125 if ( pad->Status() != AliMUONClusterFinderMLEM::GetZeroFlag()) continue;// exclude used pads
c0a16418 1126 aijclupad(imax,j) += aijclupad(indx,j);
1127 aijclupad(indx,j) = 0;
1128 }
1129 } // for (Int_t icl=0; icl<nForFit;
1130}
1131
1132
1133//_____________________________________________________________________________
1134Double_t
57e2ad1a 1135AliMUONClusterSplitterMLEM::MinGroupCoupl(Int_t nCoupled, const Int_t *clustNumb,
1136 const TMatrixD& aijcluclu, Int_t *minGroup)
c0a16418 1137{
1138 /// Find group of clusters with minimum coupling to all the others
1139
1140 Int_t i123max = TMath::Min(3,nCoupled/2);
1141 Int_t indx, indx1, indx2, indx3, nTot = 0;
1142 Double_t *coupl1 = 0, *coupl2 = 0, *coupl3 = 0;
1143
2abdae6e 1144 for (Int_t i123 = 1; i123 <= i123max; ++i123) {
c0a16418 1145
1146 if (i123 == 1) {
1147 coupl1 = new Double_t [nCoupled];
2abdae6e 1148 for (Int_t i = 0; i < nCoupled; ++i) coupl1[i] = 0;
c0a16418 1149 }
1150 else if (i123 == 2) {
1151 nTot = nCoupled*nCoupled;
1152 coupl2 = new Double_t [nTot];
2abdae6e 1153 for (Int_t i = 0; i < nTot; ++i) coupl2[i] = 9999;
c0a16418 1154 } else {
1155 nTot = nTot*nCoupled;
1156 coupl3 = new Double_t [nTot];
2abdae6e 1157 for (Int_t i = 0; i < nTot; ++i) coupl3[i] = 9999;
c0a16418 1158 } // else
1159
2abdae6e 1160 for (Int_t i = 0; i < nCoupled; ++i) {
c0a16418 1161 indx1 = clustNumb[i];
2abdae6e 1162 for (Int_t j = i+1; j < nCoupled; ++j) {
c0a16418 1163 indx2 = clustNumb[j];
1164 if (i123 == 1) {
1165 coupl1[i] += aijcluclu(indx1,indx2);
1166 coupl1[j] += aijcluclu(indx1,indx2);
1167 }
1168 else if (i123 == 2) {
1169 indx = i*nCoupled + j;
1170 coupl2[indx] = coupl1[i] + coupl1[j];
1171 coupl2[indx] -= 2 * (aijcluclu(indx1,indx2));
1172 } else {
2abdae6e 1173 for (Int_t k = j+1; k < nCoupled; ++k) {
c0a16418 1174 indx3 = clustNumb[k];
1175 indx = i*nCoupled*nCoupled + j*nCoupled + k;
1176 coupl3[indx] = coupl2[i*nCoupled+j] + coupl1[k];
1177 coupl3[indx] -= 2 * (aijcluclu(indx1,indx3)+aijcluclu(indx2,indx3));
1178 }
1179 } // else
1180 } // for (Int_t j=i+1;
1181 } // for (Int_t i=0;
1182 } // for (Int_t i123=1;
1183
1184 // Find minimum coupling
1185 Double_t couplMin = 9999;
1186 Int_t locMin = 0;
1187
2abdae6e 1188 for (Int_t i123 = 1; i123 <= i123max; ++i123) {
c0a16418 1189 if (i123 == 1) {
1190 locMin = TMath::LocMin(nCoupled, coupl1);
1191 couplMin = coupl1[locMin];
1192 minGroup[0] = locMin;
2abdae6e 1193 delete [] coupl1;
c0a16418 1194 }
1195 else if (i123 == 2) {
1196 locMin = TMath::LocMin(nCoupled*nCoupled, coupl2);
1197 if (coupl2[locMin] < couplMin) {
1198 couplMin = coupl2[locMin];
1199 minGroup[0] = locMin/nCoupled;
1200 minGroup[1] = locMin%nCoupled;
1201 }
2abdae6e 1202 delete [] coupl2;
c0a16418 1203 } else {
1204 locMin = TMath::LocMin(nTot, coupl3);
1205 if (coupl3[locMin] < couplMin) {
1206 couplMin = coupl3[locMin];
1207 minGroup[0] = locMin/nCoupled/nCoupled;
1208 minGroup[1] = locMin%(nCoupled*nCoupled)/nCoupled;
1209 minGroup[2] = locMin%nCoupled;
1210 }
2abdae6e 1211 delete [] coupl3;
c0a16418 1212 } // else
1213 } // for (Int_t i123=1;
1214 return couplMin;
1215}
1216
1217//_____________________________________________________________________________
1218Int_t
1219AliMUONClusterSplitterMLEM::SelectPad(const AliMUONCluster& cluster,
1220 Int_t nCoupled, Int_t nForFit,
57e2ad1a 1221 const Int_t *clustNumb, const Int_t *clustFit,
1222 const TMatrixD& aijclupad)
c0a16418 1223{
1224 /// Select pads for fit. If too many coupled clusters, find pads giving
1225 /// the strongest coupling with the rest of clusters and exclude them from the fit.
1226
1227 Int_t npad = cluster.Multiplicity();
1228 Double_t *padpix = 0;
1229
1230 if (nCoupled > 3)
1231 {
1232 padpix = new Double_t[npad];
a9c259b2 1233 for (Int_t i = 0; i < npad; ++i) padpix[i] = 0.;
c0a16418 1234 }
1235
1236 Int_t nOK = 0, indx, indx1;
2abdae6e 1237 for (Int_t iclust = 0; iclust < nForFit; ++iclust)
c0a16418 1238 {
1239 indx = clustFit[iclust];
2abdae6e 1240 for (Int_t j = 0; j < npad; ++j)
c0a16418 1241 {
1242 if ( aijclupad(indx,j) < fgkCouplMin) continue;
1243 AliMUONPad* pad = cluster.Pad(j);
a9c259b2 1244 /*
2abdae6e 1245 if ( pad->Status() == -5 ) pad->SetStatus(-9); // flag overflow
c0a16418 1246 if ( pad->Status() < 0 ) continue; // exclude overflows and used pads
1247 if ( !pad->Status() )
1248 {
1249 pad->SetStatus(1);
1250 ++nOK; // pad to be used in fit
1251 }
a9c259b2 1252 */
05542040 1253 if ( pad->Status() != AliMUONClusterFinderMLEM::GetZeroFlag()
a9c259b2 1254 || pad->IsSaturated() ) continue; // used pads and overflows
05542040 1255 pad->SetStatus(AliMUONClusterFinderMLEM::GetUseForFitFlag());
a9c259b2 1256 ++nOK; // pad to be used in fit
1257
c0a16418 1258 if (nCoupled > 3)
1259 {
1260 // Check other clusters
2abdae6e 1261 for (Int_t iclust1 = 0; iclust1 < nCoupled; ++iclust1)
c0a16418 1262 {
1263 indx1 = clustNumb[iclust1];
1264 if (indx1 < 0) continue;
1265 if ( aijclupad(indx1,j) < fgkCouplMin ) continue;
1266 padpix[j] += aijclupad(indx1,j);
1267 }
1268 } // if (nCoupled > 3)
1269 } // for (Int_t j=0; j<npad;
1270 } // for (Int_t iclust=0; iclust<nForFit
1271 if (nCoupled < 4) return nOK;
1272
1273 Double_t aaa = 0;
2abdae6e 1274 for (Int_t j = 0; j < npad; ++j)
c0a16418 1275 {
1276 if (padpix[j] < fgkCouplMin) continue;
1277 aaa += padpix[j];
a9c259b2 1278 //cluster.Pad(j)->SetStatus(-1); // exclude pads with strong coupling to the other clusters
05542040 1279 cluster.Pad(j)->SetStatus(AliMUONClusterFinderMLEM::GetCoupledFlag()); // exclude pads with strong coupling to the other clusters
c0a16418 1280 nOK--;
1281 }
1282 delete [] padpix;
c0a16418 1283 return nOK;
1284}
1285
1286//_____________________________________________________________________________
1287void
1288AliMUONClusterSplitterMLEM::UpdatePads(const AliMUONCluster& cluster,
1289 Int_t /*nfit*/, Double_t *par)
1290{
1291 /// Subtract the fitted charges from pads with strong coupling
1292
a9c259b2 1293 Int_t indx, mult = cluster.Multiplicity(), iend = fNpar/3;
c0a16418 1294 Double_t charge, coef=0;
1295
2abdae6e 1296 for (Int_t j = 0; j < mult; ++j)
c0a16418 1297 {
1298 AliMUONPad* pad = cluster.Pad(j);
a9c259b2 1299 //if ( pad->Status() != -1 ) continue;
05542040 1300 if ( pad->Status() != AliMUONClusterFinderMLEM::GetCoupledFlag() ) continue;
c0a16418 1301 if (fNpar != 0)
1302 {
1303 charge = 0;
a9c259b2 1304 for (Int_t i = 0; i <= iend; ++i)
c0a16418 1305 {
a9c259b2 1306 // sum over hits
1307 indx = 3 * i;
1308 coef = Param2Coef(i, coef, par);
9bbd7f60 1309 charge += ChargeIntegration(par[indx],par[indx+1],*pad) * coef;
c0a16418 1310 }
1311 charge *= fQtot;
1312 pad->SetCharge(pad->Charge()-charge);
1313 } // if (fNpar != 0)
1314
a9c259b2 1315 //if (pad->Charge() > 6 /*fgkZeroSuppression*/) pad->SetStatus(0);
110edb51 1316 if (pad->Charge() > fLowestPadCharge) pad->SetStatus(AliMUONClusterFinderMLEM::GetZeroFlag());
c0a16418 1317 // return pad for further using // FIXME: remove usage of zerosuppression here
05542040 1318 else pad->SetStatus(AliMUONClusterFinderMLEM::GetOverFlag()); // do not use anymore
c0a16418 1319
1320 } // for (Int_t j=0;
1321}
1322
1323