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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 | /* $Id$ */ | |
17 | ||
18 | //------------------------------------------------------- | |
19 | // Implementation of the TPC clusterer | |
20 | // | |
21 | // 1. The Input data for reconstruction - Options | |
22 | // 1.a Simulated data - TTree - invoked Digits2Clusters() | |
23 | // 1.b Raw data - Digits2Clusters(AliRawReader* rawReader); | |
24 | // | |
25 | // 2. The Output data | |
26 | // 2.a TTree with clusters - if SetOutput(TTree * tree) invoked | |
27 | // 2.b TObjArray - Faster option for HLT | |
28 | // 2.c TClonesArray - Faster option for HLT (smaller memory consumption), activate with fBClonesArray flag | |
29 | // | |
30 | // 3. Reconstruction setup | |
31 | // see AliTPCRecoParam for list of parameters | |
32 | // The reconstruction parameterization taken from the | |
33 | // AliTPCReconstructor::GetRecoParam() | |
34 | // Possible to setup it in reconstruction macro AliTPCReconstructor::SetRecoParam(...) | |
35 | // | |
36 | // | |
37 | // | |
38 | // Origin: Marian Ivanov | |
39 | //------------------------------------------------------- | |
40 | ||
41 | #include "Riostream.h" | |
42 | #include <TF1.h> | |
43 | #include <TFile.h> | |
44 | #include <TGraph.h> | |
45 | #include <TH1F.h> | |
46 | #include <TObjArray.h> | |
47 | #include <TClonesArray.h> | |
48 | #include <TRandom.h> | |
49 | #include <TTree.h> | |
50 | #include <TTreeStream.h> | |
51 | ||
52 | #include "AliDigits.h" | |
53 | #include "AliLoader.h" | |
54 | #include "AliLog.h" | |
55 | #include "AliMathBase.h" | |
56 | #include "AliRawEventHeaderBase.h" | |
57 | #include "AliRawReader.h" | |
58 | #include "AliRunLoader.h" | |
59 | #include "AliSimDigits.h" | |
60 | #include "AliTPCCalPad.h" | |
61 | #include "AliTPCCalROC.h" | |
62 | #include "AliTPCClustersArray.h" | |
63 | #include "AliTPCClustersRow.h" | |
64 | #include "AliTPCParam.h" | |
65 | #include "AliTPCRawStream.h" | |
66 | #include "AliTPCRawStreamV3.h" | |
67 | #include "AliTPCRecoParam.h" | |
68 | #include "AliTPCReconstructor.h" | |
69 | #include "AliTPCcalibDB.h" | |
70 | #include "AliTPCclusterInfo.h" | |
71 | #include "AliTPCclusterMI.h" | |
72 | #include "AliTPCTransform.h" | |
73 | #include "AliTPCclustererMI.h" | |
74 | ||
75 | ClassImp(AliTPCclustererMI) | |
76 | ||
77 | ||
78 | ||
79 | AliTPCclustererMI::AliTPCclustererMI(const AliTPCParam* par, const AliTPCRecoParam * recoParam): | |
80 | fBins(0), | |
81 | fSigBins(0), | |
82 | fNSigBins(0), | |
83 | fLoop(0), | |
84 | fMaxBin(0), | |
85 | fMaxTime(1006), // 1000>940 so use 1000, add 3 virtual time bins before and 3 after | |
86 | fMaxPad(0), | |
87 | fSector(-1), | |
88 | fRow(-1), | |
89 | fSign(0), | |
90 | fRx(0), | |
91 | fPadWidth(0), | |
92 | fPadLength(0), | |
93 | fZWidth(0), | |
94 | fPedSubtraction(kFALSE), | |
95 | fEventHeader(0), | |
96 | fTimeStamp(0), | |
97 | fEventType(0), | |
98 | fInput(0), | |
99 | fOutput(0), | |
100 | fOutputArray(0), | |
101 | fOutputClonesArray(0), | |
102 | fRowCl(0), | |
103 | fRowDig(0), | |
104 | fParam(0), | |
105 | fNcluster(0), | |
106 | fNclusters(0), | |
107 | fDebugStreamer(0), | |
108 | fRecoParam(0), | |
109 | fBDumpSignal(kFALSE), | |
110 | fBClonesArray(kFALSE), | |
111 | fAllBins(NULL), | |
112 | fAllSigBins(NULL), | |
113 | fAllNSigBins(NULL) | |
114 | { | |
115 | // | |
116 | // COSNTRUCTOR | |
117 | // param - tpc parameters for given file | |
118 | // recoparam - reconstruction parameters | |
119 | // | |
120 | fInput =0; | |
121 | fParam = par; | |
122 | if (recoParam) { | |
123 | fRecoParam = recoParam; | |
124 | }else{ | |
125 | //set default parameters if not specified | |
126 | fRecoParam = AliTPCReconstructor::GetRecoParam(); | |
127 | if (!fRecoParam) fRecoParam = AliTPCRecoParam::GetLowFluxParam(); | |
128 | } | |
129 | ||
130 | if(AliTPCReconstructor::StreamLevel()>0) { | |
131 | fDebugStreamer = new TTreeSRedirector("TPCsignal.root"); | |
132 | } | |
133 | ||
134 | // Int_t nPoints = fRecoParam->GetLastBin()-fRecoParam->GetFirstBin(); | |
135 | fRowCl= new AliTPCClustersRow("AliTPCclusterMI"); | |
136 | ||
137 | // Non-persistent arrays | |
138 | // | |
139 | //alocate memory for sector - maximal case | |
140 | // | |
141 | AliTPCROC * roc = AliTPCROC::Instance(); | |
142 | Int_t nRowsMax = roc->GetNRows(roc->GetNSector()-1); | |
143 | Int_t nPadsMax = roc->GetNPads(roc->GetNSector()-1,nRowsMax-1); | |
144 | ||
145 | fAllBins = new Float_t*[nRowsMax]; | |
146 | fAllSigBins = new Int_t*[nRowsMax]; | |
147 | fAllNSigBins = new Int_t[nRowsMax]; | |
148 | for (Int_t iRow = 0; iRow < nRowsMax; iRow++) { | |
149 | // | |
150 | Int_t maxBin = fMaxTime*(nPadsMax+6); // add 3 virtual pads before and 3 after | |
151 | fAllBins[iRow] = new Float_t[maxBin]; | |
152 | memset(fAllBins[iRow],0,sizeof(Float_t)*maxBin); | |
153 | fAllSigBins[iRow] = new Int_t[maxBin]; | |
154 | fAllNSigBins[iRow]=0; | |
155 | } | |
156 | } | |
157 | //______________________________________________________________ | |
158 | AliTPCclustererMI::AliTPCclustererMI(const AliTPCclustererMI ¶m) | |
159 | :TObject(param), | |
160 | fBins(0), | |
161 | fSigBins(0), | |
162 | fNSigBins(0), | |
163 | fLoop(0), | |
164 | fMaxBin(0), | |
165 | fMaxTime(0), | |
166 | fMaxPad(0), | |
167 | fSector(-1), | |
168 | fRow(-1), | |
169 | fSign(0), | |
170 | fRx(0), | |
171 | fPadWidth(0), | |
172 | fPadLength(0), | |
173 | fZWidth(0), | |
174 | fPedSubtraction(kFALSE), | |
175 | fEventHeader(0), | |
176 | fTimeStamp(0), | |
177 | fEventType(0), | |
178 | fInput(0), | |
179 | fOutput(0), | |
180 | fOutputArray(0), | |
181 | fOutputClonesArray(0), | |
182 | fRowCl(0), | |
183 | fRowDig(0), | |
184 | fParam(0), | |
185 | fNcluster(0), | |
186 | fNclusters(0), | |
187 | fDebugStreamer(0), | |
188 | fRecoParam(0), | |
189 | fBDumpSignal(kFALSE), | |
190 | fBClonesArray(kFALSE), | |
191 | fAllBins(NULL), | |
192 | fAllSigBins(NULL), | |
193 | fAllNSigBins(NULL) | |
194 | { | |
195 | // | |
196 | // dummy | |
197 | // | |
198 | fMaxBin = param.fMaxBin; | |
199 | } | |
200 | //______________________________________________________________ | |
201 | AliTPCclustererMI & AliTPCclustererMI::operator =(const AliTPCclustererMI & param) | |
202 | { | |
203 | // | |
204 | // assignment operator - dummy | |
205 | // | |
206 | fMaxBin=param.fMaxBin; | |
207 | return (*this); | |
208 | } | |
209 | //______________________________________________________________ | |
210 | AliTPCclustererMI::~AliTPCclustererMI(){ | |
211 | // | |
212 | // | |
213 | // | |
214 | if (fDebugStreamer) delete fDebugStreamer; | |
215 | if (fOutputArray){ | |
216 | //fOutputArray->Delete(); | |
217 | delete fOutputArray; | |
218 | } | |
219 | if (fOutputClonesArray){ | |
220 | fOutputClonesArray->Delete(); | |
221 | delete fOutputClonesArray; | |
222 | } | |
223 | ||
224 | if (fRowCl) { | |
225 | fRowCl->GetArray()->Delete(); | |
226 | delete fRowCl; | |
227 | } | |
228 | ||
229 | AliTPCROC * roc = AliTPCROC::Instance(); | |
230 | Int_t nRowsMax = roc->GetNRows(roc->GetNSector()-1); | |
231 | for (Int_t iRow = 0; iRow < nRowsMax; iRow++) { | |
232 | delete [] fAllBins[iRow]; | |
233 | delete [] fAllSigBins[iRow]; | |
234 | } | |
235 | delete [] fAllBins; | |
236 | delete [] fAllSigBins; | |
237 | delete [] fAllNSigBins; | |
238 | } | |
239 | ||
240 | void AliTPCclustererMI::SetInput(TTree * tree) | |
241 | { | |
242 | // | |
243 | // set input tree with digits | |
244 | // | |
245 | fInput = tree; | |
246 | if (!fInput->GetBranch("Segment")){ | |
247 | cerr<<"AliTPC::Digits2Clusters(): no porper input tree !\n"; | |
248 | fInput=0; | |
249 | return; | |
250 | } | |
251 | } | |
252 | ||
253 | void AliTPCclustererMI::SetOutput(TTree * tree) | |
254 | { | |
255 | // | |
256 | // Set the output tree | |
257 | // If not set the ObjArray used - Option for HLT | |
258 | // | |
259 | if (!tree) return; | |
260 | fOutput= tree; | |
261 | AliTPCClustersRow clrow, *pclrow=&clrow; | |
262 | pclrow = new AliTPCClustersRow("AliTPCclusterMI"); | |
263 | fOutput->Branch("Segment","AliTPCClustersRow",&pclrow,32000,200); | |
264 | } | |
265 | ||
266 | ||
267 | void AliTPCclustererMI::FillRow(){ | |
268 | // | |
269 | // fill the output container - | |
270 | // 2 Options possible | |
271 | // Tree | |
272 | // TObjArray | |
273 | // | |
274 | if (fOutput) fOutput->Fill(); | |
275 | if (!fOutput && !fBClonesArray){ | |
276 | // | |
277 | if (!fOutputArray) fOutputArray = new TObjArray(fParam->GetNRowsTotal()); | |
278 | if (fRowCl && fRowCl->GetArray()->GetEntriesFast()>0) fOutputArray->AddAt(fRowCl->Clone(), fRowCl->GetID()); | |
279 | } | |
280 | } | |
281 | ||
282 | Float_t AliTPCclustererMI::GetSigmaY2(Int_t iz){ | |
283 | // sigma y2 = in digits - we don't know the angle | |
284 | Float_t z = iz*fParam->GetZWidth()+fParam->GetNTBinsL1()*fParam->GetZWidth(); | |
285 | Float_t sd2 = (z*fParam->GetDiffL()*fParam->GetDiffL())/ | |
286 | (fPadWidth*fPadWidth); | |
287 | Float_t sres = 0.25; | |
288 | Float_t res = sd2+sres; | |
289 | return res; | |
290 | } | |
291 | ||
292 | ||
293 | Float_t AliTPCclustererMI::GetSigmaZ2(Int_t iz){ | |
294 | //sigma z2 = in digits - angle estimated supposing vertex constraint | |
295 | Float_t z = iz*fZWidth+fParam->GetNTBinsL1()*fParam->GetZWidth(); | |
296 | Float_t sd2 = (z*fParam->GetDiffL()*fParam->GetDiffL())/(fZWidth*fZWidth); | |
297 | Float_t angular = fPadLength*(fParam->GetZLength(fSector)-z)/(fRx*fZWidth); | |
298 | angular*=angular; | |
299 | angular/=12.; | |
300 | Float_t sres = fParam->GetZSigma()/fZWidth; | |
301 | sres *=sres; | |
302 | Float_t res = angular +sd2+sres; | |
303 | return res; | |
304 | } | |
305 | ||
306 | void AliTPCclustererMI::MakeCluster(Int_t k,Int_t max,Float_t *bins, UInt_t /*m*/, | |
307 | AliTPCclusterMI &c) | |
308 | { | |
309 | // | |
310 | // k - Make cluster at position k | |
311 | // bins - 2 D array of signals mapped to 1 dimensional array - | |
312 | // max - the number of time bins er one dimension | |
313 | // c - refernce to cluster to be filled | |
314 | // | |
315 | Int_t i0=k/max; //central pad | |
316 | Int_t j0=k%max; //central time bin | |
317 | ||
318 | // set pointers to data | |
319 | //Int_t dummy[5] ={0,0,0,0,0}; | |
320 | Float_t * matrix[5]; //5x5 matrix with digits - indexing i = 0 ..4 j = -2..2 | |
321 | for (Int_t di=-2;di<=2;di++){ | |
322 | matrix[di+2] = &bins[k+di*max]; | |
323 | } | |
324 | //build matrix with virtual charge | |
325 | Float_t sigmay2= GetSigmaY2(j0); | |
326 | Float_t sigmaz2= GetSigmaZ2(j0); | |
327 | ||
328 | Float_t vmatrix[5][5]; | |
329 | vmatrix[2][2] = matrix[2][0]; | |
330 | c.SetType(0); | |
331 | c.SetMax((UShort_t)(vmatrix[2][2])); // write maximal amplitude | |
332 | for (Int_t di =-1;di <=1;di++) | |
333 | for (Int_t dj =-1;dj <=1;dj++){ | |
334 | Float_t amp = matrix[di+2][dj]; | |
335 | if ( (amp<2) && (fLoop<2)){ | |
336 | // if under threshold - calculate virtual charge | |
337 | Float_t ratio = TMath::Exp(-1.2*TMath::Abs(di)/sigmay2)*TMath::Exp(-1.2*TMath::Abs(dj)/sigmaz2); | |
338 | amp = ((matrix[2][0]-2)*(matrix[2][0]-2)/(matrix[-di+2][-dj]+2))*ratio; | |
339 | if (amp>2) amp = 2; | |
340 | vmatrix[2+di][2+dj]=amp; | |
341 | vmatrix[2+2*di][2+2*dj]=0; | |
342 | if ( (di*dj)!=0){ | |
343 | //DIAGONAL ELEMENTS | |
344 | vmatrix[2+2*di][2+dj] =0; | |
345 | vmatrix[2+di][2+2*dj] =0; | |
346 | } | |
347 | continue; | |
348 | } | |
349 | if (amp<4){ | |
350 | //if small amplitude - below 2 x threshold - don't consider other one | |
351 | vmatrix[2+di][2+dj]=amp; | |
352 | vmatrix[2+2*di][2+2*dj]=0; // don't take to the account next bin | |
353 | if ( (di*dj)!=0){ | |
354 | //DIAGONAL ELEMENTS | |
355 | vmatrix[2+2*di][2+dj] =0; | |
356 | vmatrix[2+di][2+2*dj] =0; | |
357 | } | |
358 | continue; | |
359 | } | |
360 | //if bigger then take everything | |
361 | vmatrix[2+di][2+dj]=amp; | |
362 | vmatrix[2+2*di][2+2*dj]= matrix[2*di+2][2*dj] ; | |
363 | if ( (di*dj)!=0){ | |
364 | //DIAGONAL ELEMENTS | |
365 | vmatrix[2+2*di][2+dj] = matrix[2*di+2][dj]; | |
366 | vmatrix[2+di][2+2*dj] = matrix[2+di][dj*2]; | |
367 | } | |
368 | } | |
369 | ||
370 | ||
371 | ||
372 | Float_t sumw=0; | |
373 | Float_t sumiw=0; | |
374 | Float_t sumi2w=0; | |
375 | Float_t sumjw=0; | |
376 | Float_t sumj2w=0; | |
377 | // | |
378 | for (Int_t i=-2;i<=2;i++) | |
379 | for (Int_t j=-2;j<=2;j++){ | |
380 | Float_t amp = vmatrix[i+2][j+2]; | |
381 | ||
382 | sumw += amp; | |
383 | sumiw += i*amp; | |
384 | sumi2w += i*i*amp; | |
385 | sumjw += j*amp; | |
386 | sumj2w += j*j*amp; | |
387 | } | |
388 | // | |
389 | Float_t meani = sumiw/sumw; | |
390 | Float_t mi2 = sumi2w/sumw-meani*meani; | |
391 | Float_t meanj = sumjw/sumw; | |
392 | Float_t mj2 = sumj2w/sumw-meanj*meanj; | |
393 | // | |
394 | Float_t ry = mi2/sigmay2; | |
395 | Float_t rz = mj2/sigmaz2; | |
396 | ||
397 | // | |
398 | if ( ( (ry<0.6) || (rz<0.6) ) && fLoop==2) return; | |
399 | if ( ((ry <1.2) && (rz<1.2)) || (!fRecoParam->GetDoUnfold())) { | |
400 | // | |
401 | //if cluster looks like expected or Unfolding not switched on | |
402 | //standard COG is used | |
403 | //+1.2 deviation from expected sigma accepted | |
404 | // c.fMax = FitMax(vmatrix,meani,meanj,TMath::Sqrt(sigmay2),TMath::Sqrt(sigmaz2)); | |
405 | ||
406 | meani +=i0; | |
407 | meanj +=j0; | |
408 | //set cluster parameters | |
409 | c.SetQ(sumw); | |
410 | c.SetPad(meani-2.5); | |
411 | c.SetTimeBin(meanj-3); | |
412 | c.SetSigmaY2(mi2); | |
413 | c.SetSigmaZ2(mj2); | |
414 | c.SetType(0); | |
415 | AddCluster(c,(Float_t*)vmatrix,k); | |
416 | return; | |
417 | } | |
418 | // | |
419 | //unfolding when neccessary | |
420 | // | |
421 | ||
422 | Float_t * matrix2[7]; //7x7 matrix with digits - indexing i = 0 ..6 j = -3..3 | |
423 | Float_t dummy[7]={0,0,0,0,0,0}; | |
424 | for (Int_t di=-3;di<=3;di++){ | |
425 | matrix2[di+3] = &bins[k+di*max]; | |
426 | if ((k+di*max)<3) matrix2[di+3] = &dummy[3]; | |
427 | if ((k+di*max)>fMaxBin-3) matrix2[di+3] = &dummy[3]; | |
428 | } | |
429 | Float_t vmatrix2[5][5]; | |
430 | Float_t sumu; | |
431 | Float_t overlap; | |
432 | UnfoldCluster(matrix2,vmatrix2,meani,meanj,sumu,overlap); | |
433 | // | |
434 | // c.fMax = FitMax(vmatrix2,meani,meanj,TMath::Sqrt(sigmay2),TMath::Sqrt(sigmaz2)); | |
435 | meani +=i0; | |
436 | meanj +=j0; | |
437 | //set cluster parameters | |
438 | c.SetQ(sumu); | |
439 | c.SetPad(meani-2.5); | |
440 | c.SetTimeBin(meanj-3); | |
441 | c.SetSigmaY2(mi2); | |
442 | c.SetSigmaZ2(mj2); | |
443 | c.SetType(Char_t(overlap)+1); | |
444 | AddCluster(c,(Float_t*)vmatrix,k); | |
445 | ||
446 | //unfolding 2 | |
447 | meani-=i0; | |
448 | meanj-=j0; | |
449 | } | |
450 | ||
451 | ||
452 | ||
453 | void AliTPCclustererMI::UnfoldCluster(Float_t * matrix2[7], Float_t recmatrix[5][5], Float_t & meani, Float_t & meanj, | |
454 | Float_t & sumu, Float_t & overlap ) | |
455 | { | |
456 | // | |
457 | //unfold cluster from input matrix | |
458 | //data corresponding to cluster writen in recmatrix | |
459 | //output meani and meanj | |
460 | ||
461 | //take separatelly y and z | |
462 | ||
463 | Float_t sum3i[7] = {0,0,0,0,0,0,0}; | |
464 | Float_t sum3j[7] = {0,0,0,0,0,0,0}; | |
465 | ||
466 | for (Int_t k =0;k<7;k++) | |
467 | for (Int_t l = -1; l<=1;l++){ | |
468 | sum3i[k]+=matrix2[k][l]; | |
469 | sum3j[k]+=matrix2[l+3][k-3]; | |
470 | } | |
471 | Float_t mratio[3][3]={{1,1,1},{1,1,1},{1,1,1}}; | |
472 | // | |
473 | //unfold y | |
474 | Float_t sum3wi = 0; //charge minus overlap | |
475 | Float_t sum3wio = 0; //full charge | |
476 | Float_t sum3iw = 0; //sum for mean value | |
477 | for (Int_t dk=-1;dk<=1;dk++){ | |
478 | sum3wio+=sum3i[dk+3]; | |
479 | if (dk==0){ | |
480 | sum3wi+=sum3i[dk+3]; | |
481 | } | |
482 | else{ | |
483 | Float_t ratio =1; | |
484 | if ( ( ((sum3i[dk+3]+3)/(sum3i[3]-3))+1 < (sum3i[2*dk+3]-3)/(sum3i[dk+3]+3))|| | |
485 | (sum3i[dk+3]<=sum3i[2*dk+3] && sum3i[dk+3]>2 )){ | |
486 | Float_t xm2 = sum3i[-dk+3]; | |
487 | Float_t xm1 = sum3i[+3]; | |
488 | Float_t x1 = sum3i[2*dk+3]; | |
489 | Float_t x2 = sum3i[3*dk+3]; | |
490 | Float_t w11 = TMath::Max((Float_t)(4.*xm1-xm2),(Float_t)0.000001); | |
491 | Float_t w12 = TMath::Max((Float_t)(4 *x1 -x2),(Float_t)0.); | |
492 | ratio = w11/(w11+w12); | |
493 | for (Int_t dl=-1;dl<=1;dl++) | |
494 | mratio[dk+1][dl+1] *= ratio; | |
495 | } | |
496 | Float_t amp = sum3i[dk+3]*ratio; | |
497 | sum3wi+=amp; | |
498 | sum3iw+= dk*amp; | |
499 | } | |
500 | } | |
501 | meani = sum3iw/sum3wi; | |
502 | Float_t overlapi = (sum3wio-sum3wi)/sum3wio; | |
503 | ||
504 | ||
505 | ||
506 | //unfold z | |
507 | Float_t sum3wj = 0; //charge minus overlap | |
508 | Float_t sum3wjo = 0; //full charge | |
509 | Float_t sum3jw = 0; //sum for mean value | |
510 | for (Int_t dk=-1;dk<=1;dk++){ | |
511 | sum3wjo+=sum3j[dk+3]; | |
512 | if (dk==0){ | |
513 | sum3wj+=sum3j[dk+3]; | |
514 | } | |
515 | else{ | |
516 | Float_t ratio =1; | |
517 | if ( ( ((sum3j[dk+3]+3)/(sum3j[3]-3))+1 < (sum3j[2*dk+3]-3)/(sum3j[dk+3]+3)) || | |
518 | (sum3j[dk+3]<=sum3j[2*dk+3] && sum3j[dk+3]>2)){ | |
519 | Float_t xm2 = sum3j[-dk+3]; | |
520 | Float_t xm1 = sum3j[+3]; | |
521 | Float_t x1 = sum3j[2*dk+3]; | |
522 | Float_t x2 = sum3j[3*dk+3]; | |
523 | Float_t w11 = TMath::Max((Float_t)(4.*xm1-xm2),(Float_t)0.000001); | |
524 | Float_t w12 = TMath::Max((Float_t)(4 *x1 -x2),(Float_t)0.); | |
525 | ratio = w11/(w11+w12); | |
526 | for (Int_t dl=-1;dl<=1;dl++) | |
527 | mratio[dl+1][dk+1] *= ratio; | |
528 | } | |
529 | Float_t amp = sum3j[dk+3]*ratio; | |
530 | sum3wj+=amp; | |
531 | sum3jw+= dk*amp; | |
532 | } | |
533 | } | |
534 | meanj = sum3jw/sum3wj; | |
535 | Float_t overlapj = (sum3wjo-sum3wj)/sum3wjo; | |
536 | overlap = Int_t(100*TMath::Max(overlapi,overlapj)+3); | |
537 | sumu = (sum3wj+sum3wi)/2.; | |
538 | ||
539 | if (overlap ==3) { | |
540 | //if not overlap detected remove everything | |
541 | for (Int_t di =-2; di<=2;di++) | |
542 | for (Int_t dj =-2; dj<=2;dj++){ | |
543 | recmatrix[di+2][dj+2] = matrix2[3+di][dj]; | |
544 | } | |
545 | } | |
546 | else{ | |
547 | for (Int_t di =-1; di<=1;di++) | |
548 | for (Int_t dj =-1; dj<=1;dj++){ | |
549 | Float_t ratio =1; | |
550 | if (mratio[di+1][dj+1]==1){ | |
551 | recmatrix[di+2][dj+2] = matrix2[3+di][dj]; | |
552 | if (TMath::Abs(di)+TMath::Abs(dj)>1){ | |
553 | recmatrix[2*di+2][dj+2] = matrix2[3+2*di][dj]; | |
554 | recmatrix[di+2][2*dj+2] = matrix2[3+di][2*dj]; | |
555 | } | |
556 | recmatrix[2*di+2][2*dj+2] = matrix2[3+2*di][2*dj]; | |
557 | } | |
558 | else | |
559 | { | |
560 | //if we have overlap in direction | |
561 | recmatrix[di+2][dj+2] = mratio[di+1][dj+1]* matrix2[3+di][dj]; | |
562 | if (TMath::Abs(di)+TMath::Abs(dj)>1){ | |
563 | ratio = TMath::Min((Float_t)(recmatrix[di+2][dj+2]/(matrix2[3+0*di][1*dj]+1)),(Float_t)1.); | |
564 | recmatrix[2*di+2][dj+2] = ratio*recmatrix[di+2][dj+2]; | |
565 | // | |
566 | ratio = TMath::Min((Float_t)(recmatrix[di+2][dj+2]/(matrix2[3+1*di][0*dj]+1)),(Float_t)1.); | |
567 | recmatrix[di+2][2*dj+2] = ratio*recmatrix[di+2][dj+2]; | |
568 | } | |
569 | else{ | |
570 | ratio = recmatrix[di+2][dj+2]/matrix2[3][0]; | |
571 | recmatrix[2*di+2][2*dj+2] = ratio*recmatrix[di+2][dj+2]; | |
572 | } | |
573 | } | |
574 | } | |
575 | } | |
576 | ||
577 | } | |
578 | ||
579 | Float_t AliTPCclustererMI::FitMax(Float_t vmatrix[5][5], Float_t y, Float_t z, Float_t sigmay, Float_t sigmaz) | |
580 | { | |
581 | // | |
582 | // estimate max | |
583 | Float_t sumteor= 0; | |
584 | Float_t sumamp = 0; | |
585 | ||
586 | for (Int_t di = -1;di<=1;di++) | |
587 | for (Int_t dj = -1;dj<=1;dj++){ | |
588 | if (vmatrix[2+di][2+dj]>2){ | |
589 | Float_t teor = TMath::Gaus(di,y,sigmay*1.2)*TMath::Gaus(dj,z,sigmaz*1.2); | |
590 | sumteor += teor*vmatrix[2+di][2+dj]; | |
591 | sumamp += vmatrix[2+di][2+dj]*vmatrix[2+di][2+dj]; | |
592 | } | |
593 | } | |
594 | Float_t max = sumamp/sumteor; | |
595 | return max; | |
596 | } | |
597 | ||
598 | void AliTPCclustererMI::AddCluster(AliTPCclusterMI &c, Float_t * /*matrix*/, Int_t /*pos*/){ | |
599 | // | |
600 | // | |
601 | // Transform cluster to the rotated global coordinata | |
602 | // Assign labels to the cluster | |
603 | // add the cluster to the array | |
604 | // for more details - See AliTPCTranform::Transform(x,i,0,1) | |
605 | Float_t meani = c.GetPad(); | |
606 | Float_t meanj = c.GetTimeBin(); | |
607 | ||
608 | Int_t ki = TMath::Nint(meani); | |
609 | if (ki<0) ki=0; | |
610 | if (ki>=fMaxPad) ki = fMaxPad-1; | |
611 | Int_t kj = TMath::Nint(meanj); | |
612 | if (kj<0) kj=0; | |
613 | if (kj>=fMaxTime-3) kj=fMaxTime-4; | |
614 | // ki and kj shifted as integers coordinata | |
615 | if (fRowDig) { | |
616 | c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,0)-2,0); | |
617 | c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,1)-2,1); | |
618 | c.SetLabel(fRowDig->GetTrackIDFast(kj,ki,2)-2,2); | |
619 | } | |
620 | ||
621 | c.SetRow(fRow); | |
622 | c.SetDetector(fSector); | |
623 | Float_t s2 = c.GetSigmaY2(); | |
624 | Float_t w=fParam->GetPadPitchWidth(fSector); | |
625 | c.SetSigmaY2(s2*w*w); | |
626 | s2 = c.GetSigmaZ2(); | |
627 | c.SetSigmaZ2(s2*fZWidth*fZWidth); | |
628 | // | |
629 | // | |
630 | // | |
631 | ||
632 | AliTPCTransform *transform = AliTPCcalibDB::Instance()->GetTransform() ; | |
633 | if (!transform) { | |
634 | AliFatal("Tranformations not in calibDB"); | |
635 | } | |
636 | transform->SetCurrentRecoParam((AliTPCRecoParam*)fRecoParam); | |
637 | Double_t x[3]={c.GetRow(),c.GetPad(),c.GetTimeBin()}; | |
638 | Int_t i[1]={fSector}; | |
639 | transform->Transform(x,i,0,1); | |
640 | c.SetX(x[0]); | |
641 | c.SetY(x[1]); | |
642 | c.SetZ(x[2]); | |
643 | // | |
644 | // | |
645 | if (ki<=1 || ki>=fMaxPad-1 || kj==1 || kj==fMaxTime-2) { | |
646 | c.SetType(-(c.GetType()+3)); //edge clusters | |
647 | } | |
648 | if (fLoop==2) c.SetType(100); | |
649 | if (!AcceptCluster(&c)) return; | |
650 | ||
651 | // select output | |
652 | TClonesArray * arr = 0; | |
653 | AliTPCclusterMI * cl = 0; | |
654 | ||
655 | if(fBClonesArray==kFALSE) { | |
656 | arr = fRowCl->GetArray(); | |
657 | cl = new ((*arr)[fNcluster]) AliTPCclusterMI(c); | |
658 | } else { | |
659 | cl = new ((*fOutputClonesArray)[fNclusters+fNcluster]) AliTPCclusterMI(c); | |
660 | } | |
661 | ||
662 | // if (fRecoParam->DumpSignal() &&matrix ) { | |
663 | // Int_t nbins=0; | |
664 | // Float_t *graph =0; | |
665 | // if (fRecoParam->GetCalcPedestal() && cl->GetMax()>fRecoParam->GetDumpAmplitudeMin() &&fBDumpSignal){ | |
666 | // nbins = fMaxTime; | |
667 | // graph = &(fBins[fMaxTime*(pos/fMaxTime)]); | |
668 | // } | |
669 | // AliTPCclusterInfo * info = new AliTPCclusterInfo(matrix,nbins,graph); | |
670 | // cl->SetInfo(info); | |
671 | // } | |
672 | if (!fRecoParam->DumpSignal()) { | |
673 | cl->SetInfo(0); | |
674 | } | |
675 | ||
676 | if (AliTPCReconstructor::StreamLevel()>1) { | |
677 | Float_t xyz[3]; | |
678 | cl->GetGlobalXYZ(xyz); | |
679 | (*fDebugStreamer)<<"Clusters"<< | |
680 | "Cl.="<<cl<< | |
681 | "gx="<<xyz[0]<< | |
682 | "gy="<<xyz[1]<< | |
683 | "gz="<<xyz[2]<< | |
684 | "\n"; | |
685 | } | |
686 | ||
687 | fNcluster++; | |
688 | } | |
689 | ||
690 | ||
691 | //_____________________________________________________________________________ | |
692 | void AliTPCclustererMI::Digits2Clusters() | |
693 | { | |
694 | //----------------------------------------------------------------- | |
695 | // This is a simple cluster finder. | |
696 | //----------------------------------------------------------------- | |
697 | ||
698 | if (!fInput) { | |
699 | Error("Digits2Clusters", "input tree not initialised"); | |
700 | return; | |
701 | } | |
702 | fRecoParam = AliTPCReconstructor::GetRecoParam(); | |
703 | if (!fRecoParam){ | |
704 | AliFatal("Can not get the reconstruction parameters"); | |
705 | } | |
706 | if(AliTPCReconstructor::StreamLevel()>5) { | |
707 | AliInfo("Parameter Dumps"); | |
708 | fParam->Dump(); | |
709 | fRecoParam->Dump(); | |
710 | } | |
711 | ||
712 | AliTPCCalPad * gainTPC = AliTPCcalibDB::Instance()->GetPadGainFactor(); | |
713 | AliTPCCalPad * noiseTPC = AliTPCcalibDB::Instance()->GetPadNoise(); | |
714 | AliSimDigits digarr, *dummy=&digarr; | |
715 | fRowDig = dummy; | |
716 | fInput->GetBranch("Segment")->SetAddress(&dummy); | |
717 | Stat_t nentries = fInput->GetEntries(); | |
718 | ||
719 | fMaxTime=fRecoParam->GetLastBin()+6; // add 3 virtual time bins before and 3 after | |
720 | ||
721 | Int_t nclusters = 0; | |
722 | ||
723 | for (Int_t n=0; n<nentries; n++) { | |
724 | fInput->GetEvent(n); | |
725 | if (!fParam->AdjustSectorRow(digarr.GetID(),fSector,fRow)) { | |
726 | cerr<<"AliTPC warning: invalid segment ID ! "<<digarr.GetID()<<endl; | |
727 | continue; | |
728 | } | |
729 | Int_t row = fRow; | |
730 | AliTPCCalROC * gainROC = gainTPC->GetCalROC(fSector); // pad gains per given sector | |
731 | AliTPCCalROC * noiseROC = noiseTPC->GetCalROC(fSector); // noise per given sector | |
732 | // | |
733 | ||
734 | fRowCl->SetID(digarr.GetID()); | |
735 | if (fOutput) fOutput->GetBranch("Segment")->SetAddress(&fRowCl); | |
736 | fRx=fParam->GetPadRowRadii(fSector,row); | |
737 | ||
738 | ||
739 | const Int_t kNIS=fParam->GetNInnerSector(), kNOS=fParam->GetNOuterSector(); | |
740 | fZWidth = fParam->GetZWidth(); | |
741 | if (fSector < kNIS) { | |
742 | fMaxPad = fParam->GetNPadsLow(row); | |
743 | fSign = (fSector < kNIS/2) ? 1 : -1; | |
744 | fPadLength = fParam->GetPadPitchLength(fSector,row); | |
745 | fPadWidth = fParam->GetPadPitchWidth(); | |
746 | } else { | |
747 | fMaxPad = fParam->GetNPadsUp(row); | |
748 | fSign = ((fSector-kNIS) < kNOS/2) ? 1 : -1; | |
749 | fPadLength = fParam->GetPadPitchLength(fSector,row); | |
750 | fPadWidth = fParam->GetPadPitchWidth(); | |
751 | } | |
752 | ||
753 | ||
754 | fMaxBin=fMaxTime*(fMaxPad+6); // add 3 virtual pads before and 3 after | |
755 | fBins =new Float_t[fMaxBin]; | |
756 | fSigBins =new Int_t[fMaxBin]; | |
757 | fNSigBins = 0; | |
758 | memset(fBins,0,sizeof(Float_t)*fMaxBin); | |
759 | ||
760 | if (digarr.First()) //MI change | |
761 | do { | |
762 | Float_t dig=digarr.CurrentDigit(); | |
763 | if (dig<=fParam->GetZeroSup()) continue; | |
764 | Int_t j=digarr.CurrentRow()+3, i=digarr.CurrentColumn()+3; | |
765 | Float_t gain = gainROC->GetValue(row,digarr.CurrentColumn()); | |
766 | Int_t bin = i*fMaxTime+j; | |
767 | if (gain>0){ | |
768 | fBins[bin]=dig/gain; | |
769 | }else{ | |
770 | fBins[bin]=0; | |
771 | } | |
772 | fSigBins[fNSigBins++]=bin; | |
773 | } while (digarr.Next()); | |
774 | digarr.ExpandTrackBuffer(); | |
775 | ||
776 | FindClusters(noiseROC); | |
777 | FillRow(); | |
778 | fRowCl->GetArray()->Clear("C"); | |
779 | nclusters+=fNcluster; | |
780 | ||
781 | delete[] fBins; | |
782 | delete[] fSigBins; | |
783 | } | |
784 | ||
785 | Info("Digits2Clusters", "Number of found clusters : %d", nclusters); | |
786 | } | |
787 | ||
788 | void AliTPCclustererMI::ProcessSectorData(){ | |
789 | // | |
790 | // Process the data for the current sector | |
791 | // | |
792 | ||
793 | AliTPCCalPad * pedestalTPC = AliTPCcalibDB::Instance()->GetPedestals(); | |
794 | AliTPCCalPad * noiseTPC = AliTPCcalibDB::Instance()->GetPadNoise(); | |
795 | AliTPCCalROC * pedestalROC = pedestalTPC->GetCalROC(fSector); // pedestal per given sector | |
796 | AliTPCCalROC * noiseROC = noiseTPC->GetCalROC(fSector); // noise per given sector | |
797 | //check the presence of the calibration | |
798 | if (!noiseROC ||!pedestalROC ) { | |
799 | AliError(Form("Missing calibration per sector\t%d\n",fSector)); | |
800 | return; | |
801 | } | |
802 | Int_t nRows=fParam->GetNRow(fSector); | |
803 | Bool_t calcPedestal = fRecoParam->GetCalcPedestal(); | |
804 | Int_t zeroSup = fParam->GetZeroSup(); | |
805 | // if (calcPedestal) { | |
806 | if (kFALSE ) { | |
807 | for (Int_t iRow = 0; iRow < nRows; iRow++) { | |
808 | Int_t maxPad = fParam->GetNPads(fSector, iRow); | |
809 | ||
810 | for (Int_t iPad = 3; iPad < maxPad + 3; iPad++) { | |
811 | // | |
812 | // Temporary fix for data production - !!!! MARIAN | |
813 | // The noise calibration should take mean and RMS - currently the Gaussian fit used | |
814 | // In case of double peak - the pad should be rejected | |
815 | // | |
816 | // Line mean - if more than given digits over threshold - make a noise calculation | |
817 | // and pedestal substration | |
818 | if (!calcPedestal && fAllBins[iRow][iPad*fMaxTime+0]<50) continue; | |
819 | // | |
820 | if (fAllBins[iRow][iPad*fMaxTime+0] <1 ) continue; // no data | |
821 | Float_t *p = &fAllBins[iRow][iPad*fMaxTime+3]; | |
822 | //Float_t pedestal = TMath::Median(fMaxTime, p); | |
823 | Int_t id[3] = {fSector, iRow, iPad-3}; | |
824 | // calib values | |
825 | Double_t rmsCalib= noiseROC->GetValue(iRow,iPad-3); | |
826 | Double_t pedestalCalib = pedestalROC->GetValue(iRow,iPad-3); | |
827 | Double_t rmsEvent = rmsCalib; | |
828 | Double_t pedestalEvent = pedestalCalib; | |
829 | ProcesSignal(p, fMaxTime, id, rmsEvent, pedestalEvent); | |
830 | if (rmsEvent<rmsCalib) rmsEvent = rmsCalib; // take worst scenario | |
831 | if (TMath::Abs(pedestalEvent-pedestalCalib)<1.0) pedestalEvent = pedestalCalib; | |
832 | ||
833 | // | |
834 | for (Int_t iTimeBin = 0; iTimeBin < fMaxTime; iTimeBin++) { | |
835 | Int_t bin = iPad*fMaxTime+iTimeBin; | |
836 | fAllBins[iRow][bin] -= pedestalEvent; | |
837 | if (iTimeBin < fRecoParam->GetFirstBin()) | |
838 | fAllBins[iRow][bin] = 0; | |
839 | if (iTimeBin > fRecoParam->GetLastBin()) | |
840 | fAllBins[iRow][bin] = 0; | |
841 | if (fAllBins[iRow][iPad*fMaxTime+iTimeBin] < zeroSup) | |
842 | fAllBins[iRow][bin] = 0; | |
843 | if (fAllBins[iRow][bin] < 3.0*rmsEvent) // 3 sigma cut on RMS | |
844 | fAllBins[iRow][bin] = 0; | |
845 | if (fAllBins[iRow][bin]) fAllSigBins[iRow][fAllNSigBins[iRow]++] = bin; | |
846 | } | |
847 | } | |
848 | } | |
849 | } | |
850 | ||
851 | if (AliTPCReconstructor::StreamLevel()>5) { | |
852 | for (Int_t iRow = 0; iRow < nRows; iRow++) { | |
853 | Int_t maxPad = fParam->GetNPads(fSector,iRow); | |
854 | ||
855 | for (Int_t iPad = 3; iPad < maxPad + 3; iPad++) { | |
856 | for (Int_t iTimeBin = 0; iTimeBin < fMaxTime; iTimeBin++) { | |
857 | Int_t bin = iPad*fMaxTime+iTimeBin; | |
858 | Float_t signal = fAllBins[iRow][bin]; | |
859 | if (AliTPCReconstructor::StreamLevel()>3 && signal>3) { | |
860 | Double_t x[]={iRow,iPad-3,iTimeBin-3}; | |
861 | Int_t i[]={fSector}; | |
862 | AliTPCTransform trafo; | |
863 | trafo.Transform(x,i,0,1); | |
864 | Double_t gx[3]={x[0],x[1],x[2]}; | |
865 | trafo.RotatedGlobal2Global(fSector,gx); | |
866 | // fAllSigBins[iRow][fAllNSigBins[iRow]++] | |
867 | Int_t rowsigBins = fAllNSigBins[iRow]; | |
868 | Int_t first=fAllSigBins[iRow][0]; | |
869 | Int_t last= 0; | |
870 | // if (rowsigBins>0) fAllSigBins[iRow][fAllNSigBins[iRow]-1]; | |
871 | ||
872 | if (AliTPCReconstructor::StreamLevel()>5) { | |
873 | (*fDebugStreamer)<<"Digits"<< | |
874 | "sec="<<fSector<< | |
875 | "row="<<iRow<< | |
876 | "pad="<<iPad<< | |
877 | "time="<<iTimeBin<< | |
878 | "sig="<<signal<< | |
879 | "x="<<x[0]<< | |
880 | "y="<<x[1]<< | |
881 | "z="<<x[2]<< | |
882 | "gx="<<gx[0]<< | |
883 | "gy="<<gx[1]<< | |
884 | "gz="<<gx[2]<< | |
885 | // | |
886 | "rowsigBins="<<rowsigBins<< | |
887 | "first="<<first<< | |
888 | "last="<<last<< | |
889 | "\n"; | |
890 | } | |
891 | } | |
892 | } | |
893 | } | |
894 | } | |
895 | } | |
896 | ||
897 | // Now loop over rows and find clusters | |
898 | for (fRow = 0; fRow < nRows; fRow++) { | |
899 | fRowCl->SetID(fParam->GetIndex(fSector, fRow)); | |
900 | if (fOutput) fOutput->GetBranch("Segment")->SetAddress(&fRowCl); | |
901 | ||
902 | fRx = fParam->GetPadRowRadii(fSector, fRow); | |
903 | fPadLength = fParam->GetPadPitchLength(fSector, fRow); | |
904 | fPadWidth = fParam->GetPadPitchWidth(); | |
905 | fMaxPad = fParam->GetNPads(fSector,fRow); | |
906 | fMaxBin = fMaxTime*(fMaxPad+6); // add 3 virtual pads before and 3 after | |
907 | ||
908 | fBins = fAllBins[fRow]; | |
909 | fSigBins = fAllSigBins[fRow]; | |
910 | fNSigBins = fAllNSigBins[fRow]; | |
911 | ||
912 | FindClusters(noiseROC); | |
913 | ||
914 | FillRow(); | |
915 | if(fBClonesArray == kFALSE) fRowCl->GetArray()->Clear("C"); | |
916 | fNclusters += fNcluster; | |
917 | ||
918 | } // End of loop to find clusters | |
919 | } | |
920 | ||
921 | ||
922 | void AliTPCclustererMI::Digits2Clusters(AliRawReader* rawReader) | |
923 | { | |
924 | //----------------------------------------------------------------- | |
925 | // This is a cluster finder for the TPC raw data. | |
926 | // The method assumes NO ordering of the altro channels. | |
927 | // The pedestal subtraction can be switched on and off | |
928 | // using an option of the TPC reconstructor | |
929 | //----------------------------------------------------------------- | |
930 | fRecoParam = AliTPCReconstructor::GetRecoParam(); | |
931 | if (!fRecoParam){ | |
932 | AliFatal("Can not get the reconstruction parameters"); | |
933 | } | |
934 | if(AliTPCReconstructor::StreamLevel()>5) { | |
935 | AliInfo("Parameter Dumps"); | |
936 | fParam->Dump(); | |
937 | fRecoParam->Dump(); | |
938 | } | |
939 | fRowDig = NULL; | |
940 | ||
941 | AliTPCCalPad * gainTPC = AliTPCcalibDB::Instance()->GetPadGainFactor(); | |
942 | AliTPCAltroMapping** mapping =AliTPCcalibDB::Instance()->GetMapping(); | |
943 | // | |
944 | AliTPCRawStreamV3 input(rawReader,(AliAltroMapping**)mapping); | |
945 | fEventHeader = (AliRawEventHeaderBase*)rawReader->GetEventHeader(); | |
946 | if (fEventHeader){ | |
947 | fTimeStamp = fEventHeader->Get("Timestamp"); | |
948 | fEventType = fEventHeader->Get("Type"); | |
949 | AliTPCTransform *transform = AliTPCcalibDB::Instance()->GetTransform() ; | |
950 | transform->SetCurrentTimeStamp(fTimeStamp); | |
951 | transform->SetCurrentRun(rawReader->GetRunNumber()); | |
952 | } | |
953 | ||
954 | // creaate one TClonesArray for all clusters | |
955 | if(fBClonesArray && !fOutputClonesArray) fOutputClonesArray = new TClonesArray("AliTPCclusterMI",1000); | |
956 | // reset counter | |
957 | fNclusters = 0; | |
958 | ||
959 | fMaxTime = fRecoParam->GetLastBin() + 6; // add 3 virtual time bins before and 3 after | |
960 | // const Int_t kNIS = fParam->GetNInnerSector(); | |
961 | // const Int_t kNOS = fParam->GetNOuterSector(); | |
962 | // const Int_t kNS = kNIS + kNOS; | |
963 | fZWidth = fParam->GetZWidth(); | |
964 | Int_t zeroSup = fParam->GetZeroSup(); | |
965 | // | |
966 | // Clean-up | |
967 | // | |
968 | AliTPCROC * roc = AliTPCROC::Instance(); | |
969 | Int_t nRowsMax = roc->GetNRows(roc->GetNSector()-1); | |
970 | Int_t nPadsMax = roc->GetNPads(roc->GetNSector()-1,nRowsMax-1); | |
971 | for (Int_t iRow = 0; iRow < nRowsMax; iRow++) { | |
972 | // | |
973 | Int_t maxBin = fMaxTime*(nPadsMax+6); // add 3 virtual pads before and 3 after | |
974 | memset(fAllBins[iRow],0,sizeof(Float_t)*maxBin); | |
975 | fAllNSigBins[iRow]=0; | |
976 | } | |
977 | ||
978 | Int_t prevSector=-1; | |
979 | rawReader->Reset(); | |
980 | Int_t digCounter=0; | |
981 | // | |
982 | // Loop over DDLs | |
983 | // | |
984 | const Int_t kNIS = fParam->GetNInnerSector(); | |
985 | const Int_t kNOS = fParam->GetNOuterSector(); | |
986 | const Int_t kNS = kNIS + kNOS; | |
987 | ||
988 | for(fSector = 0; fSector < kNS; fSector++) { | |
989 | ||
990 | Int_t nRows = 0; | |
991 | Int_t nDDLs = 0, indexDDL = 0; | |
992 | if (fSector < kNIS) { | |
993 | nRows = fParam->GetNRowLow(); | |
994 | fSign = (fSector < kNIS/2) ? 1 : -1; | |
995 | nDDLs = 2; | |
996 | indexDDL = fSector * 2; | |
997 | } | |
998 | else { | |
999 | nRows = fParam->GetNRowUp(); | |
1000 | fSign = ((fSector-kNIS) < kNOS/2) ? 1 : -1; | |
1001 | nDDLs = 4; | |
1002 | indexDDL = (fSector-kNIS) * 4 + kNIS * 2; | |
1003 | } | |
1004 | ||
1005 | // load the raw data for corresponding DDLs | |
1006 | rawReader->Reset(); | |
1007 | rawReader->Select("TPC",indexDDL,indexDDL+nDDLs-1); | |
1008 | ||
1009 | while (input.NextDDL()){ | |
1010 | if (input.GetSector() != fSector) | |
1011 | AliFatal(Form("Sector index mismatch ! Expected (%d), but got (%d) !",fSector,input.GetSector())); | |
1012 | ||
1013 | //Int_t nRows = fParam->GetNRow(fSector); | |
1014 | ||
1015 | AliTPCCalROC * gainROC = gainTPC->GetCalROC(fSector); // pad gains per given sector | |
1016 | // Begin loop over altro data | |
1017 | Bool_t calcPedestal = fRecoParam->GetCalcPedestal(); | |
1018 | Float_t gain =1; | |
1019 | ||
1020 | //loop over pads | |
1021 | while ( input.NextChannel() ) { | |
1022 | Int_t iRow = input.GetRow(); | |
1023 | if (iRow < 0){ | |
1024 | continue; | |
1025 | } | |
1026 | if (iRow >= nRows){ | |
1027 | AliError(Form("Pad-row index (%d) outside the range (%d -> %d) !", | |
1028 | iRow, 0, nRows -1)); | |
1029 | continue; | |
1030 | } | |
1031 | //pad | |
1032 | Int_t iPad = input.GetPad(); | |
1033 | if (iPad < 0 || iPad >= nPadsMax) { | |
1034 | AliError(Form("Pad index (%d) outside the range (%d -> %d) !", | |
1035 | iPad, 0, nPadsMax-1)); | |
1036 | continue; | |
1037 | } | |
1038 | gain = gainROC->GetValue(iRow,iPad); | |
1039 | iPad+=3; | |
1040 | ||
1041 | //loop over bunches | |
1042 | while ( input.NextBunch() ){ | |
1043 | Int_t startTbin = (Int_t)input.GetStartTimeBin(); | |
1044 | Int_t bunchlength = (Int_t)input.GetBunchLength(); | |
1045 | const UShort_t *sig = input.GetSignals(); | |
1046 | for (Int_t iTime = 0; iTime<bunchlength; iTime++){ | |
1047 | Int_t iTimeBin=startTbin-iTime; | |
1048 | if ( iTimeBin < fRecoParam->GetFirstBin() || iTimeBin >= fRecoParam->GetLastBin()){ | |
1049 | continue; | |
1050 | AliFatal(Form("Timebin index (%d) outside the range (%d -> %d) !", | |
1051 | iTimeBin, 0, iTimeBin -1)); | |
1052 | } | |
1053 | iTimeBin+=3; | |
1054 | //signal | |
1055 | Float_t signal=(Float_t)sig[iTime]; | |
1056 | if (!calcPedestal && signal <= zeroSup) continue; | |
1057 | ||
1058 | if (!calcPedestal) { | |
1059 | Int_t bin = iPad*fMaxTime+iTimeBin; | |
1060 | if (gain>0){ | |
1061 | fAllBins[iRow][bin] = signal/gain; | |
1062 | }else{ | |
1063 | fAllBins[iRow][bin] =0; | |
1064 | } | |
1065 | fAllSigBins[iRow][fAllNSigBins[iRow]++] = bin; | |
1066 | }else{ | |
1067 | fAllBins[iRow][iPad*fMaxTime+iTimeBin] = signal; | |
1068 | } | |
1069 | fAllBins[iRow][iPad*fMaxTime+0]+=1.; // pad with signal | |
1070 | ||
1071 | // Temporary | |
1072 | digCounter++; | |
1073 | }// end loop signals in bunch | |
1074 | }// end loop bunches | |
1075 | } // end loop pads | |
1076 | // | |
1077 | // | |
1078 | // | |
1079 | // | |
1080 | // Now loop over rows and perform pedestal subtraction | |
1081 | if (digCounter==0) continue; | |
1082 | } // End of loop over sectors | |
1083 | //process last sector | |
1084 | if ( digCounter>0 ){ | |
1085 | ProcessSectorData(); | |
1086 | for (Int_t iRow = 0; iRow < fParam->GetNRow(fSector); iRow++) { | |
1087 | Int_t maxPad = fParam->GetNPads(fSector,iRow); | |
1088 | Int_t maxBin = fMaxTime*(maxPad+6); // add 3 virtual pads before and 3 after | |
1089 | memset(fAllBins[iRow],0,sizeof(Float_t)*maxBin); | |
1090 | fAllNSigBins[iRow] = 0; | |
1091 | } | |
1092 | prevSector=fSector; | |
1093 | digCounter=0; | |
1094 | } | |
1095 | } | |
1096 | ||
1097 | if (rawReader->GetEventId() && fOutput ){ | |
1098 | Info("Digits2Clusters", "File %s Event\t%u\tNumber of found clusters : %d\n", fOutput->GetName(),*(rawReader->GetEventId()), fNclusters); | |
1099 | } | |
1100 | ||
1101 | if(rawReader->GetEventId()) { | |
1102 | Info("Digits2Clusters", "Event\t%u\tNumber of found clusters : %d\n",*(rawReader->GetEventId()), fNclusters); | |
1103 | } | |
1104 | ||
1105 | if(fBClonesArray) { | |
1106 | //Info("Digits2Clusters", "Number of found clusters : %d\n",fOutputClonesArray->GetEntriesFast()); | |
1107 | } | |
1108 | } | |
1109 | ||
1110 | ||
1111 | ||
1112 | ||
1113 | ||
1114 | void AliTPCclustererMI::Digits2ClustersOld | |
1115 | (AliRawReader* rawReader) | |
1116 | { | |
1117 | //----------------------------------------------------------------- | |
1118 | // This is a cluster finder for the TPC raw data. | |
1119 | // The method assumes NO ordering of the altro channels. | |
1120 | // The pedestal subtraction can be switched on and off | |
1121 | // using an option of the TPC reconstructor | |
1122 | //----------------------------------------------------------------- | |
1123 | fRecoParam = AliTPCReconstructor::GetRecoParam(); | |
1124 | if (!fRecoParam){ | |
1125 | AliFatal("Can not get the reconstruction parameters"); | |
1126 | } | |
1127 | if(AliTPCReconstructor::StreamLevel()>5) { | |
1128 | AliInfo("Parameter Dumps"); | |
1129 | fParam->Dump(); | |
1130 | fRecoParam->Dump(); | |
1131 | } | |
1132 | fRowDig = NULL; | |
1133 | ||
1134 | AliTPCCalPad * gainTPC = AliTPCcalibDB::Instance()->GetPadGainFactor(); | |
1135 | AliTPCAltroMapping** mapping =AliTPCcalibDB::Instance()->GetMapping(); | |
1136 | // | |
1137 | AliTPCRawStream input(rawReader,(AliAltroMapping**)mapping); | |
1138 | fEventHeader = (AliRawEventHeaderBase*)rawReader->GetEventHeader(); | |
1139 | if (fEventHeader){ | |
1140 | fTimeStamp = fEventHeader->Get("Timestamp"); | |
1141 | fEventType = fEventHeader->Get("Type"); | |
1142 | } | |
1143 | ||
1144 | // creaate one TClonesArray for all clusters | |
1145 | if(fBClonesArray && !fOutputClonesArray) fOutputClonesArray = new TClonesArray("AliTPCclusterMI",1000); | |
1146 | // reset counter | |
1147 | fNclusters = 0; | |
1148 | ||
1149 | fMaxTime = fRecoParam->GetLastBin() + 6; // add 3 virtual time bins before and 3 after | |
1150 | const Int_t kNIS = fParam->GetNInnerSector(); | |
1151 | const Int_t kNOS = fParam->GetNOuterSector(); | |
1152 | const Int_t kNS = kNIS + kNOS; | |
1153 | fZWidth = fParam->GetZWidth(); | |
1154 | Int_t zeroSup = fParam->GetZeroSup(); | |
1155 | // | |
1156 | // Clean-up | |
1157 | // | |
1158 | ||
1159 | AliTPCROC * roc = AliTPCROC::Instance(); | |
1160 | Int_t nRowsMax = roc->GetNRows(roc->GetNSector()-1); | |
1161 | Int_t nPadsMax = roc->GetNPads(roc->GetNSector()-1,nRowsMax-1); | |
1162 | for (Int_t iRow = 0; iRow < nRowsMax; iRow++) { | |
1163 | // | |
1164 | Int_t maxBin = fMaxTime*(nPadsMax+6); // add 3 virtual pads before and 3 after | |
1165 | memset(fAllBins[iRow],0,sizeof(Float_t)*maxBin); | |
1166 | fAllNSigBins[iRow]=0; | |
1167 | } | |
1168 | // | |
1169 | // Loop over sectors | |
1170 | // | |
1171 | for(fSector = 0; fSector < kNS; fSector++) { | |
1172 | ||
1173 | Int_t nRows = 0; | |
1174 | Int_t nDDLs = 0, indexDDL = 0; | |
1175 | if (fSector < kNIS) { | |
1176 | nRows = fParam->GetNRowLow(); | |
1177 | fSign = (fSector < kNIS/2) ? 1 : -1; | |
1178 | nDDLs = 2; | |
1179 | indexDDL = fSector * 2; | |
1180 | } | |
1181 | else { | |
1182 | nRows = fParam->GetNRowUp(); | |
1183 | fSign = ((fSector-kNIS) < kNOS/2) ? 1 : -1; | |
1184 | nDDLs = 4; | |
1185 | indexDDL = (fSector-kNIS) * 4 + kNIS * 2; | |
1186 | } | |
1187 | ||
1188 | // load the raw data for corresponding DDLs | |
1189 | rawReader->Reset(); | |
1190 | rawReader->Select("TPC",indexDDL,indexDDL+nDDLs-1); | |
1191 | ||
1192 | // select only good sector | |
1193 | input.Next(); | |
1194 | if(input.GetSector() != fSector) continue; | |
1195 | ||
1196 | AliTPCCalROC * gainROC = gainTPC->GetCalROC(fSector); // pad gains per given sector | |
1197 | ||
1198 | for (Int_t iRow = 0; iRow < nRows; iRow++) { | |
1199 | Int_t maxPad; | |
1200 | if (fSector < kNIS) | |
1201 | maxPad = fParam->GetNPadsLow(iRow); | |
1202 | else | |
1203 | maxPad = fParam->GetNPadsUp(iRow); | |
1204 | ||
1205 | Int_t maxBin = fMaxTime*(maxPad+6); // add 3 virtual pads before and 3 after | |
1206 | memset(fAllBins[iRow],0,sizeof(Float_t)*maxBin); | |
1207 | fAllNSigBins[iRow] = 0; | |
1208 | } | |
1209 | ||
1210 | Int_t digCounter=0; | |
1211 | // Begin loop over altro data | |
1212 | Bool_t calcPedestal = fRecoParam->GetCalcPedestal(); | |
1213 | Float_t gain =1; | |
1214 | Int_t lastPad=-1; | |
1215 | ||
1216 | input.Reset(); | |
1217 | while (input.Next()) { | |
1218 | if (input.GetSector() != fSector) | |
1219 | AliFatal(Form("Sector index mismatch ! Expected (%d), but got (%d) !",fSector,input.GetSector())); | |
1220 | ||
1221 | ||
1222 | Int_t iRow = input.GetRow(); | |
1223 | if (iRow < 0){ | |
1224 | continue; | |
1225 | } | |
1226 | ||
1227 | if (iRow < 0 || iRow >= nRows){ | |
1228 | AliError(Form("Pad-row index (%d) outside the range (%d -> %d) !", | |
1229 | iRow, 0, nRows -1)); | |
1230 | continue; | |
1231 | } | |
1232 | //pad | |
1233 | Int_t iPad = input.GetPad(); | |
1234 | if (iPad < 0 || iPad >= nPadsMax) { | |
1235 | AliError(Form("Pad index (%d) outside the range (%d -> %d) !", | |
1236 | iPad, 0, nPadsMax-1)); | |
1237 | continue; | |
1238 | } | |
1239 | if (iPad!=lastPad){ | |
1240 | gain = gainROC->GetValue(iRow,iPad); | |
1241 | lastPad = iPad; | |
1242 | } | |
1243 | iPad+=3; | |
1244 | //time | |
1245 | Int_t iTimeBin = input.GetTime(); | |
1246 | if ( iTimeBin < fRecoParam->GetFirstBin() || iTimeBin >= fRecoParam->GetLastBin()){ | |
1247 | continue; | |
1248 | AliFatal(Form("Timebin index (%d) outside the range (%d -> %d) !", | |
1249 | iTimeBin, 0, iTimeBin -1)); | |
1250 | } | |
1251 | iTimeBin+=3; | |
1252 | ||
1253 | //signal | |
1254 | Float_t signal = input.GetSignal(); | |
1255 | if (!calcPedestal && signal <= zeroSup) continue; | |
1256 | ||
1257 | if (!calcPedestal) { | |
1258 | Int_t bin = iPad*fMaxTime+iTimeBin; | |
1259 | if (gain>0){ | |
1260 | fAllBins[iRow][bin] = signal/gain; | |
1261 | }else{ | |
1262 | fAllBins[iRow][bin] =0; | |
1263 | } | |
1264 | fAllSigBins[iRow][fAllNSigBins[iRow]++] = bin; | |
1265 | }else{ | |
1266 | fAllBins[iRow][iPad*fMaxTime+iTimeBin] = signal; | |
1267 | } | |
1268 | fAllBins[iRow][iPad*fMaxTime+0]+=1.; // pad with signal | |
1269 | ||
1270 | // Temporary | |
1271 | digCounter++; | |
1272 | } // End of the loop over altro data | |
1273 | // | |
1274 | // | |
1275 | // | |
1276 | // | |
1277 | // Now loop over rows and perform pedestal subtraction | |
1278 | if (digCounter==0) continue; | |
1279 | ProcessSectorData(); | |
1280 | } // End of loop over sectors | |
1281 | ||
1282 | if (rawReader->GetEventId() && fOutput ){ | |
1283 | Info("Digits2Clusters", "File %s Event\t%d\tNumber of found clusters : %d\n", fOutput->GetName(),*(rawReader->GetEventId()), fNclusters); | |
1284 | } | |
1285 | ||
1286 | if(rawReader->GetEventId()) { | |
1287 | Info("Digits2Clusters", "Event\t%d\tNumber of found clusters : %d\n",*(rawReader->GetEventId()), fNclusters); | |
1288 | } | |
1289 | ||
1290 | if(fBClonesArray) { | |
1291 | //Info("Digits2Clusters", "Number of found clusters : %d\n",fOutputClonesArray->GetEntriesFast()); | |
1292 | } | |
1293 | } | |
1294 | ||
1295 | void AliTPCclustererMI::FindClusters(AliTPCCalROC * noiseROC) | |
1296 | { | |
1297 | ||
1298 | // | |
1299 | // add virtual charge at the edge | |
1300 | // | |
1301 | Double_t kMaxDumpSize = 500000; | |
1302 | if (!fOutput) { | |
1303 | fBDumpSignal =kFALSE; | |
1304 | }else{ | |
1305 | if (fRecoParam->GetCalcPedestal() && fOutput->GetZipBytes()< kMaxDumpSize) fBDumpSignal =kTRUE; //dump signal flag | |
1306 | } | |
1307 | ||
1308 | fNcluster=0; | |
1309 | fLoop=1; | |
1310 | Int_t crtime = Int_t((fParam->GetZLength(fSector)-fRecoParam->GetCtgRange()*fRx)/fZWidth-fParam->GetNTBinsL1()-5); | |
1311 | Float_t minMaxCutAbs = fRecoParam->GetMinMaxCutAbs(); | |
1312 | Float_t minLeftRightCutAbs = fRecoParam->GetMinLeftRightCutAbs(); | |
1313 | Float_t minUpDownCutAbs = fRecoParam->GetMinUpDownCutAbs(); | |
1314 | Float_t minMaxCutSigma = fRecoParam->GetMinMaxCutSigma(); | |
1315 | Float_t minLeftRightCutSigma = fRecoParam->GetMinLeftRightCutSigma(); | |
1316 | Float_t minUpDownCutSigma = fRecoParam->GetMinUpDownCutSigma(); | |
1317 | Int_t useOnePadCluster = fRecoParam->GetUseOnePadCluster(); | |
1318 | for (Int_t iSig = 0; iSig < fNSigBins; iSig++) { | |
1319 | Int_t i = fSigBins[iSig]; | |
1320 | if (i%fMaxTime<=crtime) continue; | |
1321 | Float_t *b = &fBins[i]; | |
1322 | //absolute custs | |
1323 | if (b[0]<minMaxCutAbs) continue; //threshold for maxima | |
1324 | // | |
1325 | if (useOnePadCluster==0){ | |
1326 | if (b[-1]+b[1]+b[-fMaxTime]+b[fMaxTime]<=0) continue; // cut on isolated clusters | |
1327 | if (b[-1]+b[1]<=0) continue; // cut on isolated clusters | |
1328 | if (b[-fMaxTime]+b[fMaxTime]<=0) continue; // cut on isolated clusters | |
1329 | } | |
1330 | // | |
1331 | if ((b[0]+b[-1]+b[1])<minUpDownCutAbs) continue; //threshold for up down (TRF) | |
1332 | if ((b[0]+b[-fMaxTime]+b[fMaxTime])<minLeftRightCutAbs) continue; //threshold for left right (PRF) | |
1333 | if (!IsMaximum(*b,fMaxTime,b)) continue; | |
1334 | // | |
1335 | Float_t noise = noiseROC->GetValue(fRow, i/fMaxTime); | |
1336 | if (noise>fRecoParam->GetMaxNoise()) continue; | |
1337 | // sigma cuts | |
1338 | if (b[0]<minMaxCutSigma*noise) continue; //threshold form maxima | |
1339 | if ((b[0]+b[-1]+b[1])<minUpDownCutSigma*noise) continue; //threshold for up town TRF | |
1340 | if ((b[0]+b[-fMaxTime]+b[fMaxTime])<minLeftRightCutSigma*noise) continue; //threshold for left right (PRF) | |
1341 | ||
1342 | AliTPCclusterMI c; // default cosntruction without info | |
1343 | Int_t dummy=0; | |
1344 | MakeCluster(i, fMaxTime, fBins, dummy,c); | |
1345 | ||
1346 | //} | |
1347 | } | |
1348 | } | |
1349 | ||
1350 | Bool_t AliTPCclustererMI::AcceptCluster(AliTPCclusterMI *cl){ | |
1351 | // | |
1352 | // Currently hack to filter digital noise (15.06.2008) | |
1353 | // To be parameterized in the AliTPCrecoParam | |
1354 | // More inteligent way to be used in future | |
1355 | // Acces to the proper pedestal file needed | |
1356 | // | |
1357 | if (cl->GetMax()<400) return kTRUE; | |
1358 | Double_t ratio = cl->GetQ()/cl->GetMax(); | |
1359 | if (cl->GetMax()>700){ | |
1360 | if ((ratio - int(ratio)>0.8)) return kFALSE; | |
1361 | } | |
1362 | if ((ratio - int(ratio)<0.95)) return kTRUE; | |
1363 | return kFALSE; | |
1364 | } | |
1365 | ||
1366 | ||
1367 | Double_t AliTPCclustererMI::ProcesSignal(Float_t *signal, Int_t nchannels, Int_t id[3], Double_t &rmsEvent, Double_t &pedestalEvent){ | |
1368 | // | |
1369 | // process signal on given pad - + streaming of additional information in special mode | |
1370 | // | |
1371 | // id[0] - sector | |
1372 | // id[1] - row | |
1373 | // id[2] - pad | |
1374 | ||
1375 | // | |
1376 | // ESTIMATE pedestal and the noise | |
1377 | // | |
1378 | const Int_t kPedMax = 100; | |
1379 | Float_t max = 0; | |
1380 | Float_t maxPos = 0; | |
1381 | Int_t median = -1; | |
1382 | Int_t count0 = 0; | |
1383 | Int_t count1 = 0; | |
1384 | Float_t rmsCalib = rmsEvent; // backup initial value ( from calib) | |
1385 | Float_t pedestalCalib = pedestalEvent;// backup initial value ( from calib) | |
1386 | Int_t firstBin = fRecoParam->GetFirstBin(); | |
1387 | // | |
1388 | UShort_t histo[kPedMax]; | |
1389 | //memset(histo,0,kPedMax*sizeof(UShort_t)); | |
1390 | for (Int_t i=0; i<kPedMax; i++) histo[i]=0; | |
1391 | for (Int_t i=0; i<fMaxTime; i++){ | |
1392 | if (signal[i]<=0) continue; | |
1393 | if (signal[i]>max && i>firstBin) { | |
1394 | max = signal[i]; | |
1395 | maxPos = i; | |
1396 | } | |
1397 | if (signal[i]>kPedMax-1) continue; | |
1398 | histo[int(signal[i]+0.5)]++; | |
1399 | count0++; | |
1400 | } | |
1401 | // | |
1402 | for (Int_t i=1; i<kPedMax; i++){ | |
1403 | if (count1<count0*0.5) median=i; | |
1404 | count1+=histo[i]; | |
1405 | } | |
1406 | // truncated mean | |
1407 | // | |
1408 | Float_t count10=histo[median] ,mean=histo[median]*median, rms=histo[median]*median*median ; | |
1409 | Float_t count06=histo[median] ,mean06=histo[median]*median, rms06=histo[median]*median*median ; | |
1410 | Float_t count09=histo[median] ,mean09=histo[median]*median, rms09=histo[median]*median*median ; | |
1411 | // | |
1412 | for (Int_t idelta=1; idelta<10; idelta++){ | |
1413 | if (median-idelta<=0) continue; | |
1414 | if (median+idelta>kPedMax) continue; | |
1415 | if (count06<0.6*count1){ | |
1416 | count06+=histo[median-idelta]; | |
1417 | mean06 +=histo[median-idelta]*(median-idelta); | |
1418 | rms06 +=histo[median-idelta]*(median-idelta)*(median-idelta); | |
1419 | count06+=histo[median+idelta]; | |
1420 | mean06 +=histo[median+idelta]*(median+idelta); | |
1421 | rms06 +=histo[median+idelta]*(median+idelta)*(median+idelta); | |
1422 | } | |
1423 | if (count09<0.9*count1){ | |
1424 | count09+=histo[median-idelta]; | |
1425 | mean09 +=histo[median-idelta]*(median-idelta); | |
1426 | rms09 +=histo[median-idelta]*(median-idelta)*(median-idelta); | |
1427 | count09+=histo[median+idelta]; | |
1428 | mean09 +=histo[median+idelta]*(median+idelta); | |
1429 | rms09 +=histo[median+idelta]*(median+idelta)*(median+idelta); | |
1430 | } | |
1431 | if (count10<0.95*count1){ | |
1432 | count10+=histo[median-idelta]; | |
1433 | mean +=histo[median-idelta]*(median-idelta); | |
1434 | rms +=histo[median-idelta]*(median-idelta)*(median-idelta); | |
1435 | count10+=histo[median+idelta]; | |
1436 | mean +=histo[median+idelta]*(median+idelta); | |
1437 | rms +=histo[median+idelta]*(median+idelta)*(median+idelta); | |
1438 | } | |
1439 | } | |
1440 | if (count10) { | |
1441 | mean /=count10; | |
1442 | rms = TMath::Sqrt(TMath::Abs(rms/count10-mean*mean)); | |
1443 | } | |
1444 | if (count06) { | |
1445 | mean06/=count06; | |
1446 | rms06 = TMath::Sqrt(TMath::Abs(rms06/count06-mean06*mean06)); | |
1447 | } | |
1448 | if (count09) { | |
1449 | mean09/=count09; | |
1450 | rms09 = TMath::Sqrt(TMath::Abs(rms09/count09-mean09*mean09)); | |
1451 | } | |
1452 | rmsEvent = rms09; | |
1453 | // | |
1454 | pedestalEvent = median; | |
1455 | if (AliLog::GetDebugLevel("","AliTPCclustererMI")==0) return median; | |
1456 | // | |
1457 | UInt_t uid[3] = {UInt_t(id[0]),UInt_t(id[1]),UInt_t(id[2])}; | |
1458 | // | |
1459 | // Dump mean signal info | |
1460 | // | |
1461 | if (AliTPCReconstructor::StreamLevel()>0) { | |
1462 | (*fDebugStreamer)<<"Signal"<< | |
1463 | "TimeStamp="<<fTimeStamp<< | |
1464 | "EventType="<<fEventType<< | |
1465 | "Sector="<<uid[0]<< | |
1466 | "Row="<<uid[1]<< | |
1467 | "Pad="<<uid[2]<< | |
1468 | "Max="<<max<< | |
1469 | "MaxPos="<<maxPos<< | |
1470 | // | |
1471 | "Median="<<median<< | |
1472 | "Mean="<<mean<< | |
1473 | "RMS="<<rms<< | |
1474 | "Mean06="<<mean06<< | |
1475 | "RMS06="<<rms06<< | |
1476 | "Mean09="<<mean09<< | |
1477 | "RMS09="<<rms09<< | |
1478 | "RMSCalib="<<rmsCalib<< | |
1479 | "PedCalib="<<pedestalCalib<< | |
1480 | "\n"; | |
1481 | } | |
1482 | // | |
1483 | // fill pedestal histogram | |
1484 | // | |
1485 | // | |
1486 | // | |
1487 | // | |
1488 | Float_t kMin =fRecoParam->GetDumpAmplitudeMin(); // minimal signal to be dumped | |
1489 | Float_t *dsignal = new Float_t[nchannels]; | |
1490 | Float_t *dtime = new Float_t[nchannels]; | |
1491 | for (Int_t i=0; i<nchannels; i++){ | |
1492 | dtime[i] = i; | |
1493 | dsignal[i] = signal[i]; | |
1494 | } | |
1495 | ||
1496 | TGraph * graph=0; | |
1497 | // | |
1498 | // Big signals dumping | |
1499 | // | |
1500 | if (AliTPCReconstructor::StreamLevel()>0) { | |
1501 | if (max-median>kMin &&maxPos>fRecoParam->GetFirstBin()) | |
1502 | (*fDebugStreamer)<<"SignalB"<< // pads with signal | |
1503 | "TimeStamp="<<fTimeStamp<< | |
1504 | "EventType="<<fEventType<< | |
1505 | "Sector="<<uid[0]<< | |
1506 | "Row="<<uid[1]<< | |
1507 | "Pad="<<uid[2]<< | |
1508 | "Graph="<<graph<< | |
1509 | "Max="<<max<< | |
1510 | "MaxPos="<<maxPos<< | |
1511 | // | |
1512 | "Median="<<median<< | |
1513 | "Mean="<<mean<< | |
1514 | "RMS="<<rms<< | |
1515 | "Mean06="<<mean06<< | |
1516 | "RMS06="<<rms06<< | |
1517 | "Mean09="<<mean09<< | |
1518 | "RMS09="<<rms09<< | |
1519 | "\n"; | |
1520 | delete graph; | |
1521 | } | |
1522 | ||
1523 | delete [] dsignal; | |
1524 | delete [] dtime; | |
1525 | if (rms06>fRecoParam->GetMaxNoise()) { | |
1526 | pedestalEvent+=1024.; | |
1527 | return 1024+median; // sign noisy channel in debug mode | |
1528 | } | |
1529 | return median; | |
1530 | } | |
1531 | ||
1532 | ||
1533 | ||
1534 | ||
1535 |