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75d8233f | 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 | ||
75d8233f | 16 | /* $Id$ */ |
17 | ||
3cd27a08 | 18 | //////////////////////////////////////////////////////////////////////////////////////// |
19 | // // | |
20 | // Implementation of the TPC Central Electrode calibration // | |
21 | // // | |
22 | // Origin: Jens Wiechula, Marian Ivanov J.Wiechula@gsi.de, Marian.Ivanov@cern.ch // | |
23 | // // | |
24 | //////////////////////////////////////////////////////////////////////////////////////// | |
7fb602b1 | 25 | // |
26 | // | |
27 | // ************************************************************************************* | |
28 | // * Class Description * | |
29 | // ************************************************************************************* | |
30 | // | |
31 | /* BEGIN_HTML | |
32 | <h4>The AliTPCCalibCE class is used to get calibration data from the Central Electrode | |
33 | using laser runs.</h4> | |
34 | ||
35 | The information retrieved is | |
36 | <ul style="list-style-type: square;"> | |
37 | <li>Time arrival from the CE</li> | |
38 | <li>Signal width</li> | |
39 | <li>Signal sum</li> | |
40 | </ul> | |
41 | ||
42 | <h4>Overview:</h4> | |
43 | <ol style="list-style-type: upper-roman;"> | |
44 | <li><a href="#working">Working principle</a></li> | |
45 | <li><a href="#user">User interface for filling data</a></li> | |
46 | <li><a href="#info">Stored information</a></li> | |
47 | </ol> | |
48 | ||
49 | <h3><a name="working">I. Working principle</a></h3> | |
50 | ||
51 | <h4>Raw laser data is processed by calling one of the ProcessEvent(...) functions | |
52 | (see below). These in the end call the Update(...) function.</h4> | |
53 | ||
54 | <ul style="list-style-type: square;"> | |
55 | <li>the Update(...) function:<br /> | |
56 | In this function the array fPadSignal is filled with the adc signals between the specified range | |
57 | fFirstTimeBin and fLastTimeBin for the current pad. | |
58 | before going to the next pad the ProcessPad() function is called, which analyses the data for one pad | |
59 | stored in fPadSignal. | |
60 | </li> | |
61 | <ul style="list-style-type: square;"> | |
62 | <li>the ProcessPad() function:</li> | |
63 | <ol style="list-style-type: decimal;"> | |
64 | <li>Find Pedestal and Noise information</li> | |
65 | <ul style="list-style-type: square;"> | |
66 | <li>use database information which has to be set by calling<br /> | |
67 | SetPedestalDatabase(AliTPCCalPad *pedestalTPC, AliTPCCalPad *padNoiseTPC)</li> | |
68 | <li>if no information from the pedestal data base | |
69 | is available the informaion is calculated on the fly | |
70 | ( see FindPedestal() function )</li> | |
71 | </ul> | |
72 | <li>Find local maxima of the pad signal</li> | |
73 | <ul style="list-style-type: square;"> | |
74 | <li>maxima arise from the laser tracks, the CE and also periodic postpeaks after the CE signal have | |
75 | have been observed ( see FindLocalMaxima(...) )</li> | |
76 | </ul> | |
77 | <li>Find the CE signal information</li> | |
78 | <ul style="list-style-type: square;"> | |
79 | <li>to find the position of the CE signal the Tmean information from the previos event is used | |
80 | as the CE signal the local maximum closest to this Tmean is identified</li> | |
81 | <li>calculate mean = T0, RMS = signal width and Q sum in a range of -4+7 timebins around Q max position | |
82 | the Q sum is scaled by pad area (see FindPulserSignal(...) function)</li> | |
83 | </ul> | |
84 | <li>Fill a temprary array for the T0 information (GetPadTimesEvent(fCurrentSector,kTRUE)) (why see below)</li> | |
85 | <li>Fill the Q sum and RMS values in the histograms (GetHisto[RMS,Q](ROC,kTRUE))</li> | |
86 | </ol> | |
87 | </ul> | |
88 | </ul> | |
89 | ||
90 | <h4>At the end of each event the EndEvent() function is called</h4> | |
91 | ||
92 | <ul style="list-style-type: square;"> | |
93 | <li>the EndEvent() function:</li> | |
94 | <ul style="list-style-type: square;"> | |
95 | <li>calculate the mean T0 for side A and side C. Fill T0 histogram with Time0-<Time0 for side[A,C]> | |
96 | This is done to overcome syncronisation problems between the trigger and the fec clock.</li> | |
97 | <li>calculate Mean T for each ROC using the COG aroud the median of the LocalMaxima distribution in one sector</li> | |
98 | <li>calculate Mean Q</li> | |
99 | <li>calculate Global fit parameters for Pol1 and Pol2 fits</li> | |
100 | </ul> | |
101 | </ul> | |
102 | ||
103 | <h4>After accumulating the desired statistics the Analyse() function has to be called.</h4> | |
104 | <ul style="list-style-type: square;"> | |
105 | <li>the Analyse() function:</li> | |
106 | <ul style="list-style-type: square;"> | |
107 | <li>calculate the mean values of T0, RMS, Q for each pad, using | |
108 | the AliMathBase::GetCOG(...) function</li> | |
109 | <li>fill the calibration storage classes (AliTPCCalROC) for each ROC</li> | |
110 | (The calibration information is stored in the TObjArrays fCalRocArrayT0, fCalRocArrayRMS and fCalRocArrayQ</li> | |
111 | </ul> | |
112 | </ul> | |
113 | ||
114 | <h3><a name="user">II. User interface for filling data</a></h3> | |
115 | ||
116 | <h4>To Fill information one of the following functions can be used:</h4> | |
117 | ||
118 | <ul style="list-style-type: none;"> | |
119 | <li> Bool_t ProcessEvent(eventHeaderStruct *event);</li> | |
120 | <ul style="list-style-type: square;"> | |
121 | <li>process Date event</li> | |
122 | <li>use AliTPCRawReaderDate and call ProcessEvent(AliRawReader *rawReader)</li> | |
123 | </ul> | |
124 | <br /> | |
125 | ||
126 | <li> Bool_t ProcessEvent(AliRawReader *rawReader);</li> | |
127 | <ul style="list-style-type: square;"> | |
128 | <li>process AliRawReader event</li> | |
129 | <li>use AliTPCRawStream to loop over data and call ProcessEvent(AliTPCRawStream *rawStream)</li> | |
130 | </ul> | |
131 | <br /> | |
132 | ||
133 | <li> Bool_t ProcessEvent(AliTPCRawStream *rawStream);</li> | |
134 | <ul style="list-style-type: square;"> | |
135 | <li>process event from AliTPCRawStream</li> | |
136 | <li>call Update function for signal filling</li> | |
137 | </ul> | |
138 | <br /> | |
139 | ||
140 | <li> Int_t Update(const Int_t isector, const Int_t iRow, const Int_t | |
141 | iPad, const Int_t iTimeBin, const Float_t signal);</li> | |
142 | <ul style="list-style-type: square;"> | |
143 | <li>directly fill signal information (sector, row, pad, time bin, pad) | |
144 | to the reference histograms</li> | |
145 | </ul> | |
146 | </ul> | |
147 | ||
148 | <h4>It is also possible to merge two independently taken calibrations using the function</h4> | |
149 | ||
150 | <ul style="list-style-type: none;"> | |
151 | <li> void Merge(AliTPCCalibSignal *sig)</li> | |
152 | <ul style="list-style-type: square;"> | |
153 | <li>copy histograms in 'sig' if they do not exist in this instance</li> | |
154 | <li>Add histograms in 'sig' to the histograms in this instance if the allready exist</li> | |
155 | <li>After merging call Analyse again!</li> | |
156 | </ul> | |
157 | </ul> | |
158 | ||
159 | ||
160 | <h4>example: filling data using root raw data:</h4> | |
161 | <pre> | |
162 | void fillCE(Char_t *filename) | |
163 | { | |
164 | rawReader = new AliRawReaderRoot(fileName); | |
165 | if ( !rawReader ) return; | |
166 | AliTPCCalibCE *calib = new AliTPCCalibCE; | |
167 | while (rawReader->NextEvent()){ | |
168 | calib->ProcessEvent(rawReader); | |
169 | } | |
170 | calib->Analyse(); | |
171 | calib->DumpToFile("CEData.root"); | |
172 | delete rawReader; | |
173 | delete calib; | |
174 | } | |
175 | </pre> | |
176 | ||
177 | <h3><a name="info">III. What kind of information is stored and how to retrieve it</a></h4> | |
178 | ||
179 | <h4><a name="info:stored">III.1 Stored information</a></h4> | |
180 | <ul style="list-style-type: none;"> | |
181 | <li>Histograms:</li> | |
182 | <ul style="list-style-type: none;"> | |
183 | <li>For each ROC three TH2S histos 'Reference Histograms' (ROC channel vs. [Time0, signal width, Q sum]) | |
184 | is created when it is filled for the first time (GetHisto[T0,RMS,Q](ROC,kTRUE)). The histos are | |
185 | stored in the TObjArrays fHistoT0Array, fHistoRMSArray and fHistoQArray.</li> | |
186 | </ul> | |
187 | <br /> | |
188 | ||
189 | <li>Calibration Data:</li> | |
190 | <ul style="list-style-type: none;"> | |
191 | <li>For each ROC three types of calibration data (AliTPCCalROC) is stored: for the mean arrival Time, | |
192 | the signal width and the signal Sum. The AliTPCCalROC objects are stored in the TObjArrays | |
193 | fCalRocArrayT0, fCalRocArrayRMS , fCalRocArrayQ. The object for each roc is created the first time it | |
194 | is accessed (GetCalRoc[T0,RMS,Q](ROC,kTRUE));</li> | |
195 | </ul> | |
196 | <br /> | |
197 | ||
198 | <li>For each event the following information is stored:</li> | |
199 | ||
200 | <ul style="list-style-type: square;"> | |
201 | <li>event time ( TVectorD fVEventTime )</li> | |
202 | <li>event id ( TVectorD fVEventNumber )</li> | |
203 | <br /> | |
204 | <li>mean arrival time for each ROC ( TObjArray fTMeanArrayEvent )</li> | |
205 | <li>mean Q for each ROC ( TObjArray fQMeanArrayEvent )</li> | |
206 | <li>parameters of a plane fit for each ROC ( TObjArray fParamArrayEventPol1 )</li> | |
207 | <li>parameters of a 2D parabola fit for each ROC ( TObjArray fParamArrayEventPol2 )</li> | |
208 | </ul> | |
209 | </ul> | |
210 | ||
211 | <h4><a name="info:retrieve">III.2 Retrieving information</a></h4> | |
212 | <ul style="list-style-type: none;"> | |
213 | <li>Accessing the 'Reference Histograms' (Time0, signal width and Q sum information pad by pad):</li> | |
214 | <ul style="list-style-type: square;"> | |
215 | <li>TH2F *GetHistoT0(Int_t sector);</li> | |
216 | <li>TH2F *GetHistoRMS(Int_t sector);</li> | |
217 | <li>TH2F *GetHistoQ(Int_t sector);</li> | |
218 | </ul> | |
219 | <br /> | |
220 | ||
221 | <li>Accessing the calibration storage objects:</li> | |
222 | <ul style="list-style-type: square;"> | |
223 | <li>AliTPCCalROC *GetCalRocT0(Int_t sector); // for the Time0 values</li> | |
224 | <li>AliTPCCalROC *GetCalRocRMS(Int_t sector); // for the signal width values</li> | |
225 | <li>AliTPCCalROC *GetCalRocQ(Int_t sector); // for the Q sum values</li> | |
226 | </ul> | |
227 | <br /> | |
228 | ||
229 | <li>Accessin the event by event information:</li> | |
230 | <ul style="list-style-type: square;"> | |
231 | <li>The event by event information can be displayed using the</li> | |
232 | <li>MakeGraphTimeCE(Int_t sector, Int_t xVariable, Int_t fitType, Int_t fitParameter)</li> | |
233 | <li>which creates a graph from the specified variables</li> | |
234 | </ul> | |
235 | </ul> | |
236 | ||
237 | <h4>example for visualisation:</h4> | |
238 | <pre> | |
239 | //if the file "CEData.root" was created using the above example one could do the following: | |
240 | TFile fileCE("CEData.root") | |
241 | AliTPCCalibCE *ce = (AliTPCCalibCE*)fileCE->Get("AliTPCCalibCE"); | |
242 | ce->GetCalRocT0(0)->Draw("colz"); | |
243 | ce->GetCalRocRMS(0)->Draw("colz"); | |
244 | ||
245 | //or use the AliTPCCalPad functionality: | |
246 | AliTPCCalPad padT0(ped->GetCalPadT0()); | |
247 | AliTPCCalPad padSigWidth(ped->GetCalPadRMS()); | |
248 | padT0->MakeHisto2D()->Draw("colz"); //Draw A-Side Time0 Information | |
249 | padSigWidth->MakeHisto2D()->Draw("colz"); //Draw A-Side signal width Information | |
250 | ||
251 | //display event by event information: | |
252 | //Draw mean arrival time as a function of the event time for oroc sector A00 | |
253 | ce->MakeGraphTimeCE(36, 0, 2)->Draw("alp"); | |
254 | //Draw first derivative in local x from a plane fit as a function of the event time for oroc sector A00 | |
255 | ce->MakeGraphTimeCE(36, 0, 0, 1)->Draw("alp"); | |
256 | </pre> | |
257 | END_HTML */ | |
258 | ////////////////////////////////////////////////////////////////////////////////////// | |
259 | ||
260 | ||
3cd27a08 | 261 | //Root includes |
262 | #include <TObjArray.h> | |
78f17711 | 263 | #include <TH1.h> |
3cd27a08 | 264 | #include <TH1F.h> |
265 | #include <TH2S.h> | |
78f17711 | 266 | #include <TF1.h> |
3cd27a08 | 267 | #include <TString.h> |
268 | #include <TVectorF.h> | |
269 | #include <TVectorD.h> | |
78f17711 | 270 | #include <TVector3.h> |
3cd27a08 | 271 | #include <TMatrixD.h> |
272 | #include <TMath.h> | |
273 | #include <TGraph.h> | |
78f17711 | 274 | #include <TGraphErrors.h> |
3cd27a08 | 275 | #include <TString.h> |
ac940b58 | 276 | #include <TMap.h> |
3cd27a08 | 277 | #include <TDirectory.h> |
278 | #include <TSystem.h> | |
279 | #include <TFile.h> | |
7442bceb | 280 | #include <TCollection.h> |
78f17711 | 281 | #include <TTimeStamp.h> |
282 | #include <TList.h> | |
283 | #include <TKey.h> | |
6e6025f4 | 284 | #include <TSpectrum.h> |
3cd27a08 | 285 | |
286 | //AliRoot includes | |
4c6d06dc | 287 | #include "AliLog.h" |
3cd27a08 | 288 | #include "AliRawReader.h" |
289 | #include "AliRawReaderRoot.h" | |
290 | #include "AliRawReaderDate.h" | |
291 | #include "AliRawEventHeaderBase.h" | |
3cd27a08 | 292 | #include "AliTPCCalROC.h" |
293 | #include "AliTPCCalPad.h" | |
294 | #include "AliTPCROC.h" | |
295 | #include "AliTPCParam.h" | |
296 | #include "AliTPCCalibCE.h" | |
297 | #include "AliMathBase.h" | |
78f17711 | 298 | #include "AliTPCTransform.h" |
299 | #include "AliTPCLaserTrack.h" | |
3cd27a08 | 300 | #include "TTreeStream.h" |
301 | ||
78f17711 | 302 | #include "AliCDBManager.h" |
303 | #include "AliCDBEntry.h" | |
3cd27a08 | 304 | //date |
305 | #include "event.h" | |
306 | ClassImp(AliTPCCalibCE) | |
307 | ||
308 | ||
7fb602b1 | 309 | AliTPCCalibCE::AliTPCCalibCE() : |
880c3382 | 310 | AliTPCCalibRawBase(), |
311 | fNbinsT0(200), | |
312 | fXminT0(-5), | |
313 | fXmaxT0(5), | |
314 | fNbinsQ(200), | |
315 | fXminQ(1), | |
316 | fXmaxQ(40), | |
317 | fNbinsRMS(100), | |
318 | fXminRMS(0.1), | |
319 | fXmaxRMS(5.1), | |
320 | fPeakDetMinus(2), | |
321 | fPeakDetPlus(3), | |
322 | fPeakIntMinus(2), | |
323 | fPeakIntPlus(2), | |
324 | fNoiseThresholdMax(5.), | |
325 | fNoiseThresholdSum(8.), | |
326 | fIsZeroSuppressed(kFALSE), | |
327 | fLastSector(-1), | |
328 | fSecRejectRatio(.4), | |
329 | fParam(new AliTPCParam), | |
330 | fPedestalTPC(0x0), | |
331 | fPadNoiseTPC(0x0), | |
332 | fPedestalROC(0x0), | |
333 | fPadNoiseROC(0x0), | |
334 | fCalRocArrayT0(72), | |
335 | fCalRocArrayT0Err(72), | |
336 | fCalRocArrayQ(72), | |
337 | fCalRocArrayRMS(72), | |
338 | fCalRocArrayOutliers(72), | |
339 | fHistoQArray(72), | |
340 | fHistoT0Array(72), | |
341 | fHistoRMSArray(72), | |
342 | fMeanT0rms(0), | |
343 | fMeanQrms(0), | |
344 | fMeanRMSrms(0), | |
345 | fHistoTmean(72), | |
346 | fParamArrayEventPol1(72), | |
347 | fParamArrayEventPol2(72), | |
348 | fTMeanArrayEvent(72), | |
349 | fQMeanArrayEvent(72), | |
350 | fVEventTime(1000), | |
351 | fVEventNumber(1000), | |
352 | fVTime0SideA(1000), | |
353 | fVTime0SideC(1000), | |
880c3382 | 354 | fEventId(-1), |
c3066940 | 355 | fOldRunNumber(0), |
880c3382 | 356 | fPadTimesArrayEvent(72), |
357 | fPadQArrayEvent(72), | |
358 | fPadRMSArrayEvent(72), | |
359 | fPadPedestalArrayEvent(72), | |
360 | fCurrentChannel(-1), | |
361 | fCurrentSector(-1), | |
362 | fCurrentRow(-1), | |
363 | fMaxPadSignal(-1), | |
364 | fMaxTimeBin(-1), | |
2963bcbf | 365 | // fPadSignal(1024), |
880c3382 | 366 | fPadPedestal(0), |
367 | fPadNoise(0), | |
368 | fVTime0Offset(72), | |
369 | fVTime0OffsetCounter(72), | |
370 | fVMeanQ(72), | |
371 | fVMeanQCounter(72), | |
78f17711 | 372 | fCurrentCETimeRef(0), |
373 | fProcessOld(kTRUE), | |
374 | fProcessNew(kFALSE), | |
375 | fAnalyseNew(kTRUE), | |
376 | fHnDrift(0x0), | |
377 | fArrHnDrift(100), | |
378 | fTimeBursts(100), | |
6e6025f4 | 379 | fArrFitGraphs(0x0), |
380 | fEventInBunch(0) | |
75d8233f | 381 | { |
880c3382 | 382 | // |
383 | // AliTPCSignal default constructor | |
384 | // | |
385 | SetNameTitle("AliTPCCalibCE","AliTPCCalibCE"); | |
386 | fFirstTimeBin=650; | |
78f17711 | 387 | fLastTimeBin=1030; |
880c3382 | 388 | fParam->Update(); |
2963bcbf | 389 | for (Int_t i=0;i<1024;++i) fPadSignal[i]=0; |
6e6025f4 | 390 | for (Int_t i=0;i<14;++i){ |
78f17711 | 391 | fPeaks[i]=0; |
392 | fPeakWidths[i]=0; | |
393 | } | |
394 | for (Int_t i=0; i<100; ++i) fBinsLastAna[i]=0; | |
75d8233f | 395 | } |
396 | //_____________________________________________________________________ | |
397 | AliTPCCalibCE::AliTPCCalibCE(const AliTPCCalibCE &sig) : | |
880c3382 | 398 | AliTPCCalibRawBase(sig), |
399 | fNbinsT0(sig.fNbinsT0), | |
400 | fXminT0(sig.fXminT0), | |
401 | fXmaxT0(sig.fXmaxT0), | |
402 | fNbinsQ(sig.fNbinsQ), | |
403 | fXminQ(sig.fXminQ), | |
404 | fXmaxQ(sig.fXmaxQ), | |
405 | fNbinsRMS(sig.fNbinsRMS), | |
406 | fXminRMS(sig.fXminRMS), | |
407 | fXmaxRMS(sig.fXmaxRMS), | |
408 | fPeakDetMinus(sig.fPeakDetMinus), | |
409 | fPeakDetPlus(sig.fPeakDetPlus), | |
410 | fPeakIntMinus(sig.fPeakIntMinus), | |
411 | fPeakIntPlus(sig.fPeakIntPlus), | |
412 | fNoiseThresholdMax(sig.fNoiseThresholdMax), | |
413 | fNoiseThresholdSum(sig.fNoiseThresholdSum), | |
414 | fIsZeroSuppressed(sig.fIsZeroSuppressed), | |
415 | fLastSector(-1), | |
416 | fSecRejectRatio(.4), | |
417 | fParam(new AliTPCParam), | |
418 | fPedestalTPC(0x0), | |
419 | fPadNoiseTPC(0x0), | |
420 | fPedestalROC(0x0), | |
421 | fPadNoiseROC(0x0), | |
422 | fCalRocArrayT0(72), | |
423 | fCalRocArrayT0Err(72), | |
424 | fCalRocArrayQ(72), | |
425 | fCalRocArrayRMS(72), | |
426 | fCalRocArrayOutliers(72), | |
427 | fHistoQArray(72), | |
428 | fHistoT0Array(72), | |
429 | fHistoRMSArray(72), | |
430 | fMeanT0rms(sig.fMeanT0rms), | |
431 | fMeanQrms(sig.fMeanQrms), | |
432 | fMeanRMSrms(sig.fMeanRMSrms), | |
433 | fHistoTmean(72), | |
434 | fParamArrayEventPol1(72), | |
435 | fParamArrayEventPol2(72), | |
436 | fTMeanArrayEvent(72), | |
437 | fQMeanArrayEvent(72), | |
438 | fVEventTime(sig.fVEventTime), | |
439 | fVEventNumber(sig.fVEventNumber), | |
440 | fVTime0SideA(sig.fVTime0SideA), | |
441 | fVTime0SideC(sig.fVTime0SideC), | |
880c3382 | 442 | fEventId(-1), |
c3066940 | 443 | fOldRunNumber(0), |
880c3382 | 444 | fPadTimesArrayEvent(72), |
445 | fPadQArrayEvent(72), | |
446 | fPadRMSArrayEvent(72), | |
447 | fPadPedestalArrayEvent(72), | |
448 | fCurrentChannel(-1), | |
449 | fCurrentSector(-1), | |
450 | fCurrentRow(-1), | |
451 | fMaxPadSignal(-1), | |
452 | fMaxTimeBin(-1), | |
2963bcbf | 453 | // fPadSignal(1024), |
880c3382 | 454 | fPadPedestal(0), |
455 | fPadNoise(0), | |
456 | fVTime0Offset(72), | |
457 | fVTime0OffsetCounter(72), | |
458 | fVMeanQ(72), | |
459 | fVMeanQCounter(72), | |
78f17711 | 460 | fCurrentCETimeRef(0), |
461 | fProcessOld(sig.fProcessOld), | |
462 | fProcessNew(sig.fProcessNew), | |
463 | fAnalyseNew(sig.fAnalyseNew), | |
464 | fHnDrift(0x0), | |
465 | fArrHnDrift(100), | |
466 | fTimeBursts(100), | |
6e6025f4 | 467 | fArrFitGraphs(0x0), |
468 | fEventInBunch(0) | |
75d8233f | 469 | { |
ac940b58 | 470 | // |
880c3382 | 471 | // AliTPCSignal copy constructor |
ac940b58 | 472 | // |
2963bcbf | 473 | for (Int_t i=0;i<1024;++i) fPadSignal[i]=0; |
474 | ||
ac940b58 | 475 | for (Int_t iSec = 0; iSec < 72; ++iSec){ |
476 | const AliTPCCalROC *calQ = (AliTPCCalROC*)sig.fCalRocArrayQ.UncheckedAt(iSec); | |
477 | const AliTPCCalROC *calT0 = (AliTPCCalROC*)sig.fCalRocArrayT0.UncheckedAt(iSec); | |
478 | const AliTPCCalROC *calRMS = (AliTPCCalROC*)sig.fCalRocArrayRMS.UncheckedAt(iSec); | |
479 | const AliTPCCalROC *calOut = (AliTPCCalROC*)sig.fCalRocArrayOutliers.UncheckedAt(iSec); | |
75d8233f | 480 | |
ac940b58 | 481 | const TH2S *hQ = (TH2S*)sig.fHistoQArray.UncheckedAt(iSec); |
482 | const TH2S *hT0 = (TH2S*)sig.fHistoT0Array.UncheckedAt(iSec); | |
483 | const TH2S *hRMS = (TH2S*)sig.fHistoRMSArray.UncheckedAt(iSec); | |
75d8233f | 484 | |
ac940b58 | 485 | if ( calQ != 0x0 ) fCalRocArrayQ.AddAt(new AliTPCCalROC(*calQ), iSec); |
486 | if ( calT0 != 0x0 ) fCalRocArrayT0.AddAt(new AliTPCCalROC(*calT0), iSec); | |
487 | if ( calRMS != 0x0 ) fCalRocArrayRMS.AddAt(new AliTPCCalROC(*calRMS), iSec); | |
488 | if ( calOut != 0x0 ) fCalRocArrayOutliers.AddAt(new AliTPCCalROC(*calOut), iSec); | |
75d8233f | 489 | |
ac940b58 | 490 | if ( hQ != 0x0 ){ |
ac940b58 | 491 | TH2S *hNew = new TH2S(*hQ); |
492 | hNew->SetDirectory(0); | |
493 | fHistoQArray.AddAt(hNew,iSec); | |
ac940b58 | 494 | } |
495 | if ( hT0 != 0x0 ){ | |
ac940b58 | 496 | TH2S *hNew = new TH2S(*hT0); |
497 | hNew->SetDirectory(0); | |
498 | fHistoT0Array.AddAt(hNew,iSec); | |
ac940b58 | 499 | } |
500 | if ( hRMS != 0x0 ){ | |
ac940b58 | 501 | TH2S *hNew = new TH2S(*hRMS); |
502 | hNew->SetDirectory(0); | |
503 | fHistoRMSArray.AddAt(hNew,iSec); | |
75d8233f | 504 | } |
ac940b58 | 505 | } |
75d8233f | 506 | |
880c3382 | 507 | //copy fit parameters event by event |
ac940b58 | 508 | TObjArray *arr=0x0; |
509 | for (Int_t iSec=0; iSec<72; ++iSec){ | |
510 | arr = (TObjArray*)sig.fParamArrayEventPol1.UncheckedAt(iSec); | |
511 | if ( arr ){ | |
512 | TObjArray *arrEvents = new TObjArray(arr->GetSize()); | |
513 | fParamArrayEventPol1.AddAt(arrEvents, iSec); | |
514 | for (Int_t iEvent=0; iEvent<arr->GetSize(); ++iEvent) | |
515 | if ( TVectorD *vec=(TVectorD*)arr->UncheckedAt(iEvent) ) | |
516 | arrEvents->AddAt(new TVectorD(*vec),iEvent); | |
517 | } | |
7fb602b1 | 518 | |
ac940b58 | 519 | arr = (TObjArray*)sig.fParamArrayEventPol2.UncheckedAt(iSec); |
520 | if ( arr ){ | |
521 | TObjArray *arrEvents = new TObjArray(arr->GetSize()); | |
522 | fParamArrayEventPol2.AddAt(arrEvents, iSec); | |
523 | for (Int_t iEvent=0; iEvent<arr->GetSize(); ++iEvent) | |
524 | if ( TVectorD *vec=(TVectorD*)arr->UncheckedAt(iEvent) ) | |
525 | arrEvents->AddAt(new TVectorD(*vec),iEvent); | |
7fb602b1 | 526 | } |
527 | ||
ac940b58 | 528 | TVectorF *vMeanTime = (TVectorF*)sig.fTMeanArrayEvent.UncheckedAt(iSec); |
529 | TVectorF *vMeanQ = (TVectorF*)sig.fQMeanArrayEvent.UncheckedAt(iSec); | |
530 | if ( vMeanTime ) | |
531 | fTMeanArrayEvent.AddAt(new TVectorF(*vMeanTime), iSec); | |
532 | if ( vMeanQ ) | |
533 | fQMeanArrayEvent.AddAt(new TVectorF(*vMeanQ), iSec); | |
534 | } | |
535 | ||
7fb602b1 | 536 | |
ac940b58 | 537 | fVEventTime.ResizeTo(sig.fVEventTime); |
538 | fVEventNumber.ResizeTo(sig.fVEventNumber); | |
539 | fVEventTime.SetElements(sig.fVEventTime.GetMatrixArray()); | |
540 | fVEventNumber.SetElements(sig.fVEventNumber.GetMatrixArray()); | |
7fb602b1 | 541 | |
ac940b58 | 542 | fParam->Update(); |
78f17711 | 543 | |
544 | for (Int_t i=0; i<sig.fArrHnDrift.GetEntries();++i){ | |
545 | TObject *o=sig.fArrHnDrift.UncheckedAt(i); | |
546 | if (o){ | |
547 | TObject *newo=o->Clone("fHnDrift"); | |
548 | fArrHnDrift.AddAt(newo,i); | |
549 | if (sig.fHnDrift && o==sig.fHnDrift) fHnDrift=(THnSparseI*)newo; | |
550 | } | |
551 | } | |
552 | ||
553 | for (Int_t i=0;i<sig.fTimeBursts.GetNrows();++i){ | |
554 | fTimeBursts[i]=sig.fTimeBursts[i]; | |
555 | } | |
556 | ||
6e6025f4 | 557 | for (Int_t i=0;i<14;++i){ |
78f17711 | 558 | fPeaks[i]=sig.fPeaks[i]; |
559 | fPeakWidths[i]=sig.fPeakWidths[i]; | |
560 | } | |
561 | if (sig.fArrFitGraphs) { | |
562 | fArrFitGraphs=(TObjArray*)sig.fArrFitGraphs->Clone(); | |
563 | fArrFitGraphs->SetOwner(); | |
564 | } | |
565 | ||
566 | for (Int_t i=0; i<100; ++i) fBinsLastAna[i]=sig.fBinsLastAna[i]; | |
567 | ||
75d8233f | 568 | } |
ac940b58 | 569 | //_____________________________________________________________________ |
570 | AliTPCCalibCE::AliTPCCalibCE(const TMap *config) : | |
880c3382 | 571 | AliTPCCalibRawBase(), |
ac940b58 | 572 | fNbinsT0(200), |
573 | fXminT0(-5), | |
574 | fXmaxT0(5), | |
575 | fNbinsQ(200), | |
576 | fXminQ(1), | |
577 | fXmaxQ(40), | |
578 | fNbinsRMS(100), | |
579 | fXminRMS(0.1), | |
580 | fXmaxRMS(5.1), | |
880c3382 | 581 | fPeakDetMinus(2), |
582 | fPeakDetPlus(3), | |
583 | fPeakIntMinus(2), | |
584 | fPeakIntPlus(2), | |
ac940b58 | 585 | fNoiseThresholdMax(5.), |
586 | fNoiseThresholdSum(8.), | |
587 | fIsZeroSuppressed(kFALSE), | |
588 | fLastSector(-1), | |
589 | fSecRejectRatio(.4), | |
ac940b58 | 590 | fParam(new AliTPCParam), |
591 | fPedestalTPC(0x0), | |
592 | fPadNoiseTPC(0x0), | |
593 | fPedestalROC(0x0), | |
594 | fPadNoiseROC(0x0), | |
595 | fCalRocArrayT0(72), | |
596 | fCalRocArrayT0Err(72), | |
597 | fCalRocArrayQ(72), | |
598 | fCalRocArrayRMS(72), | |
599 | fCalRocArrayOutliers(72), | |
600 | fHistoQArray(72), | |
601 | fHistoT0Array(72), | |
602 | fHistoRMSArray(72), | |
603 | fMeanT0rms(0), | |
604 | fMeanQrms(0), | |
605 | fMeanRMSrms(0), | |
606 | fHistoTmean(72), | |
607 | fParamArrayEventPol1(72), | |
608 | fParamArrayEventPol2(72), | |
609 | fTMeanArrayEvent(72), | |
610 | fQMeanArrayEvent(72), | |
880c3382 | 611 | fVEventTime(1000), |
612 | fVEventNumber(1000), | |
613 | fVTime0SideA(1000), | |
614 | fVTime0SideC(1000), | |
ac940b58 | 615 | fEventId(-1), |
c3066940 | 616 | fOldRunNumber(0), |
ac940b58 | 617 | fPadTimesArrayEvent(72), |
618 | fPadQArrayEvent(72), | |
619 | fPadRMSArrayEvent(72), | |
620 | fPadPedestalArrayEvent(72), | |
621 | fCurrentChannel(-1), | |
622 | fCurrentSector(-1), | |
623 | fCurrentRow(-1), | |
624 | fMaxPadSignal(-1), | |
625 | fMaxTimeBin(-1), | |
2963bcbf | 626 | // fPadSignal(1024), |
ac940b58 | 627 | fPadPedestal(0), |
628 | fPadNoise(0), | |
629 | fVTime0Offset(72), | |
630 | fVTime0OffsetCounter(72), | |
631 | fVMeanQ(72), | |
632 | fVMeanQCounter(72), | |
78f17711 | 633 | fCurrentCETimeRef(0), |
634 | fProcessOld(kTRUE), | |
635 | fProcessNew(kFALSE), | |
636 | fAnalyseNew(kTRUE), | |
637 | fHnDrift(0x0), | |
638 | fArrHnDrift(100), | |
639 | fTimeBursts(100), | |
6e6025f4 | 640 | fArrFitGraphs(0x0), |
641 | fEventInBunch(0) | |
ac940b58 | 642 | { |
643 | // | |
644 | // constructor which uses a tmap as input to set some specific parameters | |
645 | // | |
880c3382 | 646 | SetNameTitle("AliTPCCalibCE","AliTPCCalibCE"); |
647 | fFirstTimeBin=650; | |
78f17711 | 648 | fLastTimeBin=1030; |
ac940b58 | 649 | if (config->GetValue("FirstTimeBin")) fFirstTimeBin = ((TObjString*)config->GetValue("FirstTimeBin"))->GetString().Atoi(); |
650 | if (config->GetValue("LastTimeBin")) fLastTimeBin = ((TObjString*)config->GetValue("LastTimeBin"))->GetString().Atoi(); | |
651 | if (config->GetValue("NbinsT0")) fNbinsT0 = ((TObjString*)config->GetValue("NbinsT0"))->GetString().Atoi(); | |
652 | if (config->GetValue("XminT0")) fXminT0 = ((TObjString*)config->GetValue("XminT0"))->GetString().Atof(); | |
653 | if (config->GetValue("XmaxT0")) fXmaxT0 = ((TObjString*)config->GetValue("XmaxT0"))->GetString().Atof(); | |
654 | if (config->GetValue("NbinsQ")) fNbinsQ = ((TObjString*)config->GetValue("NbinsQ"))->GetString().Atoi(); | |
655 | if (config->GetValue("XminQ")) fXminQ = ((TObjString*)config->GetValue("XminQ"))->GetString().Atof(); | |
656 | if (config->GetValue("XmaxQ")) fXmaxQ = ((TObjString*)config->GetValue("XmaxQ"))->GetString().Atof(); | |
657 | if (config->GetValue("NbinsRMS")) fNbinsRMS = ((TObjString*)config->GetValue("NbinsRMS"))->GetString().Atoi(); | |
658 | if (config->GetValue("XminRMS")) fXminRMS = ((TObjString*)config->GetValue("XminRMS"))->GetString().Atof(); | |
659 | if (config->GetValue("XmaxRMS")) fXmaxRMS = ((TObjString*)config->GetValue("XmaxRMS"))->GetString().Atof(); | |
880c3382 | 660 | if (config->GetValue("PeakDetMinus")) fPeakDetMinus = ((TObjString*)config->GetValue("PeakDetMinus"))->GetString().Atoi(); |
661 | if (config->GetValue("PeakDetPlus")) fPeakDetPlus = ((TObjString*)config->GetValue("PeakDetPlus"))->GetString().Atoi(); | |
662 | if (config->GetValue("PeakIntMinus")) fPeakIntMinus = ((TObjString*)config->GetValue("PeakIntMinus"))->GetString().Atoi(); | |
663 | if (config->GetValue("PeakIntPlus")) fPeakIntPlus = ((TObjString*)config->GetValue("PeakIntPlus"))->GetString().Atoi(); | |
ac940b58 | 664 | if (config->GetValue("NoiseThresholdMax")) fNoiseThresholdMax = ((TObjString*)config->GetValue("NoiseThresholdMax"))->GetString().Atof(); |
665 | if (config->GetValue("NoiseThresholdSum")) fNoiseThresholdSum = ((TObjString*)config->GetValue("NoiseThresholdSum"))->GetString().Atof(); | |
666 | if (config->GetValue("IsZeroSuppressed")) fIsZeroSuppressed = (Bool_t)((TObjString*)config->GetValue("IsZeroSuppressed"))->GetString().Atoi(); | |
880c3382 | 667 | if (config->GetValue("UseL1Phase")) fUseL1Phase = (Bool_t)((TObjString*)config->GetValue("UseL1Phase"))->GetString().Atoi(); |
ac940b58 | 668 | if (config->GetValue("SecRejectRatio")) fSecRejectRatio = ((TObjString*)config->GetValue("SecRejectRatio"))->GetString().Atof(); |
669 | ||
78f17711 | 670 | if (config->GetValue("ProcessOld")) fProcessOld = (Bool_t)((TObjString*)config->GetValue("ProcessOld"))->GetString().Atoi(); |
671 | if (config->GetValue("ProcessNew")) fProcessNew = (Bool_t)((TObjString*)config->GetValue("ProcessNew"))->GetString().Atoi(); | |
672 | if (config->GetValue("AnalyseNew")) fAnalyseNew = (Bool_t)((TObjString*)config->GetValue("AnalyseNew"))->GetString().Atoi(); | |
673 | ||
2963bcbf | 674 | for (Int_t i=0;i<1024;++i) fPadSignal[i]=0; |
6e6025f4 | 675 | for (Int_t i=0;i<14;++i){ |
78f17711 | 676 | fPeaks[i]=0; |
677 | fPeakWidths[i]=0; | |
678 | } | |
2963bcbf | 679 | |
ac940b58 | 680 | fParam->Update(); |
78f17711 | 681 | for (Int_t i=0; i<100; ++i) fBinsLastAna[i]=0; |
ac940b58 | 682 | } |
683 | ||
75d8233f | 684 | //_____________________________________________________________________ |
685 | AliTPCCalibCE& AliTPCCalibCE::operator = (const AliTPCCalibCE &source) | |
686 | { | |
687 | // | |
688 | // assignment operator | |
689 | // | |
690 | if (&source == this) return *this; | |
691 | new (this) AliTPCCalibCE(source); | |
692 | ||
693 | return *this; | |
694 | } | |
695 | //_____________________________________________________________________ | |
696 | AliTPCCalibCE::~AliTPCCalibCE() | |
697 | { | |
78f17711 | 698 | // |
699 | // destructor | |
700 | // | |
701 | ||
702 | fCalRocArrayT0.Delete(); | |
703 | fCalRocArrayT0Err.Delete(); | |
704 | fCalRocArrayQ.Delete(); | |
705 | fCalRocArrayRMS.Delete(); | |
706 | fCalRocArrayOutliers.Delete(); | |
707 | ||
708 | fHistoQArray.Delete(); | |
709 | fHistoT0Array.Delete(); | |
710 | fHistoRMSArray.Delete(); | |
711 | ||
712 | fHistoTmean.Delete(); | |
713 | ||
714 | fParamArrayEventPol1.Delete(); | |
715 | fParamArrayEventPol2.Delete(); | |
716 | fTMeanArrayEvent.Delete(); | |
717 | fQMeanArrayEvent.Delete(); | |
718 | ||
719 | fPadTimesArrayEvent.Delete(); | |
720 | fPadQArrayEvent.Delete(); | |
721 | fPadRMSArrayEvent.Delete(); | |
722 | fPadPedestalArrayEvent.Delete(); | |
723 | ||
724 | fArrHnDrift.SetOwner(); | |
725 | fArrHnDrift.Delete(); | |
726 | ||
727 | if (fArrFitGraphs){ | |
728 | fArrFitGraphs->SetOwner(); | |
729 | delete fArrFitGraphs; | |
730 | } | |
75d8233f | 731 | } |
732 | //_____________________________________________________________________ | |
7fb602b1 | 733 | Int_t AliTPCCalibCE::Update(const Int_t icsector, |
75d8233f | 734 | const Int_t icRow, |
735 | const Int_t icPad, | |
736 | const Int_t icTimeBin, | |
737 | const Float_t csignal) | |
738 | { | |
ac940b58 | 739 | // |
740 | // Signal filling methode on the fly pedestal and Time offset correction if necessary. | |
741 | // no extra analysis necessary. Assumes knowledge of the signal shape! | |
742 | // assumes that it is looped over consecutive time bins of one pad | |
743 | // | |
4c6d06dc | 744 | |
78f17711 | 745 | if (!fProcessOld) return 0; |
ac940b58 | 746 | //temp |
4c6d06dc | 747 | |
b401648b | 748 | if (icRow<0) return 0; |
749 | if (icPad<0) return 0; | |
750 | if (icTimeBin<0) return 0; | |
ac940b58 | 751 | if ( (icTimeBin>fLastTimeBin) || (icTimeBin<fFirstTimeBin) ) return 0; |
75d8233f | 752 | |
ac940b58 | 753 | Int_t iChannel = fROC->GetRowIndexes(icsector)[icRow]+icPad; // global pad position in sector |
75d8233f | 754 | |
ac940b58 | 755 | //init first pad and sector in this event |
756 | if ( fCurrentChannel == -1 ) { | |
757 | fLastSector=-1; | |
758 | fCurrentChannel = iChannel; | |
759 | fCurrentSector = icsector; | |
760 | fCurrentRow = icRow; | |
761 | } | |
75d8233f | 762 | |
ac940b58 | 763 | //process last pad if we change to a new one |
764 | if ( iChannel != fCurrentChannel ){ | |
765 | ProcessPad(); | |
766 | fLastSector=fCurrentSector; | |
767 | fCurrentChannel = iChannel; | |
768 | fCurrentSector = icsector; | |
769 | fCurrentRow = icRow; | |
770 | } | |
75d8233f | 771 | |
ac940b58 | 772 | //fill signals for current pad |
2963bcbf | 773 | fPadSignal[icTimeBin]=csignal; |
ac940b58 | 774 | if ( csignal > fMaxPadSignal ){ |
775 | fMaxPadSignal = csignal; | |
776 | fMaxTimeBin = icTimeBin; | |
777 | } | |
778 | return 0; | |
75d8233f | 779 | } |
78f17711 | 780 | |
781 | //_____________________________________________________________________ | |
782 | void AliTPCCalibCE::ProcessBunch(const Int_t sector, const Int_t row, const Int_t pad, | |
783 | const Int_t length, const UInt_t startTimeBin, const UShort_t* signal) | |
784 | { | |
785 | // | |
786 | // new filling method to fill the THnSparse histogram | |
787 | // | |
788 | ||
789 | //only in new processing mode | |
790 | if (!fProcessNew) return; | |
6e6025f4 | 791 | //don't use the IROCs and inner part of OROCs |
78f17711 | 792 | if (sector<36) return; |
6e6025f4 | 793 | if (row<40) return; |
78f17711 | 794 | //only bunches with reasonable length |
795 | if (length<3||length>10) return; | |
796 | ||
797 | UShort_t timeBin = (UShort_t)startTimeBin; | |
798 | //skip first laser layer | |
6e6025f4 | 799 | if (timeBin<280) return; |
800 | ||
78f17711 | 801 | Double_t timeBurst=SetBurstHnDrift(); |
802 | ||
6e6025f4 | 803 | Int_t cePeak=((sector/18)%2)*7+6; |
78f17711 | 804 | //after 1 event setup peak ranges |
6e6025f4 | 805 | if (fEventInBunch==1 && fPeaks[cePeak]==0) { |
78f17711 | 806 | // set time range |
807 | fHnDrift->GetAxis(4)->SetRangeUser(timeBurst-2*60,timeBurst+2*60); | |
808 | FindLaserLayers(); | |
809 | // set time range | |
810 | fHnDrift->GetAxis(4)->SetRangeUser(fHnDrift->GetAxis(4)->GetXmin(),fHnDrift->GetAxis(4)->GetXmax()); | |
6e6025f4 | 811 | fHnDrift->Reset(); |
78f17711 | 812 | } |
813 | ||
814 | // After the first event only fill every 5th bin in a row with the CE information | |
815 | Int_t padFill=pad; | |
6e6025f4 | 816 | if (fEventInBunch==0||(fPeaks[cePeak]>100&&TMath::Abs((Short_t)fPeaks[cePeak]-(Short_t)timeBin)<(Short_t)fPeakWidths[cePeak])){ |
78f17711 | 817 | Int_t mod=5; |
818 | Int_t n=pad/mod; | |
819 | padFill=mod*n+mod/2; | |
820 | } | |
821 | ||
822 | //noise removal | |
6e6025f4 | 823 | if (!IsPeakInRange(timeBin+length/2,sector)) return; |
78f17711 | 824 | |
825 | Double_t x[kHnBinsDV]={(Double_t)sector,(Double_t)row, | |
826 | (Double_t)padFill,(Double_t)timeBin,timeBurst}; | |
827 | ||
828 | for (Int_t iTimeBin = 0; iTimeBin<length; iTimeBin++){ | |
829 | Float_t sig=(Float_t)signal[iTimeBin]; | |
6e6025f4 | 830 | // if (fPeaks[6]>900&&timeBin>(fPeaks[6]-20)&&sig<20) continue; |
831 | // if (fPeaks[6]>900&&timeBin<(fPeaks[6]-fPeakWidth[6])&&sig<5) continue; | |
78f17711 | 832 | x[3]=timeBin; |
833 | fHnDrift->Fill(x,sig); | |
834 | --timeBin; | |
835 | } | |
836 | } | |
837 | //_____________________________________________________________________ | |
838 | void AliTPCCalibCE::FindLaserLayers() | |
839 | { | |
840 | // | |
841 | // Find the laser layer positoins | |
842 | // | |
843 | ||
6e6025f4 | 844 | //A-side + C-side |
845 | for (Int_t iside=0;iside<2;++iside){ | |
846 | Int_t add=7*iside; | |
847 | //find CE signal position and width | |
848 | fHnDrift->GetAxis(0)->SetRangeUser(36+iside*18,53+iside*18); | |
849 | TH1D *hproj=fHnDrift->Projection(3); | |
850 | hproj->GetXaxis()->SetRangeUser(700,1030); | |
851 | Int_t maxbin=hproj->GetMaximumBin(); | |
852 | Double_t binc=hproj->GetBinCenter(maxbin); | |
853 | hproj->GetXaxis()->SetRangeUser(binc-5,binc+5); | |
854 | ||
855 | fPeaks[add+6]=(UShort_t)TMath::Nint(binc); | |
856 | // fPeakWidths[4]=(UShort_t)TMath::Nint(4*hproj->GetRMS()+.5); | |
857 | fPeakWidths[add+6]=7; | |
858 | ||
859 | hproj->GetXaxis()->SetRangeUser(0,maxbin-10); | |
860 | TSpectrum s(6); | |
861 | s.Search(hproj,2,"goff"); | |
862 | Int_t index[6]; | |
863 | TMath::Sort(6,s.GetPositionX(),index,kFALSE); | |
864 | for (Int_t i=0; i<6; ++i){ | |
865 | fPeaks[i+add]=(UShort_t)TMath::Nint(s.GetPositionX()[index[i]]); | |
866 | fPeakWidths[i+add]=5; | |
78f17711 | 867 | } |
6e6025f4 | 868 | |
869 | //other peaks | |
870 | ||
871 | // Int_t timepos=fPeaks[4]-2*fPeakWidths[4]; | |
872 | // Int_t width=100; | |
873 | ||
874 | // for (Int_t i=3; i>=0; --i){ | |
875 | // hproj->GetXaxis()->SetRangeUser(timepos-width,timepos); | |
876 | // fPeaks[i]=hproj->GetMaximumBin(); | |
877 | // fPeakWidths[i]=(UShort_t)TMath::Nint(10.); | |
878 | // width=250; | |
879 | // timepos=fPeaks[i]-width/2; | |
880 | // } | |
881 | ||
882 | // for (Int_t i=add; i<add+7; ++i){ | |
883 | // printf("Peak: %u +- %u\n",fPeaks[i],fPeakWidths[i]); | |
884 | // } | |
885 | //check width and reset peak if >100 | |
886 | // for (Int_t i=0; i<5; ++i){ | |
887 | // if (fPeakWidths[i]>100) { | |
888 | // fPeaks[i]=0; | |
889 | // fPeakWidths[i]=0; | |
890 | // } | |
891 | // } | |
892 | ||
893 | delete hproj; | |
78f17711 | 894 | } |
78f17711 | 895 | } |
896 | ||
75d8233f | 897 | //_____________________________________________________________________ |
898 | void AliTPCCalibCE::FindPedestal(Float_t part) | |
899 | { | |
ac940b58 | 900 | // |
75d8233f | 901 | // find pedestal and noise for the current pad. Use either database or |
902 | // truncated mean with part*100% | |
ac940b58 | 903 | // |
904 | Bool_t noPedestal = kTRUE; | |
7fb602b1 | 905 | |
906 | //use pedestal database if set | |
ac940b58 | 907 | if (fPedestalTPC&&fPadNoiseTPC){ |
75d8233f | 908 | //only load new pedestals if the sector has changed |
ac940b58 | 909 | if ( fCurrentSector!=fLastSector ){ |
910 | fPedestalROC = fPedestalTPC->GetCalROC(fCurrentSector); | |
911 | fPadNoiseROC = fPadNoiseTPC->GetCalROC(fCurrentSector); | |
912 | } | |
75d8233f | 913 | |
ac940b58 | 914 | if ( fPedestalROC&&fPadNoiseROC ){ |
915 | fPadPedestal = fPedestalROC->GetValue(fCurrentChannel)*(Float_t)(!fIsZeroSuppressed); | |
916 | fPadNoise = fPadNoiseROC->GetValue(fCurrentChannel); | |
917 | noPedestal = kFALSE; | |
75d8233f | 918 | } |
919 | ||
ac940b58 | 920 | } |
921 | ||
75d8233f | 922 | //if we are not running with pedestal database, or for the current sector there is no information |
923 | //available, calculate the pedestal and noise on the fly | |
ac940b58 | 924 | if ( noPedestal ) { |
925 | fPadPedestal = 0; | |
926 | fPadNoise = 0; | |
927 | if ( fIsZeroSuppressed ) return; | |
928 | const Int_t kPedMax = 100; //maximum pedestal value | |
929 | Float_t max = 0; | |
930 | Float_t maxPos = 0; | |
931 | Int_t median = -1; | |
932 | Int_t count0 = 0; | |
933 | Int_t count1 = 0; | |
934 | // | |
935 | Float_t padSignal=0; | |
936 | // | |
937 | UShort_t histo[kPedMax]; | |
938 | memset(histo,0,kPedMax*sizeof(UShort_t)); | |
bf57d87d | 939 | |
7fb602b1 | 940 | //fill pedestal histogram |
ac940b58 | 941 | for (Int_t i=fFirstTimeBin; i<=fLastTimeBin; ++i){ |
2963bcbf | 942 | padSignal = fPadSignal[i]; |
ac940b58 | 943 | if (padSignal<=0) continue; |
944 | if (padSignal>max && i>10) { | |
945 | max = padSignal; | |
946 | maxPos = i; | |
947 | } | |
948 | if (padSignal>kPedMax-1) continue; | |
949 | histo[int(padSignal+0.5)]++; | |
950 | count0++; | |
951 | } | |
7fb602b1 | 952 | //find median |
ac940b58 | 953 | for (Int_t i=1; i<kPedMax; ++i){ |
954 | if (count1<count0*0.5) median=i; | |
955 | count1+=histo[i]; | |
956 | } | |
75d8233f | 957 | // truncated mean |
ac940b58 | 958 | // |
959 | Float_t count=histo[median] ,mean=histo[median]*median, rms=histo[median]*median*median ; | |
960 | // | |
961 | for (Int_t idelta=1; idelta<10; ++idelta){ | |
962 | if (median-idelta<=0) continue; | |
963 | if (median+idelta>kPedMax) continue; | |
964 | if (count<part*count1){ | |
965 | count+=histo[median-idelta]; | |
966 | mean +=histo[median-idelta]*(median-idelta); | |
967 | rms +=histo[median-idelta]*(median-idelta)*(median-idelta); | |
968 | count+=histo[median+idelta]; | |
969 | mean +=histo[median+idelta]*(median+idelta); | |
970 | rms +=histo[median+idelta]*(median+idelta)*(median+idelta); | |
971 | } | |
972 | } | |
973 | if ( count > 0 ) { | |
974 | mean/=count; | |
975 | rms = TMath::Sqrt(TMath::Abs(rms/count-mean*mean)); | |
976 | fPadPedestal = mean; | |
977 | fPadNoise = rms; | |
75d8233f | 978 | } |
ac940b58 | 979 | } |
75d8233f | 980 | } |
981 | //_____________________________________________________________________ | |
ac940b58 | 982 | void AliTPCCalibCE::UpdateCETimeRef() |
983 | { | |
984 | // Find the time reference of the last valid CE signal in sector | |
985 | // for irocs of the A-Side the reference of the corresponging OROC is returned | |
986 | // the reason are the non reflective bands on the A-Side, which make the reference very uncertain | |
987 | if ( fLastSector == fCurrentSector ) return; | |
988 | Int_t sector=fCurrentSector; | |
989 | if ( sector < 18 ) sector+=36; | |
990 | fCurrentCETimeRef=0; | |
991 | TVectorF *vtRef = GetTMeanEvents(sector); | |
992 | if ( !vtRef ) return; | |
993 | Int_t vtRefSize= vtRef->GetNrows(); | |
994 | if ( vtRefSize < fNevents+1 ) vtRef->ResizeTo(vtRefSize+100); | |
995 | else vtRefSize=fNevents; | |
996 | while ( (*vtRef)[vtRefSize]==0 && vtRefSize>=0 ) --vtRefSize; | |
997 | fCurrentCETimeRef=(*vtRef)[vtRefSize]; | |
998 | AliDebug(3,Form("Sector: %02d - T0 ref: %.2f",fCurrentSector,fCurrentCETimeRef)); | |
999 | } | |
1000 | //_____________________________________________________________________ | |
75d8233f | 1001 | void AliTPCCalibCE::FindCESignal(TVectorD ¶m, Float_t &qSum, const TVectorF maxima) |
1002 | { | |
ac940b58 | 1003 | // |
75d8233f | 1004 | // Find position, signal width and height of the CE signal (last signal) |
1005 | // param[0] = Qmax, param[1] = mean time, param[2] = rms; | |
1006 | // maxima: array of local maxima of the pad signal use the one closest to the mean CE position | |
ac940b58 | 1007 | // |
75d8233f | 1008 | |
ac940b58 | 1009 | Float_t ceQmax =0, ceQsum=0, ceTime=0, ceRMS=0; |
1010 | Int_t cemaxpos = 0; | |
1011 | Float_t ceSumThreshold = fNoiseThresholdSum*fPadNoise; // threshold for the signal sum | |
880c3382 | 1012 | const Int_t kCemin = fPeakIntMinus; // range for the analysis of the ce signal +- channels from the peak |
1013 | const Int_t kCemax = fPeakIntPlus; | |
75d8233f | 1014 | |
ac940b58 | 1015 | Float_t minDist = 25; //initial minimum distance betweek roc mean ce signal and pad ce signal |
bf57d87d | 1016 | |
75d8233f | 1017 | // find maximum closest to the sector mean from the last event |
ac940b58 | 1018 | for ( Int_t imax=0; imax<maxima.GetNrows(); ++imax){ |
7fb602b1 | 1019 | // get sector mean of last event |
ac940b58 | 1020 | Float_t tmean = fCurrentCETimeRef; |
1021 | if ( TMath::Abs( tmean-maxima[imax] ) < minDist ) { | |
1022 | minDist = tmean-maxima[imax]; | |
1023 | cemaxpos = (Int_t)maxima[imax]; | |
75d8233f | 1024 | } |
ac940b58 | 1025 | } |
880c3382 | 1026 | // printf("L1 phase TB: %f\n",GetL1PhaseTB()); |
ac940b58 | 1027 | if (cemaxpos!=0){ |
2963bcbf | 1028 | ceQmax = fPadSignal[cemaxpos]-fPadPedestal; |
880c3382 | 1029 | for (Int_t i=cemaxpos-kCemin; i<=cemaxpos+kCemax; ++i){ |
ac940b58 | 1030 | if ( (i>fFirstTimeBin) && (i<fLastTimeBin) ){ |
2963bcbf | 1031 | Float_t signal = fPadSignal[i]-fPadPedestal; |
ac940b58 | 1032 | if (signal>0) { |
1033 | ceTime+=signal*(i+0.5); | |
1034 | ceRMS +=signal*(i+0.5)*(i+0.5); | |
1035 | ceQsum+=signal; | |
1036 | } | |
1037 | } | |
75d8233f | 1038 | } |
ac940b58 | 1039 | } |
1040 | if (ceQmax&&ceQsum>ceSumThreshold) { | |
1041 | ceTime/=ceQsum; | |
1042 | ceRMS = TMath::Sqrt(TMath::Abs(ceRMS/ceQsum-ceTime*ceTime)); | |
880c3382 | 1043 | ceTime-=GetL1PhaseTB(); |
ac940b58 | 1044 | fVTime0Offset.GetMatrixArray()[fCurrentSector]+=ceTime; // mean time for each sector |
1045 | fVTime0OffsetCounter.GetMatrixArray()[fCurrentSector]++; | |
1046 | ||
1047 | //Normalise Q to the 'cell-size': The wire density is the same in the IROC and OROC, therefore the | |
1048 | // the pick-up signal should scale with the pad area. In addition | |
1049 | // the signal should decrease with the wire distance (4mm in IROC, 6mm in OROC), | |
1050 | // ratio 2/3. The pad area we express in cm2. We normalise the signal | |
1051 | // to the OROC signal (factor 2/3 for the IROCs). | |
1052 | Float_t norm = fParam->GetPadPitchWidth(fCurrentSector)*fParam->GetPadPitchLength(fCurrentSector,fCurrentRow); | |
1053 | if ( fCurrentSector<fParam->GetNInnerSector() ) norm*=3./2.; | |
1054 | ||
1055 | ceQsum/=norm; | |
1056 | fVMeanQ.GetMatrixArray()[fCurrentSector]+=ceQsum; | |
1057 | fVMeanQCounter.GetMatrixArray()[fCurrentSector]++; | |
1058 | } else { | |
1059 | ceQmax=0; | |
1060 | ceTime=0; | |
1061 | ceRMS =0; | |
1062 | ceQsum=0; | |
1063 | } | |
1064 | param[0] = ceQmax; | |
880c3382 | 1065 | param[1] = ceTime; |
ac940b58 | 1066 | param[2] = ceRMS; |
1067 | qSum = ceQsum; | |
75d8233f | 1068 | } |
1069 | //_____________________________________________________________________ | |
3cd27a08 | 1070 | Bool_t AliTPCCalibCE::IsPeak(Int_t pos, Int_t tminus, Int_t tplus) const |
75d8233f | 1071 | { |
ac940b58 | 1072 | // |
2963bcbf | 1073 | // Check if 'pos' is a Maximum. Consider 'tminus' timebins before |
1074 | // and 'tplus' timebins after 'pos' | |
ac940b58 | 1075 | // |
1076 | if ( (pos-tminus)<fFirstTimeBin || (pos+tplus)>fLastTimeBin ) return kFALSE; | |
1077 | for (Int_t iTime = pos; iTime>pos-tminus; --iTime) | |
1078 | if ( fPadSignal[iTime-1] >= fPadSignal[iTime] ) return kFALSE; | |
1079 | for (Int_t iTime = pos, iTime2=pos; iTime<pos+tplus; ++iTime, ++iTime2){ | |
1080 | if ( (iTime==pos) && (fPadSignal[iTime+1]==fPadSignal[iTime]) ) // allow two timebins with same adc value | |
1081 | ++iTime2; | |
1082 | if ( fPadSignal[iTime2+1] >= fPadSignal[iTime2] ) return kFALSE; | |
1083 | } | |
1084 | return kTRUE; | |
75d8233f | 1085 | } |
1086 | //_____________________________________________________________________ | |
1087 | void AliTPCCalibCE::FindLocalMaxima(TVectorF &maxima) | |
1088 | { | |
ac940b58 | 1089 | // |
75d8233f | 1090 | // Find local maxima on the pad signal and Histogram them |
ac940b58 | 1091 | // |
4c6d06dc | 1092 | Float_t ceThreshold = fNoiseThresholdMax*TMath::Max(fPadNoise,Float_t(1.)); // threshold for the signal |
ac940b58 | 1093 | Int_t count = 0; |
2963bcbf | 1094 | |
1095 | for (Int_t i=fLastTimeBin-fPeakDetPlus+1; i>=fFirstTimeBin+fPeakDetMinus; --i){ | |
1096 | if ( (fPadSignal[i]-fPadPedestal)<ceThreshold ) continue; | |
1097 | if (IsPeak(i,fPeakDetMinus,fPeakDetPlus) ){ | |
ac940b58 | 1098 | if (count<maxima.GetNrows()){ |
1099 | maxima.GetMatrixArray()[count++]=i; | |
1100 | GetHistoTmean(fCurrentSector,kTRUE)->Fill(i); | |
2963bcbf | 1101 | i-=(fPeakDetMinus+fPeakDetPlus-1); // next peak cannot be at bin fPeakDetMinus+fPeakDetPlus-1 |
ac940b58 | 1102 | } |
75d8233f | 1103 | } |
ac940b58 | 1104 | } |
75d8233f | 1105 | } |
1106 | //_____________________________________________________________________ | |
7fb602b1 | 1107 | void AliTPCCalibCE::ProcessPad() |
75d8233f | 1108 | { |
880c3382 | 1109 | // |
1110 | // Process data of current pad | |
1111 | // | |
1112 | FindPedestal(); | |
1113 | ||
1114 | TVectorF maxima(15); // the expected maximum number of maxima in the complete TPC should be 8 laser beam layers | |
7fb602b1 | 1115 | // + central electrode and possibly post peaks from the CE signal |
1116 | // however if we are on a high noise pad a lot more peaks due to the noise might occur | |
880c3382 | 1117 | FindLocalMaxima(maxima); |
1118 | if ( (fNevents == 0) || (fOldRunNumber!=fRunNumber) ) return; // return because we don't have Time0 info for the CE yet | |
1119 | ||
1120 | UpdateCETimeRef(); // update the time refenrence for the current sector | |
7442bceb | 1121 | if ( fCurrentCETimeRef<1e-30 ) return; //return if we don't have time 0 info, eg if only one side has laser |
880c3382 | 1122 | TVectorD param(3); |
1123 | Float_t qSum; | |
1124 | FindCESignal(param, qSum, maxima); | |
1125 | ||
1126 | Double_t meanT = param[1]; | |
1127 | Double_t sigmaT = param[2]; | |
1128 | ||
75d8233f | 1129 | //Fill Event T0 counter |
880c3382 | 1130 | (*GetPadTimesEvent(fCurrentSector,kTRUE)).GetMatrixArray()[fCurrentChannel] = meanT; |
1131 | ||
75d8233f | 1132 | //Fill Q histogram |
880c3382 | 1133 | GetHistoQ(fCurrentSector,kTRUE)->Fill( TMath::Sqrt(qSum), fCurrentChannel ); |
1134 | ||
75d8233f | 1135 | //Fill RMS histogram |
880c3382 | 1136 | GetHistoRMS(fCurrentSector,kTRUE)->Fill( sigmaT, fCurrentChannel ); |
1137 | ||
1138 | ||
75d8233f | 1139 | //Fill debugging info |
880c3382 | 1140 | if ( GetStreamLevel()>0 ){ |
1141 | (*GetPadPedestalEvent(fCurrentSector,kTRUE)).GetMatrixArray()[fCurrentChannel]=fPadPedestal; | |
1142 | (*GetPadRMSEvent(fCurrentSector,kTRUE)).GetMatrixArray()[fCurrentChannel]=sigmaT; | |
1143 | (*GetPadQEvent(fCurrentSector,kTRUE)).GetMatrixArray()[fCurrentChannel]=qSum; | |
1144 | } | |
1145 | ||
1146 | ResetPad(); | |
75d8233f | 1147 | } |
1148 | //_____________________________________________________________________ | |
7fb602b1 | 1149 | void AliTPCCalibCE::EndEvent() |
75d8233f | 1150 | { |
ac940b58 | 1151 | // Process data of current pad |
1152 | // The Functions 'SetTimeStamp' and 'SetRunNumber' should be called | |
1153 | // before the EndEvent function to set the event timestamp and number!!! | |
1154 | // This is automatically done if the ProcessEvent(AliRawReader *rawReader) | |
1155 | // function was called | |
78f17711 | 1156 | if (!fProcessOld) { |
6e6025f4 | 1157 | if (fProcessNew){ |
1158 | ++fNevents; | |
1159 | ++fEventInBunch; | |
1160 | } | |
78f17711 | 1161 | return; |
1162 | } | |
1163 | ||
ac940b58 | 1164 | //check if last pad has allready been processed, if not do so |
1165 | if ( fMaxTimeBin>-1 ) ProcessPad(); | |
75d8233f | 1166 | |
ac940b58 | 1167 | AliDebug(3, Form("EndEvent() - Start; Event: %05d", fNevents)); |
4c6d06dc | 1168 | |
ac940b58 | 1169 | TVectorD param(3); |
1170 | TMatrixD dummy(3,3); | |
7fb602b1 | 1171 | // TVectorF vMeanTime(72); |
1172 | // TVectorF vMeanQ(72); | |
ac940b58 | 1173 | AliTPCCalROC *calIroc=new AliTPCCalROC(0); |
1174 | AliTPCCalROC *calOroc=new AliTPCCalROC(36); | |
1175 | ||
1176 | //find mean time0 offset for side A and C | |
1177 | //use only orocs due to the better statistics | |
1178 | Double_t time0Side[2]; //time0 for side A:0 and C:1 | |
1179 | Double_t time0SideCount[2]; //time0 counter for side A:0 and C:1 | |
1180 | time0Side[0]=0;time0Side[1]=0;time0SideCount[0]=0;time0SideCount[1]=0; | |
1181 | for ( Int_t iSec = 36; iSec<72; ++iSec ){ | |
1182 | time0Side[(iSec/18)%2] += fVTime0Offset.GetMatrixArray()[iSec]; | |
1183 | time0SideCount[(iSec/18)%2] += fVTime0OffsetCounter.GetMatrixArray()[iSec]; | |
1184 | } | |
1185 | if ( time0SideCount[0] >0 ) | |
1186 | time0Side[0]/=time0SideCount[0]; | |
1187 | if ( time0SideCount[1] >0 ) | |
1188 | time0Side[1]/=time0SideCount[1]; | |
75d8233f | 1189 | // end find time0 offset |
ac940b58 | 1190 | AliDebug(3,Form("time0Side/time0SideCount: A=%.2f/%.2f, C=%.2f/%.2f",time0Side[0],time0SideCount[0],time0Side[1],time0SideCount[1])); |
1191 | Int_t nSecMeanT=0; | |
1192 | //loop over all ROCs, fill CE Time histogram corrected for the mean Time0 of each ROC | |
1193 | for ( Int_t iSec = 0; iSec<72; ++iSec ){ | |
1194 | AliDebug(4,Form("Processing sector '%02d'\n",iSec)); | |
1195 | //find median and then calculate the mean around it | |
1196 | TH1S *hMeanT = GetHistoTmean(iSec); //histogram with local maxima position information | |
1197 | if ( !hMeanT ) continue; | |
1198 | //continue if not enough data is filled in the meanT histogram. This is the case if we do not have a laser event. | |
1199 | if ( hMeanT->GetEffectiveEntries() < fROC->GetNChannels(iSec)*fSecRejectRatio ){ | |
1200 | hMeanT->Reset(); | |
1201 | AliDebug(3,Form("Skipping sec. '%02d': Not enough statistics\n",iSec)); | |
1202 | continue; | |
1203 | } | |
1204 | ||
1205 | Double_t entries = hMeanT->GetEffectiveEntries(); | |
1206 | Double_t sum = 0; | |
1207 | Short_t *arr = hMeanT->GetArray()+1; | |
1208 | Int_t ibin=0; | |
1209 | for ( ibin=0; ibin<hMeanT->GetNbinsX(); ++ibin){ | |
1210 | sum+=arr[ibin]; | |
1211 | if ( sum>=(entries/2.) ) break; | |
1212 | } | |
1213 | Int_t delta = 4; | |
1214 | Int_t firstBin = fFirstTimeBin+ibin-delta; | |
1215 | Int_t lastBin = fFirstTimeBin+ibin+delta; | |
1216 | if ( firstBin<fFirstTimeBin ) firstBin=fFirstTimeBin; | |
1217 | if ( lastBin>fLastTimeBin ) lastBin =fLastTimeBin; | |
1218 | Float_t median =AliMathBase::GetCOG(arr+ibin-delta,2*delta,firstBin,lastBin); | |
1219 | ||
7fb602b1 | 1220 | // check boundaries for ebye info of mean time |
ac940b58 | 1221 | TVectorF *vMeanTime=GetTMeanEvents(iSec,kTRUE); |
1222 | Int_t vSize=vMeanTime->GetNrows(); | |
1223 | if ( vSize < fNevents+1 ){ | |
1224 | vMeanTime->ResizeTo(vSize+100); | |
1225 | } | |
880c3382 | 1226 | |
1227 | // store mean time for the readout sides | |
1228 | vSize=fVTime0SideA.GetNrows(); | |
1229 | if ( vSize < fNevents+1 ){ | |
1230 | fVTime0SideA.ResizeTo(vSize+100); | |
1231 | fVTime0SideC.ResizeTo(vSize+100); | |
1232 | } | |
1233 | fVTime0SideA.GetMatrixArray()[fNevents]=time0Side[0]; | |
1234 | fVTime0SideC.GetMatrixArray()[fNevents]=time0Side[1]; | |
ac940b58 | 1235 | |
1236 | vMeanTime->GetMatrixArray()[fNevents]=median; | |
1237 | nSecMeanT++; | |
1238 | // end find median | |
1239 | ||
1240 | TVectorF *vTimes = GetPadTimesEvent(iSec); | |
1241 | if ( !vTimes ) continue; //continue if no time information for this sector is available | |
1242 | ||
1243 | AliTPCCalROC calIrocOutliers(0); | |
1244 | AliTPCCalROC calOrocOutliers(36); | |
1245 | ||
1246 | // calculate mean Q of the sector | |
1247 | TVectorF *vMeanQ=GetQMeanEvents(iSec,kTRUE); | |
1248 | vSize=vMeanQ->GetNrows(); | |
1249 | if ( vSize < fNevents+1 ){ | |
1250 | vMeanQ->ResizeTo(vSize+100); | |
1251 | } | |
1252 | Float_t meanQ = 0; | |
1253 | if ( fVMeanQCounter.GetMatrixArray()[iSec]>0 ) meanQ=fVMeanQ.GetMatrixArray()[iSec]/fVMeanQCounter.GetMatrixArray()[iSec]; | |
1254 | vMeanQ->GetMatrixArray()[fNevents]=meanQ; | |
1255 | ||
1256 | for ( UInt_t iChannel=0; iChannel<fROC->GetNChannels(iSec); ++iChannel ){ | |
1257 | Float_t time = (*vTimes).GetMatrixArray()[iChannel]; | |
75d8233f | 1258 | |
1259 | //set values for temporary roc calibration class | |
ac940b58 | 1260 | if ( iSec < 36 ) { |
1261 | calIroc->SetValue(iChannel, time); | |
7442bceb | 1262 | if ( TMath::Abs(time) < 1e-30 ) calIrocOutliers.SetValue(iChannel,1); |
bf57d87d | 1263 | |
ac940b58 | 1264 | } else { |
1265 | calOroc->SetValue(iChannel, time); | |
7442bceb | 1266 | if ( TMath::Abs(time) < 1e-30 ) calOrocOutliers.SetValue(iChannel,1); |
ac940b58 | 1267 | } |
75d8233f | 1268 | |
ac940b58 | 1269 | if ( (fNevents>0) && (fOldRunNumber==fRunNumber) ) |
c3066940 | 1270 | // test that we really found the CE signal reliably |
1271 | if ( TMath::Abs(fVTime0SideA.GetMatrixArray()[fNevents-1]-time0Side[0])<.05) | |
1272 | GetHistoT0(iSec,kTRUE)->Fill( time-time0Side[(iSec/18)%2],iChannel ); | |
75d8233f | 1273 | |
1274 | ||
1275 | ||
1276 | //------------------------------- Debug start ------------------------------ | |
880c3382 | 1277 | if ( GetStreamLevel()>0 ){ |
1278 | TTreeSRedirector *streamer=GetDebugStreamer(); | |
1279 | if (streamer){ | |
1280 | Int_t row=0; | |
1281 | Int_t pad=0; | |
1282 | Int_t padc=0; | |
1283 | ||
1284 | Float_t q = (*GetPadQEvent(iSec))[iChannel]; | |
1285 | Float_t rms = (*GetPadRMSEvent(iSec))[iChannel]; | |
1286 | ||
1287 | UInt_t channel=iChannel; | |
1288 | Int_t sector=iSec; | |
1289 | ||
1290 | while ( channel > (fROC->GetRowIndexes(sector)[row]+fROC->GetNPads(sector,row)-1) ) row++; | |
1291 | pad = channel-fROC->GetRowIndexes(sector)[row]; | |
1292 | padc = pad-(fROC->GetNPads(sector,row)/2); | |
1293 | ||
75d8233f | 1294 | // TH1F *h1 = new TH1F(Form("hSignalD%d.%d.%d",sector,row,pad), |
1295 | // Form("hSignalD%d.%d.%d",sector,row,pad), | |
1296 | // fLastTimeBin-fFirstTimeBin, | |
1297 | // fFirstTimeBin,fLastTimeBin); | |
1298 | // h1->SetDirectory(0); | |
ac940b58 | 1299 | // |
7fb602b1 | 1300 | // for (Int_t i=fFirstTimeBin; i<fLastTimeBin+1; ++i) |
75d8233f | 1301 | // h1->Fill(i,fPadSignal(i)); |
880c3382 | 1302 | |
1303 | Double_t t0Sec = 0; | |
1304 | if (fVTime0OffsetCounter.GetMatrixArray()[iSec]>0) | |
1305 | t0Sec = fVTime0Offset.GetMatrixArray()[iSec]/fVTime0OffsetCounter.GetMatrixArray()[iSec]; | |
1306 | Double_t t0Side = time0Side[(iSec/18)%2]; | |
1307 | (*streamer) << "DataPad" << | |
ac940b58 | 1308 | "Event=" << fNevents << |
1309 | "RunNumber=" << fRunNumber << | |
1310 | "TimeStamp=" << fTimeStamp << | |
1311 | "Sector="<< sector << | |
1312 | "Row=" << row<< | |
1313 | "Pad=" << pad << | |
1314 | "PadC=" << padc << | |
1315 | "PadSec="<< channel << | |
1316 | "Time0Sec=" << t0Sec << | |
1317 | "Time0Side=" << t0Side << | |
1318 | "Time=" << time << | |
1319 | "RMS=" << rms << | |
1320 | "Sum=" << q << | |
1321 | "MeanQ=" << meanQ << | |
880c3382 | 1322 | // "hist.=" << h1 << |
ac940b58 | 1323 | "\n"; |
880c3382 | 1324 | |
1325 | // delete h1; | |
1326 | } | |
ac940b58 | 1327 | } |
880c3382 | 1328 | //----------------------------- Debug end ------------------------------ |
ac940b58 | 1329 | }// end channel loop |
1330 | ||
75d8233f | 1331 | |
2963bcbf | 1332 | //do fitting now only in debug mode |
1333 | if (GetDebugLevel()>0){ | |
1334 | TVectorD paramPol1(3); | |
1335 | TVectorD paramPol2(6); | |
1336 | TMatrixD matPol1(3,3); | |
1337 | TMatrixD matPol2(6,6); | |
1338 | Float_t chi2Pol1=0; | |
1339 | Float_t chi2Pol2=0; | |
1340 | ||
1341 | if ( (fNevents>0) && (fOldRunNumber==fRunNumber) ){ | |
1342 | if ( iSec < 36 ){ | |
1343 | calIroc->GlobalFit(&calIrocOutliers,0,paramPol1,matPol1,chi2Pol1,0); | |
1344 | calIroc->GlobalFit(&calIrocOutliers,0,paramPol2,matPol2,chi2Pol2,1); | |
1345 | } else { | |
1346 | calOroc->GlobalFit(&calOrocOutliers,0,paramPol1,matPol1,chi2Pol1,0); | |
1347 | calOroc->GlobalFit(&calOrocOutliers,0,paramPol2,matPol2,chi2Pol2,1); | |
1348 | } | |
1349 | ||
1350 | GetParamArrayPol1(iSec,kTRUE)->AddAtAndExpand(new TVectorD(paramPol1), fNevents); | |
1351 | GetParamArrayPol2(iSec,kTRUE)->AddAtAndExpand(new TVectorD(paramPol2), fNevents); | |
1352 | } | |
1353 | ||
1354 | //------------------------------- Debug start ------------------------------ | |
1355 | if ( GetStreamLevel()>0 ){ | |
1356 | TTreeSRedirector *streamer=GetDebugStreamer(); | |
1357 | if ( streamer ) { | |
1358 | (*streamer) << "DataRoc" << | |
1359 | // "Event=" << fEvent << | |
1360 | "RunNumber=" << fRunNumber << | |
1361 | "TimeStamp=" << fTimeStamp << | |
1362 | "Sector="<< iSec << | |
1363 | "hMeanT.=" << hMeanT << | |
1364 | "median=" << median << | |
1365 | "paramPol1.=" << ¶mPol1 << | |
1366 | "paramPol2.=" << ¶mPol2 << | |
1367 | "matPol1.=" << &matPol1 << | |
1368 | "matPol2.=" << &matPol2 << | |
1369 | "chi2Pol1=" << chi2Pol1 << | |
1370 | "chi2Pol2=" << chi2Pol2 << | |
1371 | "\n"; | |
1372 | } | |
880c3382 | 1373 | } |
ac940b58 | 1374 | } |
75d8233f | 1375 | //------------------------------- Debug end ------------------------------ |
ac940b58 | 1376 | hMeanT->Reset(); |
1377 | }// end sector loop | |
4d885988 | 1378 | //return if no sector has a valid mean time |
ac940b58 | 1379 | if ( nSecMeanT == 0 ) return; |
4d885988 | 1380 | |
1381 | ||
7fb602b1 | 1382 | // fTMeanArrayEvent.AddAtAndExpand(new TVectorF(vMeanTime),fNevents); |
1383 | // fQMeanArrayEvent.AddAtAndExpand(new TVectorF(vMeanQ),fNevents); | |
ac940b58 | 1384 | if ( fVEventTime.GetNrows() < fNevents+1 ) { |
1385 | fVEventTime.ResizeTo((Int_t)(fVEventTime.GetNrows()+100)); | |
1386 | fVEventNumber.ResizeTo((Int_t)(fVEventNumber.GetNrows()+100)); | |
1387 | } | |
1388 | fVEventTime.GetMatrixArray()[fNevents] = fTimeStamp; | |
1389 | fVEventNumber.GetMatrixArray()[fNevents] = fEventId; | |
75d8233f | 1390 | |
78f17711 | 1391 | ++fNevents; |
6e6025f4 | 1392 | if (fProcessNew) ++fEventInBunch; |
ac940b58 | 1393 | fOldRunNumber = fRunNumber; |
75d8233f | 1394 | |
ac940b58 | 1395 | delete calIroc; |
1396 | delete calOroc; | |
1397 | AliDebug(3, Form("EndEvent() - End; Event: %05d", fNevents)); | |
75d8233f | 1398 | } |
1399 | //_____________________________________________________________________ | |
7fb602b1 | 1400 | TH2S* AliTPCCalibCE::GetHisto(Int_t sector, TObjArray *arr, |
75d8233f | 1401 | Int_t nbinsY, Float_t ymin, Float_t ymax, |
a6e0ebfe | 1402 | const Char_t *type, Bool_t force) |
75d8233f | 1403 | { |
1404 | // | |
1405 | // return pointer to TH2S histogram of 'type' | |
1406 | // if force is true create a new histogram if it doesn't exist allready | |
1407 | // | |
1408 | if ( !force || arr->UncheckedAt(sector) ) | |
a3b590cf | 1409 | return (TH2S*)arr->UncheckedAt(sector); |
75d8233f | 1410 | |
7fb602b1 | 1411 | // if we are forced and histogram doesn't exist yet create it |
75d8233f | 1412 | // new histogram with Q calib information. One value for each pad! |
a3b590cf | 1413 | TH2S* hist = new TH2S(Form("hCalib%s%.2d",type,sector),Form("%s calibration histogram sector %.2d",type,sector), |
75d8233f | 1414 | nbinsY, ymin, ymax, |
1415 | fROC->GetNChannels(sector),0,fROC->GetNChannels(sector)); | |
1416 | hist->SetDirectory(0); | |
1417 | arr->AddAt(hist,sector); | |
1418 | return hist; | |
1419 | } | |
1420 | //_____________________________________________________________________ | |
7fb602b1 | 1421 | TH2S* AliTPCCalibCE::GetHistoT0(Int_t sector, Bool_t force) |
75d8233f | 1422 | { |
1423 | // | |
1424 | // return pointer to T0 histogram | |
1425 | // if force is true create a new histogram if it doesn't exist allready | |
1426 | // | |
1427 | TObjArray *arr = &fHistoT0Array; | |
1428 | return GetHisto(sector, arr, fNbinsT0, fXminT0, fXmaxT0, "T0", force); | |
1429 | } | |
1430 | //_____________________________________________________________________ | |
7fb602b1 | 1431 | TH2S* AliTPCCalibCE::GetHistoQ(Int_t sector, Bool_t force) |
75d8233f | 1432 | { |
1433 | // | |
1434 | // return pointer to Q histogram | |
1435 | // if force is true create a new histogram if it doesn't exist allready | |
1436 | // | |
1437 | TObjArray *arr = &fHistoQArray; | |
1438 | return GetHisto(sector, arr, fNbinsQ, fXminQ, fXmaxQ, "Q", force); | |
1439 | } | |
1440 | //_____________________________________________________________________ | |
7fb602b1 | 1441 | TH2S* AliTPCCalibCE::GetHistoRMS(Int_t sector, Bool_t force) |
75d8233f | 1442 | { |
1443 | // | |
1444 | // return pointer to Q histogram | |
1445 | // if force is true create a new histogram if it doesn't exist allready | |
1446 | // | |
1447 | TObjArray *arr = &fHistoRMSArray; | |
1448 | return GetHisto(sector, arr, fNbinsRMS, fXminRMS, fXmaxRMS, "RMS", force); | |
1449 | } | |
1450 | //_____________________________________________________________________ | |
1451 | TH1S* AliTPCCalibCE::GetHisto(Int_t sector, TObjArray *arr, | |
a6e0ebfe | 1452 | const Char_t *type, Bool_t force) |
75d8233f | 1453 | { |
1454 | // | |
1455 | // return pointer to TH1S histogram | |
1456 | // if force is true create a new histogram if it doesn't exist allready | |
1457 | // | |
1458 | if ( !force || arr->UncheckedAt(sector) ) | |
a3b590cf | 1459 | return (TH1S*)arr->UncheckedAt(sector); |
75d8233f | 1460 | |
1461 | // if we are forced and histogram doesn't yes exist create it | |
4d885988 | 1462 | // new histogram with calib information. One value for each pad! |
a3b590cf | 1463 | TH1S* hist = new TH1S(Form("hCalib%s%.2d",type,sector),Form("%s calibration histogram sector %.2d",type,sector), |
75d8233f | 1464 | fLastTimeBin-fFirstTimeBin,fFirstTimeBin,fLastTimeBin); |
1465 | hist->SetDirectory(0); | |
1466 | arr->AddAt(hist,sector); | |
1467 | return hist; | |
1468 | } | |
1469 | //_____________________________________________________________________ | |
1470 | TH1S* AliTPCCalibCE::GetHistoTmean(Int_t sector, Bool_t force) | |
1471 | { | |
1472 | // | |
1473 | // return pointer to Q histogram | |
1474 | // if force is true create a new histogram if it doesn't exist allready | |
1475 | // | |
1476 | TObjArray *arr = &fHistoTmean; | |
1477 | return GetHisto(sector, arr, "LastTmean", force); | |
1478 | } | |
1479 | //_____________________________________________________________________ | |
3cd27a08 | 1480 | TVectorF* AliTPCCalibCE::GetVectSector(Int_t sector, TObjArray *arr, UInt_t size, Bool_t force) const |
75d8233f | 1481 | { |
1482 | // | |
1483 | // return pointer to Pad Info from 'arr' for the current event and sector | |
1484 | // if force is true create it if it doesn't exist allready | |
1485 | // | |
1486 | if ( !force || arr->UncheckedAt(sector) ) | |
1487 | return (TVectorF*)arr->UncheckedAt(sector); | |
1488 | ||
7fb602b1 | 1489 | TVectorF *vect = new TVectorF(size); |
75d8233f | 1490 | arr->AddAt(vect,sector); |
1491 | return vect; | |
1492 | } | |
1493 | //_____________________________________________________________________ | |
7fb602b1 | 1494 | TVectorF* AliTPCCalibCE::GetPadTimesEvent(Int_t sector, Bool_t force) |
75d8233f | 1495 | { |
1496 | // | |
1497 | // return pointer to Pad Times Array for the current event and sector | |
1498 | // if force is true create it if it doesn't exist allready | |
1499 | // | |
1500 | TObjArray *arr = &fPadTimesArrayEvent; | |
7fb602b1 | 1501 | return GetVectSector(sector,arr,fROC->GetNChannels(sector),force); |
75d8233f | 1502 | } |
1503 | //_____________________________________________________________________ | |
7fb602b1 | 1504 | TVectorF* AliTPCCalibCE::GetPadQEvent(Int_t sector, Bool_t force) |
75d8233f | 1505 | { |
1506 | // | |
1507 | // return pointer to Pad Q Array for the current event and sector | |
1508 | // if force is true create it if it doesn't exist allready | |
1509 | // for debugging purposes only | |
1510 | // | |
1511 | ||
1512 | TObjArray *arr = &fPadQArrayEvent; | |
7fb602b1 | 1513 | return GetVectSector(sector,arr,fROC->GetNChannels(sector),force); |
75d8233f | 1514 | } |
1515 | //_____________________________________________________________________ | |
7fb602b1 | 1516 | TVectorF* AliTPCCalibCE::GetPadRMSEvent(Int_t sector, Bool_t force) |
75d8233f | 1517 | { |
1518 | // | |
1519 | // return pointer to Pad RMS Array for the current event and sector | |
1520 | // if force is true create it if it doesn't exist allready | |
1521 | // for debugging purposes only | |
1522 | // | |
1523 | TObjArray *arr = &fPadRMSArrayEvent; | |
7fb602b1 | 1524 | return GetVectSector(sector,arr,fROC->GetNChannels(sector),force); |
75d8233f | 1525 | } |
1526 | //_____________________________________________________________________ | |
7fb602b1 | 1527 | TVectorF* AliTPCCalibCE::GetPadPedestalEvent(Int_t sector, Bool_t force) |
75d8233f | 1528 | { |
1529 | // | |
1530 | // return pointer to Pad RMS Array for the current event and sector | |
1531 | // if force is true create it if it doesn't exist allready | |
1532 | // for debugging purposes only | |
1533 | // | |
1534 | TObjArray *arr = &fPadPedestalArrayEvent; | |
7fb602b1 | 1535 | return GetVectSector(sector,arr,fROC->GetNChannels(sector),force); |
1536 | } | |
1537 | //_____________________________________________________________________ | |
1538 | TVectorF* AliTPCCalibCE::GetTMeanEvents(Int_t sector, Bool_t force) | |
1539 | { | |
1540 | // | |
1541 | // return pointer to the EbyE info of the mean arrival time for 'sector' | |
1542 | // if force is true create it if it doesn't exist allready | |
1543 | // | |
1544 | TObjArray *arr = &fTMeanArrayEvent; | |
1545 | return GetVectSector(sector,arr,100,force); | |
75d8233f | 1546 | } |
1547 | //_____________________________________________________________________ | |
7fb602b1 | 1548 | TVectorF* AliTPCCalibCE::GetQMeanEvents(Int_t sector, Bool_t force) |
1549 | { | |
1550 | // | |
1551 | // return pointer to the EbyE info of the mean arrival time for 'sector' | |
1552 | // if force is true create it if it doesn't exist allready | |
1553 | // | |
1554 | TObjArray *arr = &fQMeanArrayEvent; | |
1555 | return GetVectSector(sector,arr,100,force); | |
1556 | } | |
1557 | //_____________________________________________________________________ | |
3cd27a08 | 1558 | AliTPCCalROC* AliTPCCalibCE::GetCalRoc(Int_t sector, TObjArray* arr, Bool_t force) const |
75d8233f | 1559 | { |
1560 | // | |
1561 | // return pointer to ROC Calibration | |
1562 | // if force is true create a new histogram if it doesn't exist allready | |
1563 | // | |
1564 | if ( !force || arr->UncheckedAt(sector) ) | |
1565 | return (AliTPCCalROC*)arr->UncheckedAt(sector); | |
1566 | ||
1567 | // if we are forced and histogram doesn't yes exist create it | |
1568 | ||
1569 | // new AliTPCCalROC for T0 information. One value for each pad! | |
1570 | AliTPCCalROC *croc = new AliTPCCalROC(sector); | |
75d8233f | 1571 | arr->AddAt(croc,sector); |
1572 | return croc; | |
1573 | } | |
1574 | //_____________________________________________________________________ | |
7fb602b1 | 1575 | AliTPCCalROC* AliTPCCalibCE::GetCalRocT0(Int_t sector, Bool_t force) |
75d8233f | 1576 | { |
1577 | // | |
ef7f7670 | 1578 | // return pointer to Time 0 ROC Calibration |
75d8233f | 1579 | // if force is true create a new histogram if it doesn't exist allready |
1580 | // | |
1581 | TObjArray *arr = &fCalRocArrayT0; | |
1582 | return GetCalRoc(sector, arr, force); | |
1583 | } | |
1584 | //_____________________________________________________________________ | |
ef7f7670 | 1585 | AliTPCCalROC* AliTPCCalibCE::GetCalRocT0Err(Int_t sector, Bool_t force) |
1586 | { | |
1587 | // | |
1588 | // return pointer to the error of Time 0 ROC Calibration | |
1589 | // if force is true create a new histogram if it doesn't exist allready | |
1590 | // | |
1591 | TObjArray *arr = &fCalRocArrayT0Err; | |
1592 | return GetCalRoc(sector, arr, force); | |
1593 | } | |
1594 | //_____________________________________________________________________ | |
7fb602b1 | 1595 | AliTPCCalROC* AliTPCCalibCE::GetCalRocQ(Int_t sector, Bool_t force) |
75d8233f | 1596 | { |
1597 | // | |
1598 | // return pointer to T0 ROC Calibration | |
1599 | // if force is true create a new histogram if it doesn't exist allready | |
1600 | // | |
1601 | TObjArray *arr = &fCalRocArrayQ; | |
1602 | return GetCalRoc(sector, arr, force); | |
1603 | } | |
1604 | //_____________________________________________________________________ | |
7fb602b1 | 1605 | AliTPCCalROC* AliTPCCalibCE::GetCalRocRMS(Int_t sector, Bool_t force) |
75d8233f | 1606 | { |
1607 | // | |
1608 | // return pointer to signal width ROC Calibration | |
1609 | // if force is true create a new histogram if it doesn't exist allready | |
1610 | // | |
1611 | TObjArray *arr = &fCalRocArrayRMS; | |
1612 | return GetCalRoc(sector, arr, force); | |
1613 | } | |
1614 | //_____________________________________________________________________ | |
1615 | AliTPCCalROC* AliTPCCalibCE::GetCalRocOutliers(Int_t sector, Bool_t force) | |
1616 | { | |
1617 | // | |
1618 | // return pointer to Outliers | |
1619 | // if force is true create a new histogram if it doesn't exist allready | |
1620 | // | |
1621 | TObjArray *arr = &fCalRocArrayOutliers; | |
1622 | return GetCalRoc(sector, arr, force); | |
1623 | } | |
1624 | //_____________________________________________________________________ | |
3cd27a08 | 1625 | TObjArray* AliTPCCalibCE::GetParamArray(Int_t sector, TObjArray* arr, Bool_t force) const |
75d8233f | 1626 | { |
1627 | // | |
1628 | // return pointer to TObjArray of fit parameters | |
1629 | // if force is true create a new histogram if it doesn't exist allready | |
1630 | // | |
1631 | if ( !force || arr->UncheckedAt(sector) ) | |
1632 | return (TObjArray*)arr->UncheckedAt(sector); | |
1633 | ||
1634 | // if we are forced and array doesn't yes exist create it | |
1635 | ||
1636 | // new TObjArray for parameters | |
1637 | TObjArray *newArr = new TObjArray; | |
1638 | arr->AddAt(newArr,sector); | |
1639 | return newArr; | |
1640 | } | |
1641 | //_____________________________________________________________________ | |
1642 | TObjArray* AliTPCCalibCE::GetParamArrayPol1(Int_t sector, Bool_t force) | |
1643 | { | |
1644 | // | |
1645 | // return pointer to TObjArray of fit parameters from plane fit | |
1646 | // if force is true create a new histogram if it doesn't exist allready | |
1647 | // | |
1648 | TObjArray *arr = &fParamArrayEventPol1; | |
1649 | return GetParamArray(sector, arr, force); | |
1650 | } | |
1651 | //_____________________________________________________________________ | |
1652 | TObjArray* AliTPCCalibCE::GetParamArrayPol2(Int_t sector, Bool_t force) | |
1653 | { | |
1654 | // | |
1655 | // return pointer to TObjArray of fit parameters from parabola fit | |
1656 | // if force is true create a new histogram if it doesn't exist allready | |
1657 | // | |
1658 | TObjArray *arr = &fParamArrayEventPol2; | |
1659 | return GetParamArray(sector, arr, force); | |
1660 | } | |
78f17711 | 1661 | |
1662 | //_____________________________________________________________________ | |
1663 | void AliTPCCalibCE::CreateDVhist() | |
1664 | { | |
1665 | // | |
1666 | // Setup the THnSparse for the drift velocity determination | |
1667 | // | |
1668 | ||
1669 | //HnSparse bins | |
1670 | //roc, row, pad, timebin, timestamp | |
1671 | TTimeStamp begin(2010,01,01,0,0,0); | |
1672 | TTimeStamp end(2035,01,01,0,0,0); | |
1673 | Int_t nbinsTime=(end.GetSec()-begin.GetSec())/60; //Minutes resolution | |
1674 | ||
1675 | Int_t bins[kHnBinsDV] = { 72, 96, 140, 1030, nbinsTime}; | |
1676 | Double_t xmin[kHnBinsDV] = { 0., 0., 0., 0., (Double_t)begin.GetSec()}; | |
1677 | Double_t xmax[kHnBinsDV] = {72., 96., 140., 1030., (Double_t)end.GetSec()}; | |
1678 | ||
1679 | fHnDrift=new THnSparseI("fHnDrift","Laser digits",kHnBinsDV, bins, xmin, xmax); | |
1680 | fHnDrift->GetAxis(0)->SetNameTitle("ROC","Read-out chamber number"); | |
1681 | fHnDrift->GetAxis(1)->SetNameTitle("Row","Row number"); | |
1682 | fHnDrift->GetAxis(2)->SetNameTitle("Pad","Pad number"); | |
1683 | fHnDrift->GetAxis(3)->SetNameTitle("Timebin","Time bin [x100ns]"); | |
1684 | fHnDrift->GetAxis(4)->SetNameTitle("EventTime","Event time"); | |
6e6025f4 | 1685 | fHnDrift->Reset(); |
78f17711 | 1686 | } |
1687 | ||
75d8233f | 1688 | //_____________________________________________________________________ |
7fb602b1 | 1689 | void AliTPCCalibCE::ResetEvent() |
75d8233f | 1690 | { |
1691 | // | |
1692 | // Reset global counters -- Should be called before each event is processed | |
1693 | // | |
1694 | fLastSector=-1; | |
1695 | fCurrentSector=-1; | |
1696 | fCurrentRow=-1; | |
1697 | fCurrentChannel=-1; | |
1698 | ||
1699 | ResetPad(); | |
1700 | ||
1701 | fPadTimesArrayEvent.Delete(); | |
1702 | fPadQArrayEvent.Delete(); | |
1703 | fPadRMSArrayEvent.Delete(); | |
1704 | fPadPedestalArrayEvent.Delete(); | |
1705 | ||
7fb602b1 | 1706 | for ( Int_t i=0; i<72; ++i ){ |
bf57d87d | 1707 | fVTime0Offset.GetMatrixArray()[i]=0; |
1708 | fVTime0OffsetCounter.GetMatrixArray()[i]=0; | |
1709 | fVMeanQ.GetMatrixArray()[i]=0; | |
1710 | fVMeanQCounter.GetMatrixArray()[i]=0; | |
75d8233f | 1711 | } |
1712 | } | |
1713 | //_____________________________________________________________________ | |
7fb602b1 | 1714 | void AliTPCCalibCE::ResetPad() |
75d8233f | 1715 | { |
1716 | // | |
1717 | // Reset pad infos -- Should be called after a pad has been processed | |
1718 | // | |
7fb602b1 | 1719 | for (Int_t i=fFirstTimeBin; i<fLastTimeBin+1; ++i) |
2963bcbf | 1720 | fPadSignal[i] = 0; |
75d8233f | 1721 | fMaxTimeBin = -1; |
1722 | fMaxPadSignal = -1; | |
1723 | fPadPedestal = -1; | |
1724 | fPadNoise = -1; | |
1725 | } | |
1726 | //_____________________________________________________________________ | |
7442bceb | 1727 | void AliTPCCalibCE::Merge(AliTPCCalibCE * const ce) |
7fb602b1 | 1728 | { |
7442bceb | 1729 | // |
1730 | // Merge ce to the current AliTPCCalibCE | |
1731 | // | |
78f17711 | 1732 | MergeBase(ce); |
1733 | Int_t nCEevents = ce->GetNeventsProcessed(); | |
7442bceb | 1734 | |
78f17711 | 1735 | if (fProcessOld&&ce->fProcessOld){ |
7442bceb | 1736 | //merge histograms |
78f17711 | 1737 | for (Int_t iSec=0; iSec<72; ++iSec){ |
1738 | TH2S *hRefQmerge = ce->GetHistoQ(iSec); | |
1739 | TH2S *hRefT0merge = ce->GetHistoT0(iSec); | |
1740 | TH2S *hRefRMSmerge = ce->GetHistoRMS(iSec); | |
1741 | ||
1742 | ||
1743 | if ( hRefQmerge ){ | |
1744 | TDirectory *dir = hRefQmerge->GetDirectory(); hRefQmerge->SetDirectory(0); | |
1745 | TH2S *hRefQ = GetHistoQ(iSec); | |
1746 | if ( hRefQ ) hRefQ->Add(hRefQmerge); | |
1747 | else { | |
1748 | TH2S *hist = new TH2S(*hRefQmerge); | |
1749 | hist->SetDirectory(0); | |
1750 | fHistoQArray.AddAt(hist, iSec); | |
1751 | } | |
1752 | hRefQmerge->SetDirectory(dir); | |
7442bceb | 1753 | } |
78f17711 | 1754 | if ( hRefT0merge ){ |
1755 | TDirectory *dir = hRefT0merge->GetDirectory(); hRefT0merge->SetDirectory(0); | |
1756 | TH2S *hRefT0 = GetHistoT0(iSec); | |
1757 | if ( hRefT0 ) hRefT0->Add(hRefT0merge); | |
1758 | else { | |
1759 | TH2S *hist = new TH2S(*hRefT0merge); | |
1760 | hist->SetDirectory(0); | |
1761 | fHistoT0Array.AddAt(hist, iSec); | |
1762 | } | |
1763 | hRefT0merge->SetDirectory(dir); | |
7442bceb | 1764 | } |
78f17711 | 1765 | if ( hRefRMSmerge ){ |
1766 | TDirectory *dir = hRefRMSmerge->GetDirectory(); hRefRMSmerge->SetDirectory(0); | |
1767 | TH2S *hRefRMS = GetHistoRMS(iSec); | |
1768 | if ( hRefRMS ) hRefRMS->Add(hRefRMSmerge); | |
1769 | else { | |
1770 | TH2S *hist = new TH2S(*hRefRMSmerge); | |
1771 | hist->SetDirectory(0); | |
1772 | fHistoRMSArray.AddAt(hist, iSec); | |
1773 | } | |
1774 | hRefRMSmerge->SetDirectory(dir); | |
7442bceb | 1775 | } |
78f17711 | 1776 | |
7442bceb | 1777 | } |
1778 | ||
7fb602b1 | 1779 | // merge time information |
7442bceb | 1780 | |
7442bceb | 1781 | |
78f17711 | 1782 | for (Int_t iSec=0; iSec<72; ++iSec){ |
1783 | TObjArray *arrPol1CE = ce->GetParamArrayPol1(iSec); | |
1784 | TObjArray *arrPol2CE = ce->GetParamArrayPol2(iSec); | |
1785 | TVectorF *vMeanTimeCE = ce->GetTMeanEvents(iSec); | |
1786 | TVectorF *vMeanQCE = ce->GetQMeanEvents(iSec); | |
1787 | ||
1788 | TObjArray *arrPol1 = 0x0; | |
1789 | TObjArray *arrPol2 = 0x0; | |
1790 | TVectorF *vMeanTime = 0x0; | |
1791 | TVectorF *vMeanQ = 0x0; | |
1792 | ||
7442bceb | 1793 | //resize arrays |
78f17711 | 1794 | if ( arrPol1CE && arrPol2CE ){ |
1795 | arrPol1 = GetParamArrayPol1(iSec,kTRUE); | |
1796 | arrPol2 = GetParamArrayPol2(iSec,kTRUE); | |
1797 | arrPol1->Expand(fNevents+nCEevents); | |
1798 | arrPol2->Expand(fNevents+nCEevents); | |
1799 | } | |
1800 | if ( vMeanTimeCE && vMeanQCE ){ | |
1801 | vMeanTime = GetTMeanEvents(iSec,kTRUE); | |
1802 | vMeanQ = GetQMeanEvents(iSec,kTRUE); | |
1803 | vMeanTime->ResizeTo(fNevents+nCEevents); | |
1804 | vMeanQ->ResizeTo(fNevents+nCEevents); | |
1805 | } | |
1806 | ||
1807 | for (Int_t iEvent=0; iEvent<nCEevents; ++iEvent){ | |
1808 | if ( arrPol1CE && arrPol2CE ){ | |
1809 | TVectorD *paramPol1 = (TVectorD*)(arrPol1CE->UncheckedAt(iEvent)); | |
1810 | TVectorD *paramPol2 = (TVectorD*)(arrPol2CE->UncheckedAt(iEvent)); | |
1811 | if ( paramPol1 && paramPol2 ){ | |
1812 | GetParamArrayPol1(iSec,kTRUE)->AddAt(new TVectorD(*paramPol1), fNevents+iEvent); | |
1813 | GetParamArrayPol2(iSec,kTRUE)->AddAt(new TVectorD(*paramPol2), fNevents+iEvent); | |
1814 | } | |
1815 | } | |
1816 | if ( vMeanTimeCE && vMeanQCE ){ | |
1817 | vMeanTime->GetMatrixArray()[fNevents+iEvent]=vMeanTimeCE->GetMatrixArray()[iEvent]; | |
1818 | vMeanQ->GetMatrixArray()[fNevents+iEvent]=vMeanQCE->GetMatrixArray()[iEvent]; | |
1819 | } | |
1820 | } | |
7442bceb | 1821 | } |
1822 | ||
1823 | ||
78f17711 | 1824 | |
1825 | const TVectorD& eventTimes = ce->fVEventTime; | |
1826 | const TVectorD& eventIds = ce->fVEventNumber; | |
1827 | const TVectorF& time0SideA = ce->fVTime0SideA; | |
1828 | const TVectorF& time0SideC = ce->fVTime0SideC; | |
1829 | fVEventTime.ResizeTo(fNevents+nCEevents); | |
1830 | fVEventNumber.ResizeTo(fNevents+nCEevents); | |
1831 | fVTime0SideA.ResizeTo(fNevents+nCEevents); | |
1832 | fVTime0SideC.ResizeTo(fNevents+nCEevents); | |
1833 | ||
7442bceb | 1834 | for (Int_t iEvent=0; iEvent<nCEevents; ++iEvent){ |
78f17711 | 1835 | Double_t evTime = eventTimes.GetMatrixArray()[iEvent]; |
1836 | Double_t evId = eventIds.GetMatrixArray()[iEvent]; | |
1837 | Float_t t0SideA = time0SideA.GetMatrixArray()[iEvent]; | |
1838 | Float_t t0SideC = time0SideC.GetMatrixArray()[iEvent]; | |
1839 | ||
1840 | fVEventTime.GetMatrixArray()[fNevents+iEvent] = evTime; | |
1841 | fVEventNumber.GetMatrixArray()[fNevents+iEvent] = evId; | |
1842 | fVTime0SideA.GetMatrixArray()[fNevents+iEvent] = t0SideA; | |
1843 | fVTime0SideC.GetMatrixArray()[fNevents+iEvent] = t0SideC; | |
1844 | } | |
1845 | } | |
1846 | ||
1847 | if (fProcessNew&&ce->fProcessNew) { | |
1848 | if (fArrHnDrift.GetEntries() != ce->fArrHnDrift.GetEntries() ){ | |
1849 | AliError("Number of bursts in the instances to merge are different. No merging done!"); | |
1850 | } else { | |
1851 | for (Int_t i=0;i<fArrHnDrift.GetEntries();++i){ | |
1852 | THnSparseI *h=(THnSparseI*)fArrHnDrift.UncheckedAt(i); | |
1853 | THnSparseI *hce=(THnSparseI*)ce->fArrHnDrift.UncheckedAt(i); | |
1854 | if (h && hce) h->Add(hce); | |
1855 | else AliError(Form("AliTPCCalibCE::Merge - one THnSparse missing in burst %d",i)); | |
7442bceb | 1856 | } |
78f17711 | 1857 | //TODO: What to do with fTimeBursts??? |
7fb602b1 | 1858 | } |
7442bceb | 1859 | } |
1860 | ||
7442bceb | 1861 | fNevents+=nCEevents; //increase event counter |
1862 | } | |
7fb602b1 | 1863 | |
7442bceb | 1864 | //_____________________________________________________________________ |
1865 | Long64_t AliTPCCalibCE::Merge(TCollection * const list) | |
1866 | { | |
1867 | // | |
1868 | // Merge all objects of this type in list | |
1869 | // | |
7fb602b1 | 1870 | |
7442bceb | 1871 | Long64_t nmerged=1; |
7fb602b1 | 1872 | |
7442bceb | 1873 | TIter next(list); |
1874 | AliTPCCalibCE *ce=0; | |
1875 | TObject *o=0; | |
7fb602b1 | 1876 | |
7442bceb | 1877 | while ( (o=next()) ){ |
1878 | ce=dynamic_cast<AliTPCCalibCE*>(o); | |
1879 | if (ce){ | |
1880 | Merge(ce); | |
1881 | ++nmerged; | |
7fb602b1 | 1882 | } |
7442bceb | 1883 | } |
7fb602b1 | 1884 | |
7442bceb | 1885 | return nmerged; |
7fb602b1 | 1886 | } |
7442bceb | 1887 | |
7fb602b1 | 1888 | //_____________________________________________________________________ |
1889 | TGraph *AliTPCCalibCE::MakeGraphTimeCE(Int_t sector, Int_t xVariable, Int_t fitType, Int_t fitParameter) | |
75d8233f | 1890 | { |
ac940b58 | 1891 | // |
1892 | // Make graph from fit parameters of pol1 fit, pol2 fit, mean arrival time or mean Q for ROC 'sector' | |
880c3382 | 1893 | // or side (-1: A-Side, -2: C-Side) |
ac940b58 | 1894 | // xVariable: 0-event time, 1-event id, 2-internal event counter |
1895 | // fitType: 0-pol1 fit, 1-pol2 fit, 2-mean time, 3-mean Q | |
1896 | // fitParameter: fit parameter ( 0-2 for pol1 ([0]+[1]*x+[2]*y), | |
1897 | // 0-5 for pol2 ([0]+[1]*x+[2]*y+[3]*x*x+[4]*y*y+[5]*x*y), | |
1898 | // not used for mean time and mean Q ) | |
1899 | // for an example see class description at the beginning | |
1900 | // | |
75d8233f | 1901 | |
ac940b58 | 1902 | TVectorD *xVar = 0x0; |
1903 | TObjArray *aType = 0x0; | |
1904 | Int_t npoints=0; | |
75d8233f | 1905 | |
96bf9029 | 1906 | // sanity checks |
1907 | if ( (sector<-2) || (sector>71) ) return 0x0; //sector outside valid range | |
1908 | if ( (xVariable<0) || (xVariable>2) ) return 0x0; //invalid x-variable | |
1909 | if ( (fitType<0) || (fitType>3) ) return 0x0; //invalid fit type | |
1910 | if ( sector>=0 && fitType==2 && !GetTMeanEvents(sector) ) return 0x0; //no mean time information available | |
1911 | if ( sector>=0 && fitType==3 && !GetQMeanEvents(sector) ) return 0x0; //no mean charge information available | |
1912 | if ( sector<0 && fitType!=2) return 0x0; //for side wise information only mean time is available | |
880c3382 | 1913 | |
1914 | if (sector>=0){ | |
1915 | if ( fitType==0 ){ | |
1916 | if ( (fitParameter<0) || (fitParameter>2) ) return 0x0; | |
1917 | aType = &fParamArrayEventPol1; | |
1918 | if ( aType->At(sector)==0x0 ) return 0x0; | |
1919 | } | |
1920 | else if ( fitType==1 ){ | |
1921 | if ( (fitParameter<0) || (fitParameter>5) ) return 0x0; | |
1922 | aType = &fParamArrayEventPol2; | |
1923 | if ( aType->At(sector)==0x0 ) return 0x0; | |
1924 | } | |
75d8233f | 1925 | |
880c3382 | 1926 | } |
ac940b58 | 1927 | if ( xVariable == 0 ) xVar = &fVEventTime; |
1928 | if ( xVariable == 1 ) xVar = &fVEventNumber; | |
1929 | if ( xVariable == 2 ) { | |
1930 | xVar = new TVectorD(fNevents); | |
1931 | for ( Int_t i=0;i<fNevents; ++i) (*xVar)[i]=i; | |
1932 | } | |
880c3382 | 1933 | |
a3b590cf | 1934 | Double_t *x = new Double_t[fNevents]; |
1935 | Double_t *y = new Double_t[fNevents]; | |
1936 | ||
ac940b58 | 1937 | for (Int_t ievent =0; ievent<fNevents; ++ievent){ |
1938 | if ( fitType<2 ){ | |
1939 | TObjArray *events = (TObjArray*)(aType->At(sector)); | |
1940 | if ( events->GetSize()<=ievent ) break; | |
1941 | TVectorD *v = (TVectorD*)(events->At(ievent)); | |
1942 | if ( (v!=0x0) && ((*xVar)[ievent]>0) ) { x[npoints]=(*xVar)[ievent]; y[npoints]=(*v)[fitParameter]; npoints++;} | |
1943 | } else if (fitType == 2) { | |
1944 | Double_t xValue=(*xVar)[ievent]; | |
880c3382 | 1945 | Double_t yValue=0; |
1946 | if (sector>=0) yValue = (*GetTMeanEvents(sector))[ievent]; | |
1947 | else if (sector==-1) yValue=fVTime0SideA(ievent); | |
1948 | else if (sector==-2) yValue=fVTime0SideC(ievent); | |
ac940b58 | 1949 | if ( yValue>0 && xValue>0 ) { x[npoints]=xValue; y[npoints]=yValue;npoints++;} |
1950 | }else if (fitType == 3) { | |
1951 | Double_t xValue=(*xVar)[ievent]; | |
1952 | Double_t yValue=(*GetQMeanEvents(sector))[ievent]; | |
1953 | if ( yValue>0 && xValue>0 ) { x[npoints]=xValue; y[npoints]=yValue;npoints++;} | |
75d8233f | 1954 | } |
ac940b58 | 1955 | } |
75d8233f | 1956 | |
ac940b58 | 1957 | TGraph *gr = new TGraph(npoints); |
75d8233f | 1958 | //sort xVariable increasing |
ac940b58 | 1959 | Int_t *sortIndex = new Int_t[npoints]; |
a3b590cf | 1960 | TMath::Sort(npoints,x,sortIndex, kFALSE); |
ac940b58 | 1961 | for (Int_t i=0;i<npoints;++i){ |
1962 | gr->SetPoint(i,x[sortIndex[i]],y[sortIndex[i]]); | |
1963 | } | |
75d8233f | 1964 | |
1965 | ||
ac940b58 | 1966 | if ( xVariable == 2 ) delete xVar; |
4ce766eb | 1967 | delete [] x; |
1968 | delete [] y; | |
1969 | delete [] sortIndex; | |
ac940b58 | 1970 | return gr; |
75d8233f | 1971 | } |
1972 | //_____________________________________________________________________ | |
1973 | void AliTPCCalibCE::Analyse() | |
1974 | { | |
880c3382 | 1975 | // |
1976 | // Calculate calibration constants | |
1977 | // | |
78f17711 | 1978 | |
1979 | if (fProcessOld){ | |
1980 | TVectorD paramQ(3); | |
1981 | TVectorD paramT0(3); | |
1982 | TVectorD paramRMS(3); | |
1983 | TMatrixD dummy(3,3); | |
1984 | ||
1985 | Float_t channelCounter=0; | |
1986 | fMeanT0rms=0; | |
1987 | fMeanQrms=0; | |
1988 | fMeanRMSrms=0; | |
1989 | ||
1990 | for (Int_t iSec=0; iSec<72; ++iSec){ | |
1991 | TH2S *hT0 = GetHistoT0(iSec); | |
1992 | if (!hT0 ) continue; | |
1993 | ||
1994 | AliTPCCalROC *rocQ = GetCalRocQ (iSec,kTRUE); | |
1995 | AliTPCCalROC *rocT0 = GetCalRocT0 (iSec,kTRUE); | |
1996 | AliTPCCalROC *rocT0Err = GetCalRocT0Err (iSec,kTRUE); | |
1997 | AliTPCCalROC *rocRMS = GetCalRocRMS(iSec,kTRUE); | |
1998 | AliTPCCalROC *rocOut = GetCalRocOutliers(iSec,kTRUE); | |
1999 | ||
2000 | TH2S *hQ = GetHistoQ(iSec); | |
2001 | TH2S *hRMS = GetHistoRMS(iSec); | |
2002 | ||
2003 | Short_t *arrayhQ = hQ->GetArray(); | |
2004 | Short_t *arrayhT0 = hT0->GetArray(); | |
2005 | Short_t *arrayhRMS = hRMS->GetArray(); | |
2006 | ||
2007 | UInt_t nChannels = fROC->GetNChannels(iSec); | |
2008 | ||
2009 | //debug | |
2010 | Int_t row=0; | |
2011 | Int_t pad=0; | |
2012 | Int_t padc=0; | |
2013 | //! debug | |
2014 | ||
2015 | for (UInt_t iChannel=0; iChannel<nChannels; ++iChannel){ | |
2016 | ||
2017 | ||
2018 | Float_t cogTime0 = -1000; | |
2019 | Float_t cogQ = -1000; | |
2020 | Float_t cogRMS = -1000; | |
2021 | Float_t cogOut = 0; | |
2022 | Float_t rms = 0; | |
2023 | Float_t rmsT0 = 0; | |
2024 | ||
2025 | ||
2026 | Int_t offsetQ = (fNbinsQ+2)*(iChannel+1)+1; | |
2027 | Int_t offsetT0 = (fNbinsT0+2)*(iChannel+1)+1; | |
2028 | Int_t offsetRMS = (fNbinsRMS+2)*(iChannel+1)+1; | |
2029 | ||
2030 | cogQ = AliMathBase::GetCOG(arrayhQ+offsetQ,fNbinsQ,fXminQ,fXmaxQ,&rms); | |
2031 | fMeanQrms+=rms; | |
2032 | cogTime0 = AliMathBase::GetCOG(arrayhT0+offsetT0,fNbinsT0,fXminT0,fXmaxT0,&rmsT0); | |
2033 | fMeanT0rms+=rmsT0; | |
2034 | cogRMS = AliMathBase::GetCOG(arrayhRMS+offsetRMS,fNbinsRMS,fXminRMS,fXmaxRMS,&rms); | |
2035 | fMeanRMSrms+=rms; | |
2036 | channelCounter++; | |
2037 | ||
2038 | /* | |
2039 | //outlier specifications | |
2040 | if ( (cogQ < ??) && (cogTime0 > ??) && (cogTime0<??) && ( cogRMS>??) ){ | |
2041 | cogOut = 1; | |
2042 | cogTime0 = 0; | |
2043 | cogQ = 0; | |
2044 | cogRMS = 0; | |
2045 | } | |
2046 | */ | |
2047 | rocQ->SetValue(iChannel, cogQ*cogQ); | |
2048 | rocT0->SetValue(iChannel, cogTime0); | |
2049 | rocT0Err->SetValue(iChannel, rmsT0); | |
2050 | rocRMS->SetValue(iChannel, cogRMS); | |
2051 | rocOut->SetValue(iChannel, cogOut); | |
2052 | ||
2053 | ||
2054 | //debug | |
2055 | if ( GetStreamLevel() > 0 ){ | |
2056 | TTreeSRedirector *streamer=GetDebugStreamer(); | |
2057 | if ( streamer ) { | |
2058 | ||
2059 | while ( iChannel > (fROC->GetRowIndexes(iSec)[row]+fROC->GetNPads(iSec,row)-1) ) row++; | |
2060 | pad = iChannel-fROC->GetRowIndexes(iSec)[row]; | |
2061 | padc = pad-(fROC->GetNPads(iSec,row)/2); | |
2062 | ||
2063 | (*streamer) << "DataEnd" << | |
2064 | "Sector=" << iSec << | |
2065 | "Pad=" << pad << | |
2066 | "PadC=" << padc << | |
2067 | "Row=" << row << | |
2068 | "PadSec=" << iChannel << | |
2069 | "Q=" << cogQ << | |
2070 | "T0=" << cogTime0 << | |
2071 | "RMS=" << cogRMS << | |
2072 | "\n"; | |
2073 | } | |
2074 | } | |
2075 | //! debug | |
2076 | ||
2077 | } | |
2078 | ||
2079 | } | |
2080 | if ( channelCounter>0 ){ | |
2081 | fMeanT0rms/=channelCounter; | |
2082 | fMeanQrms/=channelCounter; | |
2083 | fMeanRMSrms/=channelCounter; | |
2084 | } | |
2085 | // if ( fDebugStreamer ) fDebugStreamer->GetFile()->Write(); | |
2086 | // delete fDebugStreamer; | |
2087 | // fDebugStreamer = 0x0; | |
2088 | fVEventTime.ResizeTo(fNevents); | |
2089 | fVEventNumber.ResizeTo(fNevents); | |
2090 | fVTime0SideA.ResizeTo(fNevents); | |
2091 | fVTime0SideC.ResizeTo(fNevents); | |
2092 | } | |
2093 | ||
2094 | if (fProcessNew&&fAnalyseNew){ | |
2095 | AnalyseTrack(); | |
2096 | for (Int_t iburst=0; iburst<fArrHnDrift.GetEntries(); ++iburst){ | |
2097 | THnSparseI *h=(THnSparseI*)fArrHnDrift.UncheckedAt(iburst); | |
2098 | h->GetAxis(4)->SetRangeUser(fTimeBursts[iburst]-60*5,fTimeBursts[iburst]+60*5); | |
2099 | } | |
2100 | } | |
2101 | } | |
2102 | ||
2103 | ||
2104 | ||
2105 | ||
2106 | // | |
2107 | // New functions that also use the laser tracks | |
2108 | // | |
2109 | ||
2110 | ||
2111 | ||
2112 | //_____________________________________________________________________ | |
2113 | void AliTPCCalibCE::FindLocalMaxima(TObjArray * const arrObj, Double_t timestamp, Int_t burst) | |
2114 | { | |
2115 | // | |
2116 | //Find the local maximums for the projections to each axis | |
2117 | // | |
880c3382 | 2118 | |
78f17711 | 2119 | //find laser layer positoins |
2120 | fHnDrift->GetAxis(4)->SetRangeUser(timestamp-2*60,timestamp+2*60); | |
2121 | FindLaserLayers(); | |
2122 | THnSparse *hProj=fHnDrift; | |
2123 | Double_t posCE[4]={0.,0.,0.,0.}; | |
2124 | Double_t widthCE[4]={0.,0.,0.,0.}; | |
880c3382 | 2125 | |
78f17711 | 2126 | // if(fPeaks[4]!=0){ |
2127 | // find central electrode position once more, separately for IROC, OROC, A-, C-Side | |
880c3382 | 2128 | |
78f17711 | 2129 | for (Int_t i=0; i<4; ++i){ |
6e6025f4 | 2130 | Int_t ce=(i/2>0)*7+6; |
78f17711 | 2131 | hProj->GetAxis(0)->SetRangeUser(i*18,(i+1)*18-1); |
2132 | TH1 *h=fHnDrift->Projection(3); | |
6e6025f4 | 2133 | h->GetXaxis()->SetRangeUser(fPeaks[ce]-fPeakWidths[ce],fPeaks[ce]+fPeakWidths[ce]); |
78f17711 | 2134 | Int_t nbinMax=h->GetMaximumBin(); |
2135 | Double_t maximum=h->GetMaximum(); | |
2136 | // Double_t maxExpected=fNevents/fArrHnDrift->GetEntries()*556568./5./10.; | |
2137 | // if (nbinMax<700||maximum<maxExpected) continue; | |
2138 | Double_t xbinMax=h->GetBinCenter(nbinMax); | |
6e6025f4 | 2139 | TF1 fgaus("gaus","gaus",xbinMax-5,xbinMax+5); |
78f17711 | 2140 | fgaus.SetParameters(maximum,xbinMax,2); |
2141 | fgaus.SetParLimits(1,xbinMax-5.,xbinMax+5.); | |
2142 | fgaus.SetParLimits(2,0.2,4.); | |
2143 | h->Fit(&fgaus,"RQN"); | |
2144 | // Double_t deltaX=4*fgaus.GetParameter(2); | |
2145 | // xbinMax=fgaus.GetParameter(1); | |
2146 | delete h; | |
2147 | posCE[i]=fgaus.GetParameter(1); | |
2148 | widthCE[i]=4*fgaus.GetParameter(2); | |
2149 | hProj->GetAxis(0)->SetRangeUser(0,72); | |
2150 | } | |
2151 | // } | |
2152 | //Current drift velocity | |
2153 | Float_t vdrift=2.61301900000000000e+06;//fParam->GetDriftV(); | |
2154 | // cout<<"vdrift="<<vdrift<<endl; | |
2155 | ||
2156 | AliDebug(5,Form("Timestamp %f - default drift velocity %f",timestamp,vdrift)); | |
2157 | //loop over all entries in the histogram | |
2158 | Int_t coord[5]; | |
2159 | for(Long64_t ichunk=0;ichunk<hProj->GetNbins();ichunk++){ | |
2160 | //get entry position and content | |
2161 | Double_t adc=hProj->GetBinContent(ichunk,coord); | |
2162 | ||
880c3382 | 2163 | |
78f17711 | 2164 | Int_t sector = coord[0]-1; |
2165 | Int_t row = coord[1]-1; | |
2166 | Int_t pad = coord[2]-1; | |
2167 | Int_t timeBin= coord[3]-1; | |
2168 | Double_t time = fHnDrift->GetAxis(4)->GetBinCenter(coord[4]); | |
2169 | Int_t side = (sector/18)%2; | |
2170 | // return; | |
2171 | // fPeaks[4]=(UInt_t)posCE[sector/18]; | |
2172 | // fPeakWidths[4]=(UInt_t)widthCE[sector/18]; | |
880c3382 | 2173 | |
78f17711 | 2174 | //cuts |
2175 | if (time<timestamp-120||time>timestamp+120) continue; //window of +- 2min | |
2176 | if (adc < 5 ) continue; | |
2177 | if (IsEdgePad(sector,row,pad)) continue; | |
2178 | // if (!IsPeakInRange(timeBin)) continue; | |
2179 | // if (isCE&&((row%2)||(row%2)||(sector%2))) continue; | |
2180 | // if (isCE&&(sector!=0)) continue; | |
880c3382 | 2181 | |
78f17711 | 2182 | Int_t padmin=-2, padmax=2; |
2183 | Int_t timemin=-2, timemax=2; | |
2184 | Int_t minsumperpad=2; | |
2185 | //CE or laser tracks | |
2186 | Bool_t isCE=kFALSE; | |
2187 | if (TMath::Abs((Short_t)timeBin-(Short_t)posCE[sector/18])<(Short_t)widthCE[sector/18]) { | |
2188 | isCE=kTRUE; | |
2189 | padmin=0; | |
2190 | padmax=0; | |
2191 | timemin=-3; | |
2192 | timemax=7; | |
2193 | } | |
880c3382 | 2194 | |
78f17711 | 2195 | // |
2196 | // Find local maximum and cogs | |
2197 | // | |
2198 | Bool_t isMaximum=kTRUE; | |
2199 | Float_t totalmass=0, tbcm=0, padcm=0, rmstb=0, rmspad=0; | |
2200 | Double_t cogY=0, rmsY=0; | |
2201 | Int_t npart=0; | |
880c3382 | 2202 | |
78f17711 | 2203 | // for position calculation use |
2204 | for(Int_t ipad=padmin;ipad<=padmax;++ipad){ | |
2205 | Float_t lxyz[3]; | |
2206 | fROC->GetPositionLocal(sector,row,pad+ipad,lxyz); | |
2207 | ||
2208 | for(Int_t itime=timemin;itime<=timemax;++itime){ | |
2209 | ||
2210 | Int_t a[5]={coord[0],coord[1],coord[2]+ipad,coord[3]+itime,coord[4]}; | |
2211 | Double_t val=hProj->GetBinContent(a); | |
2212 | totalmass+=val; | |
2213 | ||
2214 | tbcm +=(timeBin+itime)*val; | |
2215 | padcm+=(pad+ipad)*val; | |
2216 | cogY +=lxyz[1]*val; | |
2217 | ||
2218 | rmstb +=(timeBin+itime)*(timeBin+itime)*val; | |
2219 | rmspad+=(pad+ipad)*(pad+ipad)*val; | |
2220 | rmsY +=lxyz[1]*lxyz[1]*val; | |
2221 | ||
2222 | if (val>0) ++npart; | |
2223 | if (val>adc) { | |
2224 | isMaximum=kFALSE; | |
2225 | break; | |
2226 | } | |
2227 | } | |
2228 | if (!isMaximum) break; | |
2229 | } | |
2230 | ||
2231 | if (!isMaximum||!npart) continue; | |
2232 | if (totalmass<npart*minsumperpad) continue; | |
2233 | if (!isCE&&rmspad<.1) continue; //most probably noise, since signal only in one pad, | |
2234 | //for CE we want only one pad by construction | |
880c3382 | 2235 | |
78f17711 | 2236 | tbcm/=totalmass; |
2237 | padcm/=totalmass; | |
2238 | cogY/=totalmass; | |
2239 | ||
2240 | rmstb/=totalmass; | |
2241 | rmspad/=totalmass; | |
2242 | rmsY/=totalmass; | |
2243 | ||
2244 | rmstb=TMath::Sqrt(TMath::Abs(tbcm*tbcm-rmstb)); | |
2245 | rmspad=TMath::Sqrt(TMath::Abs(padcm*padcm-rmspad)); | |
2246 | rmsY=TMath::Sqrt(TMath::Abs(cogY*cogY-rmsY)); | |
2247 | ||
2248 | Int_t cog=TMath::Nint(padcm); | |
2249 | ||
2250 | // timebin --> z position | |
2251 | Float_t zlength=fParam->GetZLength(side); | |
2252 | // Float_t timePos=tbcm+(1000-fPeaks[4]) | |
2253 | // drift velocity is in m/s we would like to have cm/100ns, so 100cm/(10^7*100ns) | |
2254 | Double_t gz=(zlength-(tbcm*vdrift*1.e-7))*TMath::Power(-1,side); | |
2255 | ||
2256 | // local to global transformation--> x and y positions | |
2257 | Float_t padlxyz[3]; | |
2258 | fROC->GetPositionLocal(sector,row,pad,padlxyz); | |
2259 | ||
2260 | Double_t gxyz[3]={padlxyz[0],cogY,gz}; | |
2261 | Double_t lxyz[3]={padlxyz[0],cogY,gz}; | |
2262 | Double_t igxyz[3]={0,0,0}; | |
2263 | AliTPCTransform t1; | |
2264 | t1.RotatedGlobal2Global(sector,gxyz); | |
2265 | ||
2266 | Double_t mindist=0; | |
2267 | Int_t trackID=-1; | |
2268 | Int_t trackID2=-1; | |
2269 | ||
2270 | //find track id and index of the position in the track (row) | |
2271 | Int_t index=0; | |
2272 | if (!isCE){ | |
2273 | index=row+(sector>35)*fROC->GetNRows(0); | |
2274 | trackID=FindLaserTrackID(sector,index,gxyz,mindist,lxyz,trackID2); | |
2275 | } else { | |
2276 | trackID=336+((sector/18)%2); | |
2277 | index= fROC->GetRowIndexes(sector)[row]+pad; // global pad position in sector | |
2278 | if (sector<36) { | |
2279 | index+=(sector%18)*fROC->GetNChannels(sector); | |
2280 | } else { | |
2281 | index+=18*fROC->GetNChannels(0); | |
2282 | index+=(sector%18)*fROC->GetNChannels(sector); | |
2283 | } | |
2284 | //TODO: find out about the multiple peaks in the CE | |
2285 | // mindist=TMath::Abs(fPeaks[4]-tbcm); | |
2286 | mindist=1.; | |
2287 | } | |
2288 | ||
2289 | // fill track vectors | |
2290 | if (trackID>0){ | |
2291 | AliTPCLaserTrack *ltr=(AliTPCLaserTrack*)arrObj->UncheckedAt(trackID); | |
2292 | Double_t oldMinDist=ltr->fVecPhi->GetMatrixArray()[index]; | |
2293 | ||
880c3382 | 2294 | |
78f17711 | 2295 | // travel time effect of light includes |
880c3382 | 2296 | |
78f17711 | 2297 | Double_t raylength=ltr->GetRayLength(); |
2298 | Double_t globmir[3]={ltr->Xv(),ltr->Yv(),ltr->Zv()}; | |
2299 | ltr->GetXYZ(globmir); | |
2300 | if(trackID<336){ | |
2301 | if(side==0){ | |
2302 | gxyz[2]=gxyz[2]-(TMath::Sqrt((gxyz[0]-globmir[0])*(gxyz[0]-globmir[0]) | |
2303 | +(gxyz[1]-globmir[1])*(gxyz[1]-globmir[1]) | |
a7307087 | 2304 | +(gxyz[2]-globmir[2])*(gxyz[2]-globmir[2])+raylength))*vdrift*TMath::Power(10.,-6.)/30000; |
78f17711 | 2305 | } |
2306 | else { | |
2307 | gxyz[2]=gxyz[2]-(TMath::Sqrt((gxyz[0]-globmir[0])*(gxyz[0]-globmir[0]) | |
2308 | +(gxyz[1]-globmir[1])*(gxyz[1]-globmir[1]) | |
a7307087 | 2309 | +(gxyz[2]-globmir[2])*(gxyz[2]-globmir[2])+raylength))*vdrift*TMath::Power(10.,-6.)/30000; |
78f17711 | 2310 | } |
2311 | } | |
880c3382 | 2312 | |
78f17711 | 2313 | if (TMath::Abs(oldMinDist)<1.e-20||oldMinDist>mindist){ |
2314 | ltr->fVecSec->GetMatrixArray()[index]=sector; | |
2315 | ltr->fVecP2->GetMatrixArray()[index]=0; | |
2316 | ltr->fVecPhi->GetMatrixArray()[index]=mindist; | |
2317 | ltr->fVecGX->GetMatrixArray()[index]=gxyz[0]; | |
2318 | ltr->fVecGY->GetMatrixArray()[index]=gxyz[1]; | |
2319 | ltr->fVecGZ->GetMatrixArray()[index]=gxyz[2]; | |
2320 | ltr->fVecLX->GetMatrixArray()[index]=lxyz[0]; | |
2321 | ltr->fVecLY->GetMatrixArray()[index]=lxyz[1]; | |
2322 | ltr->fVecLZ->GetMatrixArray()[index]=lxyz[2]; | |
2323 | // ltr->SetUniqueID((UInt_t)(mindist*10000)); //distance in um | |
2324 | } | |
2325 | TObjArray *arr=AliTPCLaserTrack::GetTracks(); | |
2326 | ltr=(AliTPCLaserTrack*)arr->UncheckedAt(trackID); | |
2327 | igxyz[0]=ltr->fVecGX->GetMatrixArray()[row]; | |
2328 | igxyz[1]=ltr->fVecGY->GetMatrixArray()[row]; | |
2329 | igxyz[2]=ltr->fVecGZ->GetMatrixArray()[row]; | |
2330 | } | |
2331 | ||
2332 | ||
2333 | if (fStreamLevel>4){ | |
2334 | (*GetDebugStreamer()) << "clusters" << | |
2335 | "run=" << fRunNumber << | |
2336 | "timestamp=" << timestamp << | |
2337 | "burst=" << burst << | |
2338 | "side=" << side << | |
2339 | "sec=" << sector << | |
2340 | "row=" << row << | |
2341 | "pad=" << pad << | |
2342 | "padCog=" << cog << | |
2343 | "timebin=" << timeBin << | |
2344 | "cogCE=" << posCE[sector/18] << | |
2345 | "withCE=" << widthCE[sector/18] << | |
2346 | "index=" << index << | |
2347 | ||
2348 | "padcm=" << padcm << | |
2349 | "rmspad=" << rmspad << | |
2350 | ||
2351 | "cogtb=" << tbcm << | |
2352 | "rmstb=" << rmstb << | |
2353 | ||
2354 | "npad=" << npart << | |
2355 | ||
2356 | "lx=" << padlxyz[0]<< | |
2357 | "ly=" << cogY << | |
2358 | "lypad=" << padlxyz[1]<< | |
2359 | "rmsY=" << rmsY << | |
2360 | ||
2361 | "gx=" << gxyz[0] << | |
2362 | "gy=" << gxyz[1] << | |
2363 | "gz=" << gxyz[2] << | |
2364 | ||
2365 | "igx=" << igxyz[0] << | |
2366 | "igy=" << igxyz[1] << | |
2367 | "igz=" << igxyz[2] << | |
2368 | ||
2369 | "mind=" << mindist << | |
2370 | "max=" << adc << | |
2371 | "trackid=" << trackID << | |
2372 | "trackid2=" << trackID2 << | |
2373 | "npart=" << npart << | |
2374 | "\n"; | |
2375 | } // end stream levelmgz.fElements | |
2376 | ||
2377 | } | |
2378 | ||
2379 | } | |
2380 | ||
2381 | //_____________________________________________________________________ | |
2382 | void AliTPCCalibCE::AnalyseTrack() | |
2383 | { | |
2384 | // | |
2385 | // Analyse the tracks | |
2386 | // | |
2387 | ||
2388 | ||
2389 | AliTPCLaserTrack::LoadTracks(); | |
2390 | // AliTPCParam *param=0x0; | |
2391 | // //cdb run number | |
2392 | // AliCDBManager *man=AliCDBManager::Instance(); | |
2393 | // if (man->GetDefaultStorage()){ | |
2394 | // AliCDBEntry *entry=man->Get("TPC/Calib/Parameters",fRunNumber); | |
2395 | // if (entry){ | |
2396 | // entry->SetOwner(kTRUE); | |
2397 | // param = (AliTPCParam*)(entry->GetObject()->Clone()); | |
2398 | // } | |
2399 | // } | |
2400 | // if (param){ | |
2401 | // if (fParam) delete fParam; | |
2402 | // fParam=param; | |
2403 | // } else { | |
2404 | // AliError("Could not get updated AliTPCParam from OCDB!!!"); | |
2405 | // } | |
2406 | ||
2407 | //Measured and ideal laser tracks | |
2408 | TObjArray* arrMeasured = SetupMeasured(); | |
2409 | TObjArray* arrIdeal = AliTPCLaserTrack::GetTracks(); | |
2410 | AddCEtoIdeal(arrIdeal); | |
2411 | ||
2412 | //find bursts and loop over them | |
2413 | for (Int_t iburst=0; iburst<fArrHnDrift.GetEntries();++iburst){ | |
2414 | Double_t timestamp=fTimeBursts[iburst]; | |
2415 | AliDebug(5,Form("Burst: %d (%f)",iburst,timestamp)); | |
2416 | fHnDrift=(THnSparseI*)fArrHnDrift.UncheckedAt(iburst); | |
2417 | if (!fHnDrift) continue; | |
2418 | UInt_t entries=(UInt_t)fHnDrift->GetEntries(); | |
2419 | if (fBinsLastAna[iburst]>=entries) continue; //already analysed!!! | |
2420 | fBinsLastAna[iburst]=entries; | |
2421 | ||
2422 | for (Int_t iDim=0; iDim<fHnDrift->GetNdimensions(); ++iDim) fHnDrift->GetAxis(iDim)->SetRange(0,0); | |
2423 | // if (iburst==0) FindLaserLayers(); | |
2424 | ||
2425 | //reset laser tracks | |
2426 | ResetMeasured(arrMeasured); | |
2427 | ||
2428 | //find clusters and associate to the tracks | |
2429 | FindLocalMaxima(arrMeasured, timestamp, iburst); | |
2430 | ||
2431 | //calculate drift velocity | |
2432 | CalculateDV(arrIdeal,arrMeasured,iburst); | |
2433 | ||
2434 | //Dump information to file if requested | |
2435 | if (fStreamLevel>2){ | |
6e6025f4 | 2436 | //printf("make tree\n"); |
78f17711 | 2437 | //laser track information |
880c3382 | 2438 | |
78f17711 | 2439 | for (Int_t itrack=0; itrack<338; ++itrack){ |
2440 | TObject *iltr=arrIdeal->UncheckedAt(itrack); | |
2441 | TObject *mltr=arrMeasured->UncheckedAt(itrack); | |
2442 | (*GetDebugStreamer()) << "tracks" << | |
2443 | "run=" << fRunNumber << | |
2444 | "time=" << timestamp << | |
2445 | "burst="<< iburst << | |
2446 | "iltr.=" << iltr << | |
2447 | "mltr.=" << mltr << | |
2448 | "\n"; | |
2449 | } | |
2450 | } | |
2451 | } | |
2452 | if (fStreamLevel>0) GetDebugStreamer()->GetFile()->Write(); | |
2453 | } | |
2454 | ||
2455 | //_____________________________________________________________________ | |
2456 | Int_t AliTPCCalibCE::FindLaserTrackID(Int_t sector,Int_t row, const Double_t *peakpos,Double_t &mindist, | |
2457 | const Double_t *peakposloc, Int_t &itrackMin2) | |
2458 | { | |
2459 | // | |
2460 | // Find the tracks, which are closest to the ideal tracks, from clusters closest to the ideal tracks | |
2461 | // | |
2462 | ||
2463 | ||
2464 | TObjArray *arr=AliTPCLaserTrack::GetTracks(); | |
2465 | TVector3 vP(peakpos[0],peakpos[1],peakpos[2]); | |
2466 | TVector3 vDir; | |
2467 | TVector3 vSt; | |
2468 | ||
2469 | Int_t firstbeam=0; | |
2470 | Int_t lastbeam=336/2; | |
2471 | if ( (sector/18)%2 ) { | |
2472 | firstbeam=336/2; | |
2473 | lastbeam=336; | |
2474 | } | |
2475 | ||
2476 | mindist=1000000; | |
2477 | Int_t itrackMin=-1; | |
2478 | for (Int_t itrack=firstbeam; itrack<lastbeam; ++itrack){ | |
2479 | AliTPCLaserTrack *ltr=(AliTPCLaserTrack*)arr->At(itrack); //get the track | |
2480 | // if (ltr->GetVecSec()->GetMatrixArray()[row]!=sector) continue; | |
2481 | vSt.SetXYZ(ltr->GetX(),ltr->GetY(),ltr->GetZ()); | |
2482 | Double_t deltaZ=ltr->GetZ()-peakpos[2]; | |
2483 | if (TMath::Abs(deltaZ)>40) continue; | |
2484 | vDir.SetMagThetaPhi(1,ltr->Theta(),TMath::ASin(ltr->GetSnp())); | |
2485 | vSt.RotateZ(ltr->GetAlpha()); | |
2486 | vDir.RotateZ(ltr->GetAlpha()); | |
2487 | ||
2488 | Double_t dist=(vDir.Cross(vSt-vP)).Mag()/vDir.Mag(); | |
2489 | ||
2490 | if (dist<mindist){ | |
2491 | mindist=dist; | |
2492 | itrackMin=itrack; | |
2493 | } | |
2494 | ||
2495 | } | |
2496 | itrackMin2=-1; | |
2497 | Float_t mindist2=10; | |
2498 | for (Int_t itrack=firstbeam; itrack<lastbeam; ++itrack){ | |
2499 | AliTPCLaserTrack *ltr=(AliTPCLaserTrack*)arr->At(itrack); //get the track | |
2500 | if ((ltr->fVecSec->GetMatrixArray())[row]!=sector) continue; | |
2501 | ||
2502 | Double_t deltaZ=ltr->GetZ()-peakpos[2]; | |
2503 | if (TMath::Abs(deltaZ)>40) continue; | |
2504 | ||
2505 | Double_t dist=TMath::Abs((ltr->fVecLY->GetMatrixArray())[row]-peakposloc[1]); | |
2506 | if (dist>1) continue; | |
2507 | ||
2508 | if (dist<mindist2){ | |
2509 | mindist2=dist; | |
2510 | itrackMin2=itrack; | |
2511 | } | |
2512 | } | |
2513 | mindist=mindist2; | |
2514 | return itrackMin2; | |
2515 | ||
2516 | } | |
2517 | ||
2518 | //_____________________________________________________________________ | |
2519 | Bool_t AliTPCCalibCE::IsEdgePad(Int_t sector, Int_t row, Int_t pad) const | |
2520 | { | |
2521 | // | |
2522 | // return true if pad is on the edge of a row | |
2523 | // | |
2524 | Int_t edge1 = 0; | |
2525 | if ( pad == edge1 ) return kTRUE; | |
2526 | Int_t edge2 = fROC->GetNPads(sector,row)-1; | |
2527 | if ( pad == edge2 ) return kTRUE; | |
2528 | ||
2529 | return kFALSE; | |
2530 | } | |
2531 | ||
2532 | //_____________________________________________________________________ | |
2533 | TObjArray* AliTPCCalibCE::SetupMeasured() | |
2534 | { | |
2535 | // | |
2536 | // setup array of measured laser tracks and CE | |
2537 | // | |
2538 | ||
2539 | TObjArray *arrIdeal = AliTPCLaserTrack::GetTracks(); | |
2540 | TObjArray *arrMeasured = new TObjArray(338); | |
2541 | arrMeasured->SetOwner(); | |
2542 | for(Int_t itrack=0;itrack<336;itrack++){ | |
2543 | arrMeasured->AddAt(new AliTPCLaserTrack(*((AliTPCLaserTrack*)arrIdeal->At(itrack))),itrack); | |
2544 | } | |
2545 | ||
2546 | //"tracks" for CE | |
2547 | AliTPCLaserTrack *ltrce=new AliTPCLaserTrack; | |
2548 | ltrce->SetId(336); | |
2549 | ltrce->SetSide(0); | |
2550 | ltrce->fVecSec=new TVectorD(557568/2); | |
2551 | ltrce->fVecP2=new TVectorD(557568/2); | |
2552 | ltrce->fVecPhi=new TVectorD(557568/2); | |
2553 | ltrce->fVecGX=new TVectorD(557568/2); | |
2554 | ltrce->fVecGY=new TVectorD(557568/2); | |
2555 | ltrce->fVecGZ=new TVectorD(557568/2); | |
2556 | ltrce->fVecLX=new TVectorD(557568/2); | |
2557 | ltrce->fVecLY=new TVectorD(557568/2); | |
2558 | ltrce->fVecLZ=new TVectorD(557568/2); | |
2559 | ||
2560 | arrMeasured->AddAt(ltrce,336); //CE A-Side | |
2561 | ||
2562 | ltrce=new AliTPCLaserTrack; | |
2563 | ltrce->SetId(337); | |
2564 | ltrce->SetSide(1); | |
2565 | ltrce->fVecSec=new TVectorD(557568/2); | |
2566 | ltrce->fVecP2=new TVectorD(557568/2); | |
2567 | ltrce->fVecPhi=new TVectorD(557568/2); | |
2568 | ltrce->fVecGX=new TVectorD(557568/2); | |
2569 | ltrce->fVecGY=new TVectorD(557568/2); | |
2570 | ltrce->fVecGZ=new TVectorD(557568/2); | |
2571 | ltrce->fVecLX=new TVectorD(557568/2); | |
2572 | ltrce->fVecLY=new TVectorD(557568/2); | |
2573 | ltrce->fVecLZ=new TVectorD(557568/2); | |
2574 | arrMeasured->AddAt(ltrce,337); //CE C-Side | |
2575 | ||
2576 | return arrMeasured; | |
2577 | } | |
2578 | ||
2579 | //_____________________________________________________________________ | |
2580 | void AliTPCCalibCE::ResetMeasured(TObjArray * const arr) | |
2581 | { | |
2582 | // | |
2583 | // reset array of measured laser tracks and CE | |
2584 | // | |
2585 | for(Int_t itrack=0;itrack<338;itrack++){ | |
2586 | AliTPCLaserTrack *ltr=(AliTPCLaserTrack*)arr->UncheckedAt(itrack); | |
2587 | ltr->fVecSec->Zero(); | |
2588 | ltr->fVecP2->Zero(); | |
2589 | ltr->fVecPhi->Zero(); | |
2590 | ltr->fVecGX->Zero(); | |
2591 | ltr->fVecGY->Zero(); | |
2592 | ltr->fVecGZ->Zero(); | |
2593 | ltr->fVecLX->Zero(); | |
2594 | ltr->fVecLY->Zero(); | |
2595 | ltr->fVecLZ->Zero(); | |
2596 | } | |
2597 | } | |
2598 | ||
2599 | //_____________________________________________________________________ | |
2600 | void AliTPCCalibCE::AddCEtoIdeal(TObjArray *arr) | |
2601 | { | |
2602 | // | |
2603 | // Add ideal CE positions to the ideal track data | |
2604 | // | |
2605 | ||
2606 | arr->Expand(338); | |
2607 | //"tracks" for CE | |
2608 | AliTPCLaserTrack *ltrceA=new AliTPCLaserTrack; | |
2609 | ltrceA->SetId(336); | |
2610 | ltrceA->SetSide(0); | |
2611 | ltrceA->fVecSec=new TVectorD(557568/2); | |
2612 | ltrceA->fVecP2=new TVectorD(557568/2); | |
2613 | ltrceA->fVecPhi=new TVectorD(557568/2); | |
2614 | ltrceA->fVecGX=new TVectorD(557568/2); | |
2615 | ltrceA->fVecGY=new TVectorD(557568/2); | |
2616 | ltrceA->fVecGZ=new TVectorD(557568/2); | |
2617 | ltrceA->fVecLX=new TVectorD(557568/2); | |
2618 | ltrceA->fVecLY=new TVectorD(557568/2); | |
2619 | ltrceA->fVecLZ=new TVectorD(557568/2); | |
2620 | arr->AddAt(ltrceA,336); //CE A-Side | |
2621 | ||
2622 | AliTPCLaserTrack *ltrceC=new AliTPCLaserTrack; | |
2623 | ltrceC->SetId(337); | |
2624 | ltrceC->SetSide(1); | |
2625 | ltrceC->fVecSec=new TVectorD(557568/2); | |
2626 | ltrceC->fVecP2=new TVectorD(557568/2); | |
2627 | ltrceC->fVecPhi=new TVectorD(557568/2); | |
2628 | ltrceC->fVecGX=new TVectorD(557568/2); | |
2629 | ltrceC->fVecGY=new TVectorD(557568/2); | |
2630 | ltrceC->fVecGZ=new TVectorD(557568/2); | |
2631 | ltrceC->fVecLX=new TVectorD(557568/2); | |
2632 | ltrceC->fVecLY=new TVectorD(557568/2); | |
2633 | ltrceC->fVecLZ=new TVectorD(557568/2); | |
2634 | arr->AddAt(ltrceC,337); //CE C-Side | |
2635 | ||
2636 | //Calculate ideal positoins | |
2637 | Float_t gxyz[3]; | |
2638 | Float_t lxyz[3]; | |
2639 | Int_t channelSideA=0; | |
2640 | Int_t channelSideC=0; | |
2641 | Int_t channelSide=0; | |
2642 | AliTPCLaserTrack *ltrce=0x0; | |
2643 | ||
2644 | for (Int_t isector=0; isector<72; ++isector){ | |
2645 | Int_t side=((isector/18)%2); | |
2646 | for (UInt_t irow=0;irow<fROC->GetNRows(isector);++irow){ | |
2647 | for (UInt_t ipad=0;ipad<fROC->GetNPads(isector,irow);++ipad){ | |
2648 | fROC->GetPositionGlobal(isector,irow,ipad,gxyz); | |
2649 | fROC->GetPositionLocal(isector,irow,ipad,lxyz); | |
2650 | if (side==0) { | |
2651 | ltrce=ltrceA; | |
2652 | channelSide=channelSideA; | |
2653 | } else { | |
2654 | ltrce=ltrceC; | |
2655 | channelSide=channelSideC; | |
2656 | } | |
2657 | ||
2658 | ltrce->fVecSec->GetMatrixArray()[channelSide]=isector; | |
2659 | ltrce->fVecP2->GetMatrixArray()[channelSide]=0; | |
2660 | ltrce->fVecPhi->GetMatrixArray()[channelSide]=0; | |
2661 | ltrce->fVecGX->GetMatrixArray()[channelSide]=gxyz[0]; | |
2662 | ltrce->fVecGY->GetMatrixArray()[channelSide]=gxyz[1]; | |
2663 | // ltrce->fVecGZ->GetMatrixArray()[channelSide]=-1; | |
2664 | ltrce->fVecLX->GetMatrixArray()[channelSide]=lxyz[0]; | |
2665 | ltrce->fVecLY->GetMatrixArray()[channelSide]=lxyz[1]; | |
2666 | // ltrce->fVecLZ->GetMatrixArray()[channelSide]=-1; | |
2667 | ||
2668 | if (side==0){ | |
2669 | ltrce->fVecGZ->GetMatrixArray()[channelSide]=-0.335; | |
2670 | ltrce->fVecLZ->GetMatrixArray()[channelSide]=-0.335; | |
2671 | ++channelSideA; | |
2672 | } | |
2673 | else { | |
2674 | ltrce->fVecGZ->GetMatrixArray()[channelSide]=0.15; | |
2675 | ltrce->fVecLZ->GetMatrixArray()[channelSide]=0.15; | |
2676 | ++channelSideC; | |
2677 | } | |
2678 | } | |
2679 | } | |
2680 | } | |
2681 | ||
2682 | ||
2683 | } | |
2684 | ||
2685 | //_____________________________________________________________________ | |
2686 | void AliTPCCalibCE::CalculateDV(TObjArray * const arrIdeal, TObjArray * const arrMeasured, Int_t burst) | |
2687 | { | |
2688 | // | |
2689 | // calculate the drift velocity from the reconstructed clusters associated | |
2690 | // to the ideal laser tracks | |
2691 | // use two different fit scenarios: Separate fit for A- and C-Side | |
2692 | // Common fit for A- and C-Side | |
2693 | // | |
2694 | ||
2695 | if (!fArrFitGraphs){ | |
2696 | fArrFitGraphs=new TObjArray; | |
2697 | } | |
2698 | ||
2699 | // static TLinearFitter fdriftA(5,"hyp4"); | |
2700 | // static TLinearFitter fdriftC(5,"hyp4"); | |
2701 | // static TLinearFitter fdriftAC(6,"hyp5"); | |
2702 | Double_t timestamp=fTimeBursts[burst]; | |
2703 | ||
2704 | static TLinearFitter fdriftA(4,"hyp3"); | |
2705 | static TLinearFitter fdriftC(4,"hyp3"); | |
2706 | static TLinearFitter fdriftAC(5,"hyp4"); | |
2707 | TVectorD fitA(7),fitC(7),fitAC(8); //fit values+chi2+npoints | |
2708 | ||
2709 | Float_t chi2A = 10; | |
2710 | Float_t chi2C = 10; | |
2711 | Float_t chi2AC = 10; | |
2712 | Int_t npointsA=0; | |
2713 | Int_t npointsC=0; | |
2714 | Int_t npointsAC=0; | |
2715 | ||
2716 | Double_t minres[3]={20.,1,0.8}; | |
2717 | //---- | |
2718 | for(Int_t i=0;i<3;i++){ | |
2719 | ||
2720 | fdriftA.ClearPoints(); | |
2721 | fdriftC.ClearPoints(); | |
2722 | fdriftAC.ClearPoints(); | |
2723 | ||
2724 | chi2A = 10; | |
2725 | chi2C = 10; | |
2726 | chi2AC = 10; | |
2727 | npointsA=0; | |
2728 | npointsC=0; | |
2729 | npointsAC=0; | |
2730 | ||
2731 | for (Int_t itrack=0; itrack<338; ++itrack){ | |
2732 | AliTPCLaserTrack *iltr=(AliTPCLaserTrack*)arrIdeal->UncheckedAt(itrack); | |
2733 | AliTPCLaserTrack *mltr=(AliTPCLaserTrack*)arrMeasured->UncheckedAt(itrack); | |
2734 | ||
2735 | //-- Exclude the tracks which has the biggest inclanation angle | |
2736 | if ((itrack%7==0||itrack%7==6)&&itrack<336) continue; | |
2737 | Int_t clustercounter=0; | |
2738 | Int_t indexMax=159; | |
880c3382 | 2739 | |
78f17711 | 2740 | //-- exclude the low intensity tracks |
880c3382 | 2741 | |
78f17711 | 2742 | for (Int_t index=0; index<indexMax; ++index){ |
2743 | ||
2744 | Double_t mGx=mltr->fVecGX->GetMatrixArray()[index]; | |
2745 | Double_t mGy=mltr->fVecGY->GetMatrixArray()[index]; | |
2746 | Double_t mGz=mltr->fVecGZ->GetMatrixArray()[index]; | |
2747 | ||
2748 | if (TMath::Abs(mGz)<1e-20 && TMath::Abs(mGy)<1e-20 && TMath::Abs(mGx)<1e-20) clustercounter++; | |
880c3382 | 2749 | } |
78f17711 | 2750 | if (clustercounter>130&&itrack<336) continue; // don't accept tracks with <= 159-130=29 clusters |
2751 | clustercounter=0; | |
2752 | ||
880c3382 | 2753 | |
78f17711 | 2754 | //-- drift length |
2755 | Double_t zlength = (iltr->GetSide()==0)? fParam->GetZLength(36): fParam->GetZLength(71); | |
880c3382 | 2756 | |
78f17711 | 2757 | if (itrack>335) indexMax=557568/2; |
2758 | for (Int_t index=0; index<indexMax; ++index){ | |
2759 | Double_t iGx=iltr->fVecGX->GetMatrixArray()[index]; | |
2760 | Double_t iGy=iltr->fVecGY->GetMatrixArray()[index]; | |
2761 | Double_t iGz=iltr->fVecGZ->GetMatrixArray()[index]; | |
2762 | Double_t iR=TMath::Sqrt(iGx*iGx+iGy*iGy); | |
880c3382 | 2763 | |
78f17711 | 2764 | Double_t mGx=mltr->fVecGX->GetMatrixArray()[index]; |
2765 | Double_t mGy=mltr->fVecGY->GetMatrixArray()[index]; | |
2766 | Double_t mGz=mltr->fVecGZ->GetMatrixArray()[index]; | |
2767 | Double_t mR=TMath::Sqrt(mGx*mGx+mGy*mGy); | |
880c3382 | 2768 | |
78f17711 | 2769 | //cut if no track info available |
2770 | if (iltr->GetBundle()==0) continue; | |
2771 | if (iR<133||mR<133) continue; | |
6e6025f4 | 2772 | if(TMath::Abs(mltr->fVecP2->GetMatrixArray()[index])>minres[i]) continue; |
78f17711 | 2773 | |
2774 | Double_t ldrift = (iltr->GetSide()==0)?zlength-iGz:iGz+zlength; | |
2775 | Double_t mdrift = (iltr->GetSide()==0)?zlength-mGz:mGz+zlength; | |
2776 | ||
2777 | //Double_t xxx[4] = {ldrift,iGy*ldrift/(zlength*250.), 250.-mR, iltr->fVecSec->GetMatrixArray()[index]>35}; | |
2778 | Double_t xxx[3] = {ldrift,iGy*ldrift/(zlength*250.), 250.-mR}; | |
2779 | ||
2780 | if (iltr->GetSide()==0){ | |
2781 | fdriftA.AddPoint(xxx,mdrift,1); | |
2782 | }else{ | |
2783 | fdriftC.AddPoint(xxx,mdrift,1); | |
880c3382 | 2784 | } |
78f17711 | 2785 | // Double_t xxx2[4] = { ldrift,iGy*ldrift/(zlength*250.), 250.-mR, iltr->fVecSec->GetMatrixArray()[index]>35, iltr->GetSide()}; |
2942f542 | 2786 | Double_t xxx2[4] = { ldrift,iGy*ldrift/(zlength*250.), 250.-mR, static_cast<Double_t>(iltr->GetSide())}; |
78f17711 | 2787 | fdriftAC.AddPoint(xxx2,mdrift,1); |
2788 | ||
2789 | }//end index loop | |
2790 | }//end laser track loop | |
2791 | ||
2792 | //perform fit | |
2793 | fdriftA.Eval(); | |
2794 | fdriftC.Eval(); | |
2795 | fdriftAC.Eval(); | |
2796 | ||
2797 | ||
2798 | ||
2799 | //get fit values | |
2800 | fdriftA.GetParameters(fitA); | |
2801 | fdriftC.GetParameters(fitC); | |
2802 | fdriftAC.GetParameters(fitAC); | |
2803 | ||
2804 | //Parameters: 0 linear offset | |
2805 | // 1 mean drift velocity correction factor | |
2806 | // 2 relative global y gradient | |
2807 | // 3 radial deformation | |
2808 | // 4 IROC/OROC offset | |
2809 | ||
2810 | // FindResiduals(arrMeasured,arrIdeal,fitA,fitC); | |
2811 | ||
2812 | for (Int_t itrack=0; itrack<338; ++itrack){ | |
2813 | AliTPCLaserTrack *iltr=(AliTPCLaserTrack*)arrIdeal->UncheckedAt(itrack); | |
2814 | AliTPCLaserTrack *mltr=(AliTPCLaserTrack*)arrMeasured->UncheckedAt(itrack); | |
2815 | ||
2816 | //-- Exclude the tracks which has the biggest inclanation angle | |
2817 | if ((itrack%7==0||itrack%7==6)&&itrack<336) continue; | |
2818 | Int_t clustercounter=0; | |
2819 | Int_t indexMax=159; | |
2820 | ||
2821 | //-- exclude the low intensity tracks | |
2822 | ||
2823 | for (Int_t index=0; index<indexMax; ++index){ | |
2824 | Double_t mGx=mltr->fVecGX->GetMatrixArray()[index]; | |
2825 | Double_t mGy=mltr->fVecGY->GetMatrixArray()[index]; | |
2826 | Double_t mGz=mltr->fVecGZ->GetMatrixArray()[index]; | |
2827 | if (TMath::Abs(mGz)<1e-20 && TMath::Abs(mGy)<1e-20 && TMath::Abs(mGx)<1e-20) clustercounter++; | |
880c3382 | 2828 | } |
78f17711 | 2829 | if (clustercounter>130&&itrack<336) continue; // don't accept tracks with <= 159-130=29 clusters |
2830 | clustercounter=0; | |
2831 | ||
2832 | //-- drift length | |
2833 | Double_t zlength = (iltr->GetSide()==0)? fParam->GetZLength(36): fParam->GetZLength(71); | |
2834 | ||
2835 | if (itrack>335) indexMax=557568/2; | |
2836 | for (Int_t index=0; index<indexMax; ++index){ | |
2837 | Double_t iGx=iltr->fVecGX->GetMatrixArray()[index]; | |
2838 | Double_t iGy=iltr->fVecGY->GetMatrixArray()[index]; | |
2839 | Double_t iGz=iltr->fVecGZ->GetMatrixArray()[index]; | |
2840 | Double_t iR=TMath::Sqrt(iGx*iGx+iGy*iGy); | |
2841 | ||
2842 | Double_t mGx=mltr->fVecGX->GetMatrixArray()[index]; | |
2843 | Double_t mGy=mltr->fVecGY->GetMatrixArray()[index]; | |
2844 | Double_t mGz=mltr->fVecGZ->GetMatrixArray()[index]; | |
2845 | Double_t mR=TMath::Sqrt(mGx*mGx+mGy*mGy); | |
2846 | ||
2847 | //cut if no track info available | |
2848 | if (iR<60||mR<60) continue; | |
2849 | ||
2850 | Double_t ldrift = (iltr->GetSide()==0)?zlength-iGz:iGz+zlength; | |
2851 | Double_t mdrift = (iltr->GetSide()==0)?zlength-mGz:mGz+zlength; | |
2852 | ||
2853 | TVectorD *v=&fitA; | |
2854 | if (iltr->GetSide()==1) v=&fitC; | |
2855 | // Double_t iCorr=(*v)[0]+(*v)[1]*ldrift+(*v)[2]*iGy*ldrift/(zlength*250.)+(*v)[3]*(250.-mR)+(*v)[4]*( iltr->fVecSec->GetMatrixArray()[index]>35); | |
2856 | Double_t iCorr=(*v)[0]+(*v)[1]*ldrift+(*v)[2]*iGy*ldrift/(zlength*250.)+(*v)[3]*(250.-mR); | |
2857 | ||
2858 | mltr->fVecP2->GetMatrixArray()[index]=mdrift-iCorr; | |
2859 | ||
2860 | } | |
2861 | } | |
2862 | ||
2863 | fitA.ResizeTo(7); | |
2864 | fitC.ResizeTo(7); | |
2865 | fitAC.ResizeTo(8); | |
2866 | ||
2867 | //set statistics values | |
2868 | ||
2869 | npointsA= fdriftA.GetNpoints(); | |
2870 | if (npointsA>0) chi2A = fdriftA.GetChisquare()/fdriftA.GetNpoints(); | |
2871 | fitA[5]=npointsA; | |
2872 | fitA[6]=chi2A; | |
2873 | ||
2874 | npointsC= fdriftC.GetNpoints(); | |
2875 | if (npointsC>0) chi2C = fdriftC.GetChisquare()/fdriftC.GetNpoints(); | |
2876 | fitC[5]=npointsC; | |
2877 | fitC[6]=chi2C; | |
2878 | ||
2879 | npointsAC= fdriftAC.GetNpoints(); | |
2880 | if (npointsAC>0) chi2AC = fdriftAC.GetChisquare()/fdriftAC.GetNpoints(); | |
2881 | fitAC[5]=npointsAC; | |
2882 | fitAC[6]=chi2AC; | |
2883 | ||
2884 | if (fStreamLevel>2){ | |
2885 | //laser track information | |
2886 | (*GetDebugStreamer()) << "DriftV" << | |
2887 | "iter=" << i << | |
2888 | "run=" << fRunNumber << | |
2889 | "time=" << timestamp << | |
2890 | "fitA.=" << &fitA << | |
2891 | "fitC.=" << &fitC << | |
2892 | "fitAC.=" << &fitAC << | |
2893 | "\n"; | |
2894 | ||
880c3382 | 2895 | |
ef7f7670 | 2896 | } |
880c3382 | 2897 | |
2898 | } | |
78f17711 | 2899 | //----- |
2900 | ||
2901 | ||
2902 | //Parameters: 0 linear offset (global) | |
2903 | // 1 mean drift velocity correction factor | |
2904 | // 2 relative global y gradient | |
2905 | // 3 radial deformation | |
2906 | // 4 IROC/OROC offset | |
2907 | // 5 linear offset relative A-C | |
2908 | ||
2909 | //get graphs | |
2910 | TGraphErrors *grA[7]; | |
2911 | TGraphErrors *grC[7]; | |
2912 | TGraphErrors *grAC[8]; | |
2913 | TString names("GRAPH_MEAN_DELAY_LASER_ALL_;GRAPH_MEAN_DRIFT_LASER_ALL_;GRAPH_MEAN_GLOBALYGRADIENT_LASER_ALL_;GRAPH_MEAN_RGRADIENT_LASER_ALL_;GRAPH_MEAN_IROCOROCOFFSET_LASER_ALL_;GRAPH_MEAN_NPOINTS_LASER_ALL_;GRAPH_MEAN_CHI2_LASER_ALL_"); | |
2914 | TString namesAC("GRAPH_MEAN_DELAY_LASER_ALL_;GRAPH_MEAN_DRIFT_LASER_ALL_;GRAPH_MEAN_GLOBALYGRADIENT_LASER_ALL_;GRAPH_MEAN_RGRADIENT_LASER_ALL_;GRAPH_MEAN_IROCOROCOFFSET_LASER_ALL_;GRAPH_MEAN_NPOINTS_LASER_ALL_;GRAPH_MEAN_CHI2_LASER_ALL_;GRAPH_MEAN_DELAYC_LASER_ALL_"); | |
2915 | ||
2916 | TObjArray *arrNames=names.Tokenize(";"); | |
2917 | TObjArray *arrNamesAC=namesAC.Tokenize(";"); | |
2918 | ||
2919 | //A-Side graphs | |
2920 | for (Int_t i=0; i<7; ++i){ | |
2921 | TString grName=arrNames->UncheckedAt(i)->GetName(); | |
2922 | grName+="A"; | |
2923 | grA[i]=(TGraphErrors*)fArrFitGraphs->FindObject(grName.Data()); | |
2924 | if (!grA[i]){ | |
2925 | grA[i]=new TGraphErrors; | |
2926 | grA[i]->SetName(grName.Data()); | |
2927 | grA[i]->SetTitle(grName.ReplaceAll("_"," ").Data()); | |
2928 | fArrFitGraphs->Add(grA[i]); | |
2929 | } | |
2930 | // Int_t ipoint=grA[i]->GetN(); | |
2931 | Int_t ipoint=burst; | |
2932 | grA[i]->SetPoint(ipoint,timestamp,fitA(i)); | |
2933 | grA[i]->SetPointError(ipoint,60,.0001); | |
2934 | if (i<4) grA[i]->SetPointError(ipoint,60,fdriftA.GetCovarianceMatrixElement(i,i)); | |
2935 | } | |
2936 | ||
2937 | //C-Side graphs | |
2938 | for (Int_t i=0; i<7; ++i){ | |
2939 | TString grName=arrNames->UncheckedAt(i)->GetName(); | |
2940 | grName+="C"; | |
2941 | grC[i]=(TGraphErrors*)fArrFitGraphs->FindObject(grName.Data()); | |
2942 | if (!grC[i]){ | |
2943 | grC[i]=new TGraphErrors; | |
2944 | grC[i]->SetName(grName.Data()); | |
2945 | grC[i]->SetTitle(grName.ReplaceAll("_"," ").Data()); | |
2946 | fArrFitGraphs->Add(grC[i]); | |
2947 | } | |
2948 | // Int_t ipoint=grC[i]->GetN(); | |
2949 | Int_t ipoint=burst; | |
2950 | grC[i]->SetPoint(ipoint,timestamp,fitC(i)); | |
2951 | grC[i]->SetPointError(ipoint,60,.0001); | |
6e6025f4 | 2952 | if (i<4) grC[i]->SetPointError(ipoint,60,fdriftC.GetCovarianceMatrixElement(i,i)); |
78f17711 | 2953 | } |
2954 | ||
2955 | //AC-Side graphs | |
2956 | for (Int_t i=0; i<8; ++i){ | |
2957 | TString grName=arrNamesAC->UncheckedAt(i)->GetName(); | |
2958 | grName+="AC"; | |
2959 | grAC[i]=(TGraphErrors*)fArrFitGraphs->FindObject(grName.Data()); | |
2960 | if (!grAC[i]){ | |
2961 | grAC[i]=new TGraphErrors; | |
2962 | grAC[i]->SetName(grName.Data()); | |
2963 | grAC[i]->SetTitle(grName.ReplaceAll("_"," ").Data()); | |
2964 | fArrFitGraphs->Add(grAC[i]); | |
2965 | } | |
2966 | // Int_t ipoint=grAC[i]->GetN(); | |
2967 | Int_t ipoint=burst; | |
2968 | grAC[i]->SetPoint(ipoint,timestamp,fitAC(i)); | |
2969 | grAC[i]->SetPointError(ipoint,60,.0001); | |
6e6025f4 | 2970 | if (i<5) grAC[i]->SetPointError(ipoint,60,fdriftAC.GetCovarianceMatrixElement(i,i)); |
78f17711 | 2971 | } |
2972 | ||
2973 | if (fDebugLevel>10){ | |
2974 | printf("A side fit parameters:\n"); | |
2975 | fitA.Print(); | |
2976 | printf("\nC side fit parameters:\n"); | |
2977 | fitC.Print(); | |
2978 | printf("\nAC side fit parameters:\n"); | |
2979 | fitAC.Print(); | |
2980 | } | |
2981 | delete arrNames; | |
2982 | delete arrNamesAC; | |
2983 | } | |
2984 | ||
2985 | //_____________________________________________________________________ | |
2986 | Double_t AliTPCCalibCE::SetBurstHnDrift() | |
2987 | { | |
2988 | // | |
2989 | // Create a new THnSparse for the current burst | |
2990 | // return the time of the current burst | |
2991 | // | |
2992 | Int_t i=0; | |
2993 | for(i=0; i<fTimeBursts.GetNrows(); ++i){ | |
2994 | if(fTimeBursts.GetMatrixArray()[i]<1.e-20) break; | |
2995 | if(TMath::Abs(fTimeBursts.GetMatrixArray()[i]-fTimeStamp)<300){ | |
2996 | fHnDrift=(THnSparseI*)fArrHnDrift.UncheckedAt(i); | |
2997 | return fTimeBursts(i); | |
2998 | } | |
2999 | } | |
3000 | ||
3001 | CreateDVhist(); | |
3002 | fArrHnDrift.AddAt(fHnDrift,i); | |
3003 | fTimeBursts.GetMatrixArray()[i]=fTimeStamp; | |
6e6025f4 | 3004 | for (i=0;i<14;++i){ |
3005 | fPeaks[i]=0; | |
3006 | fPeakWidths[i]=0; | |
3007 | } | |
3008 | fEventInBunch=0; | |
78f17711 | 3009 | return fTimeStamp; |
3010 | } | |
3011 | ||
3012 | //_____________________________________________________________________ | |
3013 | void AliTPCCalibCE::DumpToFile(const Char_t *filename, const Char_t *dir, Bool_t /*append*/) | |
3014 | { | |
3015 | // | |
3016 | // Write class to file | |
3017 | // option can be specified in the dir option: | |
3018 | // options: | |
3019 | // name=<objname>: the name of the calibration object in file will be <objname> | |
3020 | // type=<type>: the saving type: | |
3021 | // 0 - write the complte object | |
3022 | // 1 - Store the histogram arrays separately to make the streamed object smaller, Analyse to be called | |
3023 | // 2 - like 2, but in addition delete objects that will most probably not be used for calibration | |
3024 | // 3 - store only calibration output, don't store the reference histograms | |
3025 | // and THnSparse (requires Analyse called before) | |
3026 | // | |
3027 | // NOTE: to read the object back, the ReadFromFile function should be used | |
3028 | // | |
3029 | ||
3030 | TString sDir(dir); | |
3031 | TString objName=GetName(); | |
3032 | Int_t type=0; | |
3033 | ||
3034 | //get options | |
3035 | TObjArray *arr=sDir.Tokenize(","); | |
3036 | TIter next(arr); | |
3037 | TObjString *s; | |
3038 | while ( (s=(TObjString*)next()) ){ | |
3039 | TString optString=s->GetString(); | |
3040 | optString.Remove(TString::kBoth,' '); | |
3041 | if (optString.BeginsWith("name=")){ | |
3042 | objName=optString.ReplaceAll("name=",""); | |
3043 | } | |
3044 | if (optString.BeginsWith("type=")){ | |
3045 | optString.ReplaceAll("type=",""); | |
3046 | type=optString.Atoi(); | |
3047 | } | |
3048 | } | |
09d5920f | 3049 | delete arr; |
78f17711 | 3050 | |
6e6025f4 | 3051 | if ( type==4 ){ |
3052 | // only for the new algorithm | |
3053 | AliTPCCalibCE ce; | |
3054 | ce.fArrFitGraphs=fArrFitGraphs; | |
3055 | ce.fNevents=fNevents; | |
3056 | ce.fTimeBursts.ResizeTo(fTimeBursts.GetNrows()); | |
3057 | ce.fTimeBursts=fTimeBursts; | |
3058 | ce.fProcessNew=kTRUE; | |
3059 | TFile f(filename,"recreate"); | |
3060 | ce.Write(objName.Data()); | |
3061 | fArrHnDrift.Write("arrHnDrift",TObject::kSingleKey); | |
3062 | f.Close(); | |
3063 | ce.fArrFitGraphs=0x0; | |
3064 | return; | |
3065 | } | |
3066 | ||
3067 | ||
78f17711 | 3068 | if (type==1||type==2) { |
3069 | //delete most probably not needed stuff | |
3070 | //This requires Analyse to be called after reading the object from file | |
3071 | fCalRocArrayT0.Delete(); | |
3072 | fCalRocArrayT0Err.Delete(); | |
3073 | fCalRocArrayQ.Delete(); | |
3074 | fCalRocArrayRMS.Delete(); | |
3075 | fCalRocArrayOutliers.Delete(); | |
3076 | } | |
3077 | if (type==2||type==3){ | |
3078 | fParamArrayEventPol1.Delete(); | |
3079 | fParamArrayEventPol2.Delete(); | |
3080 | } | |
3081 | ||
3082 | TObjArray histoQArray(72); | |
3083 | TObjArray histoT0Array(72); | |
3084 | TObjArray histoRMSArray(72); | |
3085 | TObjArray arrHnDrift(fArrHnDrift.GetEntries()); | |
3086 | ||
3087 | //save all large 2D histograms in separte pointers | |
3088 | //to have a smaller memory print when saving the object | |
3089 | if (type==1||type==2||type==3){ | |
3090 | for (Int_t i=0; i<72; ++i){ | |
3091 | histoQArray.AddAt(fHistoQArray.UncheckedAt(i),i); | |
3092 | histoT0Array.AddAt(fHistoT0Array.UncheckedAt(i),i); | |
3093 | histoRMSArray.AddAt(fHistoRMSArray.UncheckedAt(i),i); | |
3094 | } | |
3095 | fHistoQArray.SetOwner(kFALSE); | |
3096 | fHistoT0Array.SetOwner(kFALSE); | |
3097 | fHistoRMSArray.SetOwner(kFALSE); | |
3098 | fHistoQArray.Clear(); | |
3099 | fHistoT0Array.Clear(); | |
3100 | fHistoRMSArray.Clear(); | |
3101 | ||
3102 | for (Int_t i=0;i<fArrHnDrift.GetEntries();++i){ | |
3103 | arrHnDrift.AddAt(fArrHnDrift.UncheckedAt(i),i); | |
3104 | } | |
3105 | fArrHnDrift.SetOwner(kFALSE); | |
3106 | fArrHnDrift.Clear(); | |
3107 | } | |
3108 | ||
3109 | ||
3110 | TDirectory *backup = gDirectory; | |
3111 | ||
3112 | TFile f(filename,"recreate"); | |
6e6025f4 | 3113 | Write(objName.Data()); |
78f17711 | 3114 | if (type==1||type==2) { |
3115 | histoQArray.Write("histoQArray",TObject::kSingleKey); | |
3116 | histoT0Array.Write("histoT0Array",TObject::kSingleKey); | |
3117 | histoRMSArray.Write("histoRMSArray",TObject::kSingleKey); | |
3118 | arrHnDrift.Write("arrHnDrift",TObject::kSingleKey); | |
3119 | } | |
3120 | ||
3121 | f.Save(); | |
3122 | f.Close(); | |
3123 | ||
3124 | //move histograms back to the object | |
3125 | if (type==1||type==2){ | |
3126 | for (Int_t i=0; i<72; ++i){ | |
3127 | fHistoQArray.AddAt(histoQArray.UncheckedAt(i),i); | |
3128 | fHistoT0Array.AddAt(histoT0Array.UncheckedAt(i),i); | |
3129 | fHistoRMSArray.AddAt(histoRMSArray.UncheckedAt(i),i); | |
3130 | } | |
3131 | fHistoQArray.SetOwner(kTRUE); | |
3132 | fHistoT0Array.SetOwner(kTRUE); | |
3133 | fHistoRMSArray.SetOwner(kTRUE); | |
3134 | ||
3135 | for (Int_t i=0;i<arrHnDrift.GetEntries();++i){ | |
3136 | fArrHnDrift.AddAt(arrHnDrift.UncheckedAt(i),i); | |
3137 | } | |
3138 | fArrHnDrift.SetOwner(kTRUE); | |
3139 | } | |
3140 | ||
3141 | if ( backup ) backup->cd(); | |
3142 | } | |
3143 | //_____________________________________________________________________ | |
3144 | AliTPCCalibCE* AliTPCCalibCE::ReadFromFile(const Char_t *filename) | |
3145 | { | |
3146 | // | |
3147 | // Read object from file | |
3148 | // Handle properly if the histogram arrays were stored separately | |
3149 | // call Analyse to make sure to have the calibration relevant information in the object | |
3150 | // | |
3151 | ||
3152 | TFile f(filename); | |
3153 | if (!f.IsOpen() || f.IsZombie() ) return 0x0; | |
3154 | TList *l=f.GetListOfKeys(); | |
3155 | TIter next(l); | |
3156 | TKey *key=0x0; | |
3157 | TObject *o=0x0; | |
3158 | ||
3159 | AliTPCCalibCE *ce=0x0; | |
3160 | TObjArray *histoQArray=0x0; | |
3161 | TObjArray *histoT0Array=0x0; | |
3162 | TObjArray *histoRMSArray=0x0; | |
3163 | TObjArray *arrHnDrift=0x0; | |
3164 | ||
3165 | while ( (key=(TKey*)next()) ){ | |
3166 | o=key->ReadObj(); | |
3167 | if ( o->IsA()==AliTPCCalibCE::Class() ){ | |
3168 | ce=(AliTPCCalibCE*)o; | |
3169 | } else if ( o->IsA()==TObjArray::Class() ){ | |
3170 | TString name=key->GetName(); | |
3171 | if ( name=="histoQArray") histoQArray=(TObjArray*)o; | |
3172 | if ( name=="histoT0Array") histoT0Array=(TObjArray*)o; | |
3173 | if ( name=="histoRMSArray") histoRMSArray=(TObjArray*)o; | |
3174 | if ( name=="arrHnDrift") arrHnDrift=(TObjArray*)o; | |
3175 | } | |
3176 | } | |
3177 | ||
3178 | if (ce){ | |
3179 | //move histograms back to the object | |
3180 | TH1* hist=0x0; | |
3181 | if (histoQArray){ | |
3182 | for (Int_t i=0; i<72; ++i){ | |
3183 | hist=(TH1*)histoQArray->UncheckedAt(i); | |
3184 | if (hist) hist->SetDirectory(0x0); | |
3185 | ce->fHistoQArray.AddAt(hist,i); | |
3186 | } | |
3187 | ce->fHistoQArray.SetOwner(kTRUE); | |
3188 | } | |
3189 | ||
3190 | if (histoT0Array) { | |
3191 | for (Int_t i=0; i<72; ++i){ | |
3192 | hist=(TH1*)histoT0Array->UncheckedAt(i); | |
3193 | if (hist) hist->SetDirectory(0x0); | |
3194 | ce->fHistoT0Array.AddAt(hist,i); | |
3195 | } | |
3196 | ce->fHistoT0Array.SetOwner(kTRUE); | |
3197 | } | |
3198 | ||
3199 | if (histoRMSArray){ | |
3200 | for (Int_t i=0; i<72; ++i){ | |
3201 | hist=(TH1*)histoRMSArray->UncheckedAt(i); | |
3202 | if (hist) hist->SetDirectory(0x0); | |
3203 | ce->fHistoRMSArray.AddAt(hist,i); | |
3204 | } | |
3205 | ce->fHistoRMSArray.SetOwner(kTRUE); | |
3206 | } | |
3207 | ||
3208 | if (arrHnDrift){ | |
3209 | for (Int_t i=0; i<arrHnDrift->GetEntries(); ++i){ | |
3210 | THnSparseI *hSparse=(THnSparseI*)arrHnDrift->UncheckedAt(i); | |
3211 | ce->fArrHnDrift.AddAt(hSparse,i); | |
3212 | } | |
3213 | } | |
3214 | ||
3215 | ce->Analyse(); | |
880c3382 | 3216 | } |
78f17711 | 3217 | f.Close(); |
3218 | ||
3219 | return ce; | |
75d8233f | 3220 | } |