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892226be | 1 | /************************************************************************** |
2 | * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * | |
3 | * * | |
4 | * Author: The ALICE Off-line Project. * | |
5 | * Contributors are mentioned in the code where appropriate. * | |
6 | * * | |
7 | * Permission to use, copy, modify and distribute this software and its * | |
8 | * documentation strictly for non-commercial purposes is hereby granted * | |
9 | * without fee, provided that the above copyright notice appears in all * | |
10 | * copies and that both the copyright notice and this permission notice * | |
11 | * appear in the supporting documentation. The authors make no claims * | |
12 | * about the suitability of this software for any purpose. It is * | |
13 | * provided "as is" without express or implied warranty. * | |
14 | **************************************************************************/ | |
15 | ||
16 | ||
17 | /////////////////////////////////////////////////////////////////////////////// | |
18 | // // | |
19 | // Class providing the calculation of derived quantities (mean,rms,fits,...) // | |
20 | // of calibration entries // | |
21 | /* | |
22 | ||
23 | ||
24 | */ | |
25 | //////////////////////////////////////////////////////////////////////////////// | |
26 | ||
27 | #include <TMath.h> | |
28 | #include <TVectorT.h> | |
29 | #include <TObjArray.h> | |
30 | #include <TGraph.h> | |
7390f655 | 31 | #include <TFile.h> |
32 | #include <TDirectory.h> | |
949d8707 | 33 | #include <TMap.h> |
34 | #include <TGraphErrors.h> | |
a23ba1c3 | 35 | #include <AliCDBStorage.h> |
892226be | 36 | #include <AliDCSSensorArray.h> |
a23ba1c3 | 37 | #include <AliTPCSensorTempArray.h> |
892226be | 38 | #include <AliDCSSensor.h> |
949d8707 | 39 | #include <AliLog.h> |
40 | #include <AliCDBEntry.h> | |
41 | #include <AliCDBManager.h> | |
42 | #include <AliCDBId.h> | |
892226be | 43 | #include "AliTPCcalibDB.h" |
44 | #include "AliTPCCalPad.h" | |
45 | #include "AliTPCCalROC.h" | |
46 | #include "AliTPCROC.h" | |
47 | #include "AliTPCmapper.h" | |
48 | #include "AliTPCParam.h" | |
6e7d7dc4 | 49 | #include "AliTPCCalibRaw.h" |
949d8707 | 50 | #include "AliTPCPreprocessorOnline.h" |
51 | #include "AliTPCdataQA.h" | |
a23ba1c3 | 52 | #include "AliLog.h" |
892226be | 53 | #include "AliTPCcalibDButil.h" |
a23ba1c3 | 54 | #include "AliTPCCalibVdrift.h" |
1fabc823 | 55 | #include "AliMathBase.h" |
892226be | 56 | |
57 | ClassImp(AliTPCcalibDButil) | |
58 | AliTPCcalibDButil::AliTPCcalibDButil() : | |
59 | TObject(), | |
1e722a63 | 60 | fCalibDB(0), |
892226be | 61 | fPadNoise(0x0), |
62 | fPedestals(0x0), | |
63 | fPulserTmean(0x0), | |
64 | fPulserTrms(0x0), | |
65 | fPulserQmean(0x0), | |
66 | fPulserOutlier(new AliTPCCalPad("PulserOutliers","PulserOutliers")), | |
67 | fCETmean(0x0), | |
68 | fCETrms(0x0), | |
69 | fCEQmean(0x0), | |
70 | fALTROMasked(0x0), | |
6e7d7dc4 | 71 | fCalibRaw(0x0), |
949d8707 | 72 | fDataQA(0x0), |
73 | fRefMap(0x0), | |
74 | fCurrentRefMap(0x0), | |
75 | fRefValidity(""), | |
7390f655 | 76 | fRefPadNoise(0x0), |
77 | fRefPedestals(0x0), | |
949d8707 | 78 | fRefPedestalMasked(0x0), |
7390f655 | 79 | fRefPulserTmean(0x0), |
80 | fRefPulserTrms(0x0), | |
81 | fRefPulserQmean(0x0), | |
82 | fRefPulserOutlier(new AliTPCCalPad("RefPulserOutliers","RefPulserOutliers")), | |
949d8707 | 83 | fRefPulserMasked(0x0), |
7390f655 | 84 | fRefCETmean(0x0), |
85 | fRefCETrms(0x0), | |
86 | fRefCEQmean(0x0), | |
949d8707 | 87 | fRefCEMasked(0x0), |
88 | fRefALTROFPED(0x0), | |
89 | fRefALTROZsThr(0x0), | |
90 | fRefALTROAcqStart(0x0), | |
91 | fRefALTROAcqStop(0x0), | |
7390f655 | 92 | fRefALTROMasked(0x0), |
93 | fRefCalibRaw(0x0), | |
949d8707 | 94 | fRefDataQA(0x0), |
892226be | 95 | fGoofieArray(0x0), |
96 | fMapper(new AliTPCmapper(0x0)), | |
97 | fNpulserOutliers(-1), | |
7390f655 | 98 | fIrocTimeOffset(0), |
892226be | 99 | fCETmaxLimitAbs(1.5), |
100 | fPulTmaxLimitAbs(1.5), | |
101 | fPulQmaxLimitAbs(5), | |
a23ba1c3 | 102 | fPulQminLimit(11), |
103 | fRuns(0), // run list with OCDB info | |
104 | fRunsStart(0), // start time for given run | |
105 | fRunsStop(0) // stop time for given run | |
892226be | 106 | { |
107 | // | |
108 | // Default ctor | |
109 | // | |
110 | } | |
111 | //_____________________________________________________________________________________ | |
112 | AliTPCcalibDButil::~AliTPCcalibDButil() | |
113 | { | |
114 | // | |
115 | // dtor | |
116 | // | |
117 | delete fPulserOutlier; | |
7390f655 | 118 | delete fRefPulserOutlier; |
892226be | 119 | delete fMapper; |
7390f655 | 120 | if (fRefPadNoise) delete fRefPadNoise; |
121 | if (fRefPedestals) delete fRefPedestals; | |
949d8707 | 122 | if (fRefPedestalMasked) delete fRefPedestalMasked; |
7390f655 | 123 | if (fRefPulserTmean) delete fRefPulserTmean; |
124 | if (fRefPulserTrms) delete fRefPulserTrms; | |
125 | if (fRefPulserQmean) delete fRefPulserQmean; | |
949d8707 | 126 | if (fRefPulserMasked) delete fRefPulserMasked; |
7390f655 | 127 | if (fRefCETmean) delete fRefCETmean; |
128 | if (fRefCETrms) delete fRefCETrms; | |
129 | if (fRefCEQmean) delete fRefCEQmean; | |
949d8707 | 130 | if (fRefCEMasked) delete fRefCEMasked; |
131 | if (fRefALTROFPED) delete fRefALTROFPED; | |
132 | if (fRefALTROZsThr) delete fRefALTROZsThr; | |
133 | if (fRefALTROAcqStart) delete fRefALTROAcqStart; | |
134 | if (fRefALTROAcqStop) delete fRefALTROAcqStop; | |
7390f655 | 135 | if (fRefALTROMasked) delete fRefALTROMasked; |
136 | if (fRefCalibRaw) delete fRefCalibRaw; | |
949d8707 | 137 | if (fCurrentRefMap) delete fCurrentRefMap; |
892226be | 138 | } |
139 | //_____________________________________________________________________________________ | |
140 | void AliTPCcalibDButil::UpdateFromCalibDB() | |
141 | { | |
142 | // | |
143 | // Update pointers from calibDB | |
144 | // | |
1e722a63 | 145 | if (!fCalibDB) fCalibDB=AliTPCcalibDB::Instance(); |
892226be | 146 | fPadNoise=fCalibDB->GetPadNoise(); |
147 | fPedestals=fCalibDB->GetPedestals(); | |
148 | fPulserTmean=fCalibDB->GetPulserTmean(); | |
149 | fPulserTrms=fCalibDB->GetPulserTrms(); | |
150 | fPulserQmean=fCalibDB->GetPulserQmean(); | |
151 | fCETmean=fCalibDB->GetCETmean(); | |
152 | fCETrms=fCalibDB->GetCETrms(); | |
153 | fCEQmean=fCalibDB->GetCEQmean(); | |
154 | fALTROMasked=fCalibDB->GetALTROMasked(); | |
155 | fGoofieArray=fCalibDB->GetGoofieSensors(fCalibDB->GetRun()); | |
6e7d7dc4 | 156 | fCalibRaw=fCalibDB->GetCalibRaw(); |
949d8707 | 157 | fDataQA=fCalibDB->GetDataQA(); |
892226be | 158 | UpdatePulserOutlierMap(); |
949d8707 | 159 | SetReferenceRun(); |
160 | UpdateRefDataFromOCDB(); | |
892226be | 161 | } |
162 | //_____________________________________________________________________________________ | |
7390f655 | 163 | void AliTPCcalibDButil::ProcessCEdata(const char* fitFormula, TVectorD &fitResultsA, TVectorD &fitResultsC, |
2cb269df | 164 | Int_t &noutliersCE, Double_t & chi2A, Double_t &chi2C, AliTPCCalPad *outCE) |
892226be | 165 | { |
166 | // | |
167 | // Process the CE data for this run | |
168 | // the return TVectorD arrays contian the results of the fit | |
169 | // noutliersCE contains the number of pads marked as outliers, | |
170 | // not including masked and edge pads | |
171 | // | |
172 | ||
173 | //retrieve CE and ALTRO data | |
174 | if (!fCETmean){ | |
175 | TString fitString(fitFormula); | |
176 | fitString.ReplaceAll("++","#"); | |
177 | Int_t ndim=fitString.CountChar('#')+2; | |
178 | fitResultsA.ResizeTo(ndim); | |
179 | fitResultsC.ResizeTo(ndim); | |
180 | fitResultsA.Zero(); | |
181 | fitResultsC.Zero(); | |
182 | noutliersCE=-1; | |
183 | return; | |
184 | } | |
185 | noutliersCE=0; | |
186 | //create outlier map | |
7390f655 | 187 | AliTPCCalPad *out=0; |
188 | if (outCE) out=outCE; | |
189 | else out=new AliTPCCalPad("outCE","outCE"); | |
892226be | 190 | AliTPCCalROC *rocMasked=0x0; |
191 | //loop over all channels | |
192 | for (UInt_t iroc=0;iroc<fCETmean->kNsec;++iroc){ | |
193 | AliTPCCalROC *rocData=fCETmean->GetCalROC(iroc); | |
194 | if (fALTROMasked) rocMasked=fALTROMasked->GetCalROC(iroc); | |
7390f655 | 195 | AliTPCCalROC *rocOut=out->GetCalROC(iroc); |
6e7d7dc4 | 196 | if (!rocData) { |
197 | noutliersCE+=AliTPCROC::Instance()->GetNChannels(iroc); | |
7390f655 | 198 | rocOut->Add(1.); |
6e7d7dc4 | 199 | continue; |
200 | } | |
892226be | 201 | //add time offset to IROCs |
202 | if (iroc<AliTPCROC::Instance()->GetNInnerSector()) | |
203 | rocData->Add(fIrocTimeOffset); | |
204 | //select outliers | |
205 | UInt_t nrows=rocData->GetNrows(); | |
206 | for (UInt_t irow=0;irow<nrows;++irow){ | |
207 | UInt_t npads=rocData->GetNPads(irow); | |
208 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
7390f655 | 209 | rocOut->SetValue(irow,ipad,0); |
892226be | 210 | //exclude masked pads |
211 | if (rocMasked && rocMasked->GetValue(irow,ipad)) { | |
7390f655 | 212 | rocOut->SetValue(irow,ipad,1); |
892226be | 213 | continue; |
214 | } | |
732e90a8 | 215 | //exclude first two rows in IROC and last two rows in OROC |
216 | if (iroc<36){ | |
217 | if (irow<2) rocOut->SetValue(irow,ipad,1); | |
218 | } else { | |
219 | if (irow>nrows-3) rocOut->SetValue(irow,ipad,1); | |
220 | } | |
892226be | 221 | //exclude edge pads |
7390f655 | 222 | if (ipad==0||ipad==npads-1) rocOut->SetValue(irow,ipad,1); |
223 | Float_t valTmean=rocData->GetValue(irow,ipad); | |
892226be | 224 | //exclude values that are exactly 0 |
225 | if (valTmean==0) { | |
7390f655 | 226 | rocOut->SetValue(irow,ipad,1); |
892226be | 227 | ++noutliersCE; |
228 | } | |
229 | // exclude channels with too large variations | |
230 | if (TMath::Abs(valTmean)>fCETmaxLimitAbs) { | |
7390f655 | 231 | rocOut->SetValue(irow,ipad,1); |
892226be | 232 | ++noutliersCE; |
233 | } | |
234 | } | |
235 | } | |
236 | } | |
237 | //perform fit | |
238 | TMatrixD dummy; | |
2cb269df | 239 | Float_t chi2Af,chi2Cf; |
240 | fCETmean->GlobalSidesFit(out,fitFormula,fitResultsA,fitResultsC,dummy,dummy,chi2Af,chi2Cf); | |
241 | chi2A=chi2Af; | |
242 | chi2C=chi2Cf; | |
7390f655 | 243 | if (!outCE) delete out; |
892226be | 244 | } |
245 | //_____________________________________________________________________________________ | |
246 | void AliTPCcalibDButil::ProcessCEgraphs(TVectorD &vecTEntries, TVectorD &vecTMean, TVectorD &vecTRMS, TVectorD &vecTMedian, | |
247 | TVectorD &vecQEntries, TVectorD &vecQMean, TVectorD &vecQRMS, TVectorD &vecQMedian, | |
248 | Float_t &driftTimeA, Float_t &driftTimeC ) | |
249 | { | |
250 | // | |
251 | // Calculate statistical information from the CE graphs for drift time and charge | |
252 | // | |
253 | ||
254 | //reset arrays | |
255 | vecTEntries.ResizeTo(72); | |
256 | vecTMean.ResizeTo(72); | |
257 | vecTRMS.ResizeTo(72); | |
258 | vecTMedian.ResizeTo(72); | |
259 | vecQEntries.ResizeTo(72); | |
260 | vecQMean.ResizeTo(72); | |
261 | vecQRMS.ResizeTo(72); | |
262 | vecQMedian.ResizeTo(72); | |
263 | vecTEntries.Zero(); | |
264 | vecTMean.Zero(); | |
265 | vecTRMS.Zero(); | |
266 | vecTMedian.Zero(); | |
267 | vecQEntries.Zero(); | |
268 | vecQMean.Zero(); | |
269 | vecQRMS.Zero(); | |
270 | vecQMedian.Zero(); | |
271 | driftTimeA=0; | |
272 | driftTimeC=0; | |
273 | TObjArray *arrT=fCalibDB->GetCErocTtime(); | |
274 | TObjArray *arrQ=fCalibDB->GetCErocQtime(); | |
275 | if (arrT){ | |
276 | for (Int_t isec=0;isec<74;++isec){ | |
277 | TGraph *gr=(TGraph*)arrT->At(isec); | |
278 | if (!gr) continue; | |
279 | TVectorD values; | |
280 | Int_t npoints = gr->GetN(); | |
281 | values.ResizeTo(npoints); | |
282 | Int_t nused =0; | |
6e7d7dc4 | 283 | //skip first points, theres always some problems with finding the CE position |
284 | for (Int_t ipoint=4; ipoint<npoints; ipoint++){ | |
285 | if (gr->GetY()[ipoint]>500 && gr->GetY()[ipoint]<1020 ){ | |
892226be | 286 | values[nused]=gr->GetY()[ipoint]; |
287 | nused++; | |
288 | } | |
289 | } | |
290 | // | |
291 | if (isec<72) vecTEntries[isec]= nused; | |
292 | if (nused>1){ | |
293 | if (isec<72){ | |
294 | vecTMedian[isec] = TMath::Median(nused,values.GetMatrixArray()); | |
295 | vecTMean[isec] = TMath::Mean(nused,values.GetMatrixArray()); | |
296 | vecTRMS[isec] = TMath::RMS(nused,values.GetMatrixArray()); | |
297 | } else if (isec==72){ | |
298 | driftTimeA=TMath::Median(nused,values.GetMatrixArray()); | |
299 | } else if (isec==73){ | |
300 | driftTimeC=TMath::Median(nused,values.GetMatrixArray()); | |
301 | } | |
302 | } | |
303 | } | |
304 | } | |
305 | if (arrQ){ | |
6e7d7dc4 | 306 | for (Int_t isec=0;isec<arrQ->GetEntriesFast();++isec){ |
892226be | 307 | TGraph *gr=(TGraph*)arrQ->At(isec); |
308 | if (!gr) continue; | |
309 | TVectorD values; | |
310 | Int_t npoints = gr->GetN(); | |
311 | values.ResizeTo(npoints); | |
312 | Int_t nused =0; | |
313 | for (Int_t ipoint=0; ipoint<npoints; ipoint++){ | |
817766d5 | 314 | if (gr->GetY()[ipoint]>10 && gr->GetY()[ipoint]<500 ){ |
892226be | 315 | values[nused]=gr->GetY()[ipoint]; |
316 | nused++; | |
317 | } | |
318 | } | |
319 | // | |
6e7d7dc4 | 320 | vecQEntries[isec]= nused; |
892226be | 321 | if (nused>1){ |
322 | vecQMedian[isec] = TMath::Median(nused,values.GetMatrixArray()); | |
323 | vecQMean[isec] = TMath::Mean(nused,values.GetMatrixArray()); | |
324 | vecQRMS[isec] = TMath::RMS(nused,values.GetMatrixArray()); | |
325 | } | |
326 | } | |
327 | } | |
328 | } | |
329 | ||
330 | //_____________________________________________________________________________________ | |
331 | void AliTPCcalibDButil::ProcessNoiseData(TVectorD &vNoiseMean, TVectorD &vNoiseMeanSenRegions, | |
332 | TVectorD &vNoiseRMS, TVectorD &vNoiseRMSSenRegions, | |
333 | Int_t &nonMaskedZero) | |
334 | { | |
335 | // | |
336 | // process noise data | |
337 | // vNoiseMean/RMS contains the Mean/RMS noise of the complete TPC [0], IROCs only [1], | |
338 | // OROCs small pads [2] and OROCs large pads [3] | |
339 | // vNoiseMean/RMSsenRegions constains the same information, but only for the sensitive regions (edge pads, corners, IROC spot) | |
340 | // nonMaskedZero contains the number of pads which show zero noise and were not masked. This might indicate an error | |
341 | // | |
342 | ||
343 | //set proper size and reset | |
344 | const UInt_t infoSize=4; | |
345 | vNoiseMean.ResizeTo(infoSize); | |
346 | vNoiseMeanSenRegions.ResizeTo(infoSize); | |
347 | vNoiseRMS.ResizeTo(infoSize); | |
348 | vNoiseRMSSenRegions.ResizeTo(infoSize); | |
349 | vNoiseMean.Zero(); | |
350 | vNoiseMeanSenRegions.Zero(); | |
351 | vNoiseRMS.Zero(); | |
352 | vNoiseRMSSenRegions.Zero(); | |
353 | nonMaskedZero=0; | |
354 | //counters | |
355 | TVectorD c(infoSize); | |
356 | TVectorD cs(infoSize); | |
357 | //tpc parameters | |
358 | AliTPCParam par; | |
359 | par.Update(); | |
360 | //retrieve noise and ALTRO data | |
361 | if (!fPadNoise) return; | |
362 | AliTPCCalROC *rocMasked=0x0; | |
363 | //create IROC, OROC1, OROC2 and sensitive region masks | |
364 | for (UInt_t isec=0;isec<AliTPCCalPad::kNsec;++isec){ | |
365 | AliTPCCalROC *noiseROC=fPadNoise->GetCalROC(isec); | |
366 | if (fALTROMasked) rocMasked=fALTROMasked->GetCalROC(isec); | |
367 | UInt_t nrows=noiseROC->GetNrows(); | |
368 | for (UInt_t irow=0;irow<nrows;++irow){ | |
369 | UInt_t npads=noiseROC->GetNPads(irow); | |
370 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
371 | //don't use masked channels; | |
372 | if (rocMasked && rocMasked->GetValue(irow,ipad)) continue; | |
373 | Float_t noiseVal=noiseROC->GetValue(irow,ipad); | |
374 | //check if noise==0 | |
375 | if (noiseVal==0) { | |
376 | ++nonMaskedZero; | |
377 | continue; | |
378 | } | |
379 | //check for nan | |
380 | if ( !(noiseVal<10000000) ){ | |
381 | printf ("Warning: nan detected in (sec,row,pad - val): %02d,%02d,%03d - %.1f\n",isec,irow,ipad,noiseVal); | |
382 | continue; | |
383 | } | |
384 | Int_t cpad=(Int_t)ipad-(Int_t)npads/2; | |
385 | Int_t masksen=1; // sensitive pards are not masked (0) | |
386 | if (ipad<2||npads-ipad-1<2) masksen=0; //don't mask edge pads (sensitive) | |
387 | if (isec<AliTPCROC::Instance()->GetNInnerSector()){ | |
388 | //IROCs | |
389 | if (irow>19&&irow<46){ | |
390 | if (TMath::Abs(cpad)<7) masksen=0; //IROC spot | |
391 | } | |
392 | Int_t type=1; | |
393 | vNoiseMean[type]+=noiseVal; | |
394 | vNoiseRMS[type]+=noiseVal*noiseVal; | |
395 | ++c[type]; | |
396 | if (!masksen){ | |
397 | vNoiseMeanSenRegions[type]+=noiseVal; | |
398 | vNoiseRMSSenRegions[type]+=noiseVal*noiseVal; | |
399 | ++cs[type]; | |
400 | } | |
401 | } else { | |
402 | //OROCs | |
403 | //define sensive regions | |
404 | if ((nrows-irow-1)<3) masksen=0; //last three rows in OROCs are sensitive | |
405 | if ( irow>75 ){ | |
406 | Int_t padEdge=(Int_t)TMath::Min(ipad,npads-ipad); | |
407 | if (padEdge<((((Int_t)irow-76)/4+1))*2) masksen=0; //OROC outer corners are sensitive | |
408 | } | |
409 | if ((Int_t)irow<par.GetNRowUp1()){ | |
410 | //OROC1 | |
411 | Int_t type=2; | |
412 | vNoiseMean[type]+=noiseVal; | |
413 | vNoiseRMS[type]+=noiseVal*noiseVal; | |
414 | ++c[type]; | |
415 | if (!masksen){ | |
416 | vNoiseMeanSenRegions[type]+=noiseVal; | |
417 | vNoiseRMSSenRegions[type]+=noiseVal*noiseVal; | |
418 | ++cs[type]; | |
419 | } | |
420 | }else{ | |
421 | //OROC2 | |
422 | Int_t type=3; | |
423 | vNoiseMean[type]+=noiseVal; | |
424 | vNoiseRMS[type]+=noiseVal*noiseVal; | |
425 | ++c[type]; | |
426 | if (!masksen){ | |
427 | vNoiseMeanSenRegions[type]+=noiseVal; | |
428 | vNoiseRMSSenRegions[type]+=noiseVal*noiseVal; | |
429 | ++cs[type]; | |
430 | } | |
431 | } | |
432 | } | |
433 | //whole tpc | |
434 | Int_t type=0; | |
435 | vNoiseMean[type]+=noiseVal; | |
436 | vNoiseRMS[type]+=noiseVal*noiseVal; | |
437 | ++c[type]; | |
438 | if (!masksen){ | |
439 | vNoiseMeanSenRegions[type]+=noiseVal; | |
440 | vNoiseRMSSenRegions[type]+=noiseVal*noiseVal; | |
441 | ++cs[type]; | |
442 | } | |
443 | }//end loop pads | |
444 | }//end loop rows | |
445 | }//end loop sectors (rocs) | |
446 | ||
447 | //calculate mean and RMS | |
448 | const Double_t verySmall=0.0000000001; | |
449 | for (UInt_t i=0;i<infoSize;++i){ | |
450 | Double_t mean=0; | |
451 | Double_t rms=0; | |
452 | Double_t meanSen=0; | |
453 | Double_t rmsSen=0; | |
454 | ||
455 | if (c[i]>verySmall){ | |
456 | // printf ("i: %d - m: %.3f, c: %.0f, r: %.3f\n",i,vNoiseMean[i],c[i],vNoiseRMS[i]); | |
457 | mean=vNoiseMean[i]/c[i]; | |
458 | rms=vNoiseRMS[i]; | |
459 | rms=TMath::Sqrt(TMath::Abs(rms/c[i]-mean*mean)); | |
460 | } | |
461 | vNoiseMean[i]=mean; | |
462 | vNoiseRMS[i]=rms; | |
463 | ||
464 | if (cs[i]>verySmall){ | |
465 | meanSen=vNoiseMeanSenRegions[i]/cs[i]; | |
466 | rmsSen=vNoiseRMSSenRegions[i]; | |
467 | rmsSen=TMath::Sqrt(TMath::Abs(rmsSen/cs[i]-meanSen*meanSen)); | |
468 | } | |
469 | vNoiseMeanSenRegions[i]=meanSen; | |
470 | vNoiseRMSSenRegions[i]=rmsSen; | |
471 | } | |
472 | } | |
473 | ||
474 | //_____________________________________________________________________________________ | |
475 | void AliTPCcalibDButil::ProcessPulser(TVectorD &vMeanTime) | |
476 | { | |
477 | // | |
478 | // Process the Pulser information | |
479 | // vMeanTime: pulser mean time position in IROC-A, IROC-C, OROC-A, OROC-C | |
480 | // | |
481 | ||
482 | const UInt_t infoSize=4; | |
483 | //reset counters to error number | |
484 | vMeanTime.ResizeTo(infoSize); | |
485 | vMeanTime.Zero(); | |
486 | //counter | |
487 | TVectorD c(infoSize); | |
488 | //retrieve pulser and ALTRO data | |
489 | if (!fPulserTmean) return; | |
490 | // | |
491 | //get Outliers | |
492 | AliTPCCalROC *rocOut=0x0; | |
493 | for (UInt_t isec=0;isec<AliTPCCalPad::kNsec;++isec){ | |
494 | AliTPCCalROC *tmeanROC=fPulserTmean->GetCalROC(isec); | |
495 | if (!tmeanROC) continue; | |
496 | rocOut=fPulserOutlier->GetCalROC(isec); | |
497 | UInt_t nchannels=tmeanROC->GetNchannels(); | |
498 | for (UInt_t ichannel=0;ichannel<nchannels;++ichannel){ | |
499 | if (rocOut && rocOut->GetValue(ichannel)) continue; | |
500 | Float_t val=tmeanROC->GetValue(ichannel); | |
501 | Int_t type=isec/18; | |
502 | vMeanTime[type]+=val; | |
503 | ++c[type]; | |
504 | } | |
505 | } | |
506 | //calculate mean | |
507 | for (UInt_t itype=0; itype<infoSize; ++itype){ | |
508 | if (c[itype]>0) vMeanTime[itype]/=c[itype]; | |
509 | else vMeanTime[itype]=0; | |
510 | } | |
511 | } | |
512 | //_____________________________________________________________________________________ | |
513 | void AliTPCcalibDButil::ProcessALTROConfig(Int_t &nMasked) | |
514 | { | |
515 | // | |
516 | // Get Values from ALTRO configuration data | |
517 | // | |
518 | nMasked=-1; | |
519 | if (!fALTROMasked) return; | |
520 | nMasked=0; | |
521 | for (Int_t isec=0;isec<fALTROMasked->kNsec; ++isec){ | |
522 | AliTPCCalROC *rocMasked=fALTROMasked->GetCalROC(isec); | |
523 | for (UInt_t ichannel=0; ichannel<rocMasked->GetNchannels();++ichannel){ | |
524 | if (rocMasked->GetValue(ichannel)) ++nMasked; | |
525 | } | |
526 | } | |
527 | } | |
528 | //_____________________________________________________________________________________ | |
529 | void AliTPCcalibDButil::ProcessGoofie(TVectorD & vecEntries, TVectorD & vecMedian, TVectorD &vecMean, TVectorD &vecRMS) | |
530 | { | |
531 | // | |
532 | // Proces Goofie values, return statistical information of the currently set goofieArray | |
533 | // The meaning of the entries are given below | |
534 | /* | |
535 | 1 TPC_ANODE_I_A00_STAT | |
536 | 2 TPC_DVM_CO2 | |
537 | 3 TPC_DVM_DriftVelocity | |
538 | 4 TPC_DVM_FCageHV | |
539 | 5 TPC_DVM_GainFar | |
540 | 6 TPC_DVM_GainNear | |
541 | 7 TPC_DVM_N2 | |
542 | 8 TPC_DVM_NumberOfSparks | |
543 | 9 TPC_DVM_PeakAreaFar | |
544 | 10 TPC_DVM_PeakAreaNear | |
545 | 11 TPC_DVM_PeakPosFar | |
546 | 12 TPC_DVM_PeakPosNear | |
547 | 13 TPC_DVM_PickupHV | |
548 | 14 TPC_DVM_Pressure | |
549 | 15 TPC_DVM_T1_Over_P | |
550 | 16 TPC_DVM_T2_Over_P | |
551 | 17 TPC_DVM_T_Over_P | |
552 | 18 TPC_DVM_TemperatureS1 | |
553 | */ | |
554 | if (!fGoofieArray){ | |
555 | Int_t nsensors=19; | |
556 | vecEntries.ResizeTo(nsensors); | |
557 | vecMedian.ResizeTo(nsensors); | |
558 | vecMean.ResizeTo(nsensors); | |
559 | vecRMS.ResizeTo(nsensors); | |
560 | vecEntries.Zero(); | |
561 | vecMedian.Zero(); | |
562 | vecMean.Zero(); | |
563 | vecRMS.Zero(); | |
564 | return; | |
565 | } | |
566 | Double_t kEpsilon=0.0000000001; | |
567 | Double_t kBig=100000000000.; | |
568 | Int_t nsensors = fGoofieArray->NumSensors(); | |
569 | vecEntries.ResizeTo(nsensors); | |
570 | vecMedian.ResizeTo(nsensors); | |
571 | vecMean.ResizeTo(nsensors); | |
572 | vecRMS.ResizeTo(nsensors); | |
573 | TVectorF values; | |
574 | for (Int_t isensor=0; isensor<fGoofieArray->NumSensors();isensor++){ | |
575 | AliDCSSensor *gsensor = fGoofieArray->GetSensor(isensor); | |
576 | if (gsensor && gsensor->GetGraph()){ | |
577 | Int_t npoints = gsensor->GetGraph()->GetN(); | |
578 | // filter zeroes | |
579 | values.ResizeTo(npoints); | |
580 | Int_t nused =0; | |
581 | for (Int_t ipoint=0; ipoint<npoints; ipoint++){ | |
582 | if (TMath::Abs(gsensor->GetGraph()->GetY()[ipoint])>kEpsilon && | |
583 | TMath::Abs(gsensor->GetGraph()->GetY()[ipoint])<kBig ){ | |
584 | values[nused]=gsensor->GetGraph()->GetY()[ipoint]; | |
585 | nused++; | |
586 | } | |
587 | } | |
588 | // | |
589 | vecEntries[isensor]= nused; | |
590 | if (nused>1){ | |
591 | vecMedian[isensor] = TMath::Median(nused,values.GetMatrixArray()); | |
592 | vecMean[isensor] = TMath::Mean(nused,values.GetMatrixArray()); | |
593 | vecRMS[isensor] = TMath::RMS(nused,values.GetMatrixArray()); | |
594 | } | |
595 | } | |
596 | } | |
597 | } | |
7390f655 | 598 | //_____________________________________________________________________________________ |
599 | void AliTPCcalibDButil::ProcessPedestalVariations(TVectorF &pedestalDeviations) | |
600 | { | |
601 | // | |
602 | // check the variations of the pedestal data to the reference pedestal data | |
603 | // thresholds are 0.5, 1.0, 1.5 and 2 timebins respectively. | |
604 | // | |
605 | const Int_t npar=4; | |
606 | TVectorF vThres(npar); //thresholds | |
607 | Int_t nActive=0; //number of active channels | |
608 | ||
609 | //reset and set thresholds | |
610 | pedestalDeviations.ResizeTo(npar); | |
611 | for (Int_t i=0;i<npar;++i){ | |
612 | pedestalDeviations.GetMatrixArray()[i]=0; | |
613 | vThres.GetMatrixArray()[i]=(i+1)*.5; | |
614 | } | |
615 | //check all needed data is available | |
616 | if (!fRefPedestals || !fPedestals || !fALTROMasked || !fRefALTROMasked) return; | |
617 | //loop over all channels | |
618 | for (UInt_t isec=0;isec<AliTPCCalPad::kNsec;++isec){ | |
619 | AliTPCCalROC *pROC=fPedestals->GetCalROC(isec); | |
620 | AliTPCCalROC *pRefROC=fRefPedestals->GetCalROC(isec); | |
621 | AliTPCCalROC *mROC=fALTROMasked->GetCalROC(isec); | |
622 | AliTPCCalROC *mRefROC=fRefALTROMasked->GetCalROC(isec); | |
623 | UInt_t nrows=mROC->GetNrows(); | |
624 | for (UInt_t irow=0;irow<nrows;++irow){ | |
625 | UInt_t npads=mROC->GetNPads(irow); | |
626 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
627 | //don't use masked channels; | |
628 | if (mROC ->GetValue(irow,ipad)) continue; | |
629 | if (mRefROC->GetValue(irow,ipad)) continue; | |
630 | Float_t deviation=TMath::Abs(pROC->GetValue(irow,ipad)-pRefROC->GetValue(irow,ipad)); | |
631 | for (Int_t i=0;i<npar;++i){ | |
632 | if (deviation>vThres[i]) | |
633 | ++pedestalDeviations.GetMatrixArray()[i]; | |
634 | } | |
635 | ++nActive; | |
636 | }//end ipad | |
637 | }//ind irow | |
638 | }//end isec | |
639 | if (nActive>0){ | |
640 | for (Int_t i=0;i<npar;++i){ | |
641 | pedestalDeviations.GetMatrixArray()[i]/=nActive; | |
642 | } | |
643 | } | |
644 | } | |
645 | //_____________________________________________________________________________________ | |
646 | void AliTPCcalibDButil::ProcessNoiseVariations(TVectorF &noiseDeviations) | |
647 | { | |
648 | // | |
649 | // check the variations of the noise data to the reference noise data | |
650 | // thresholds are 5, 10, 15 and 20 percent respectively. | |
651 | // | |
652 | const Int_t npar=4; | |
653 | TVectorF vThres(npar); //thresholds | |
654 | Int_t nActive=0; //number of active channels | |
655 | ||
656 | //reset and set thresholds | |
657 | noiseDeviations.ResizeTo(npar); | |
658 | for (Int_t i=0;i<npar;++i){ | |
659 | noiseDeviations.GetMatrixArray()[i]=0; | |
660 | vThres.GetMatrixArray()[i]=(i+1)*.05; | |
661 | } | |
662 | //check all needed data is available | |
663 | if (!fRefPadNoise || !fPadNoise || !fALTROMasked || !fRefALTROMasked) return; | |
664 | //loop over all channels | |
665 | for (UInt_t isec=0;isec<AliTPCCalPad::kNsec;++isec){ | |
666 | AliTPCCalROC *nROC=fPadNoise->GetCalROC(isec); | |
667 | AliTPCCalROC *nRefROC=fRefPadNoise->GetCalROC(isec); | |
668 | AliTPCCalROC *mROC=fALTROMasked->GetCalROC(isec); | |
669 | AliTPCCalROC *mRefROC=fRefALTROMasked->GetCalROC(isec); | |
670 | UInt_t nrows=mROC->GetNrows(); | |
671 | for (UInt_t irow=0;irow<nrows;++irow){ | |
672 | UInt_t npads=mROC->GetNPads(irow); | |
673 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
674 | //don't use masked channels; | |
675 | if (mROC ->GetValue(irow,ipad)) continue; | |
676 | if (mRefROC->GetValue(irow,ipad)) continue; | |
677 | Float_t deviation=(nROC->GetValue(irow,ipad)/nRefROC->GetValue(irow,ipad))-1; | |
678 | for (Int_t i=0;i<npar;++i){ | |
679 | if (deviation>vThres[i]) | |
680 | ++noiseDeviations.GetMatrixArray()[i]; | |
681 | } | |
682 | ++nActive; | |
683 | }//end ipad | |
684 | }//ind irow | |
685 | }//end isec | |
686 | if (nActive>0){ | |
687 | for (Int_t i=0;i<npar;++i){ | |
688 | noiseDeviations.GetMatrixArray()[i]/=nActive; | |
689 | } | |
690 | } | |
691 | } | |
692 | //_____________________________________________________________________________________ | |
693 | void AliTPCcalibDButil::ProcessPulserVariations(TVectorF &pulserQdeviations, Float_t &varQMean, | |
694 | Int_t &npadsOutOneTB, Int_t &npadsOffAdd) | |
695 | { | |
696 | // | |
697 | // check the variations of the pulserQmean data to the reference pulserQmean data: pulserQdeviations | |
698 | // thresholds are .5, 1, 5 and 10 percent respectively. | |
699 | // | |
700 | // | |
701 | const Int_t npar=4; | |
702 | TVectorF vThres(npar); //thresholds | |
703 | Int_t nActive=0; //number of active channels | |
704 | ||
705 | //reset and set thresholds | |
706 | pulserQdeviations.ResizeTo(npar); | |
707 | for (Int_t i=0;i<npar;++i){ | |
708 | pulserQdeviations.GetMatrixArray()[i]=0; | |
709 | } | |
710 | npadsOutOneTB=0; | |
711 | npadsOffAdd=0; | |
712 | varQMean=0; | |
713 | vThres.GetMatrixArray()[0]=.005; | |
714 | vThres.GetMatrixArray()[1]=.01; | |
715 | vThres.GetMatrixArray()[2]=.05; | |
716 | vThres.GetMatrixArray()[3]=.1; | |
717 | //check all needed data is available | |
718 | if (!fRefPulserTmean || !fPulserTmean || !fPulserQmean || !fRefPulserQmean || !fALTROMasked || !fRefALTROMasked) return; | |
719 | // | |
720 | UpdateRefPulserOutlierMap(); | |
721 | //loop over all channels | |
732e90a8 | 722 | for (UInt_t isec=0;isec<AliTPCCalPad::kNsec;++isec){ |
7390f655 | 723 | AliTPCCalROC *pqROC=fPulserQmean->GetCalROC(isec); |
724 | AliTPCCalROC *pqRefROC=fRefPulserQmean->GetCalROC(isec); | |
725 | AliTPCCalROC *ptROC=fPulserTmean->GetCalROC(isec); | |
732e90a8 | 726 | // AliTPCCalROC *ptRefROC=fRefPulserTmean->GetCalROC(isec); |
7390f655 | 727 | AliTPCCalROC *mROC=fALTROMasked->GetCalROC(isec); |
728 | AliTPCCalROC *mRefROC=fRefALTROMasked->GetCalROC(isec); | |
729 | AliTPCCalROC *oROC=fPulserOutlier->GetCalROC(isec); | |
730 | Float_t pt_mean=ptROC->GetMean(oROC); | |
731 | UInt_t nrows=mROC->GetNrows(); | |
732 | for (UInt_t irow=0;irow<nrows;++irow){ | |
733 | UInt_t npads=mROC->GetNPads(irow); | |
734 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
735 | //don't use masked channels; | |
736 | if (mROC ->GetValue(irow,ipad)) continue; | |
737 | if (mRefROC->GetValue(irow,ipad)) continue; | |
738 | //don't user edge pads | |
739 | if (ipad==0||ipad==npads-1) continue; | |
740 | //data | |
741 | Float_t pq=pqROC->GetValue(irow,ipad); | |
742 | Float_t pqRef=pqRefROC->GetValue(irow,ipad); | |
743 | Float_t pt=ptROC->GetValue(irow,ipad); | |
744 | // Float_t ptRef=ptRefROC->GetValue(irow,ipad); | |
745 | //comparisons q | |
746 | Float_t deviation=TMath::Abs(pq/pqRef-1); | |
747 | for (Int_t i=0;i<npar;++i){ | |
748 | if (deviation>vThres[i]) | |
749 | ++pulserQdeviations.GetMatrixArray()[i]; | |
750 | } | |
751 | if (pqRef>11&&pq<11) ++npadsOffAdd; | |
752 | varQMean+=pq-pqRef; | |
753 | //comparisons t | |
754 | if (TMath::Abs(pt-pt_mean)>1) ++npadsOutOneTB; | |
755 | ++nActive; | |
756 | }//end ipad | |
757 | }//ind irow | |
758 | }//end isec | |
759 | if (nActive>0){ | |
760 | for (Int_t i=0;i<npar;++i){ | |
761 | pulserQdeviations.GetMatrixArray()[i]/=nActive; | |
762 | varQMean/=nActive; | |
763 | } | |
764 | } | |
765 | } | |
892226be | 766 | //_____________________________________________________________________________________ |
767 | void AliTPCcalibDButil::UpdatePulserOutlierMap() | |
7390f655 | 768 | { |
769 | // | |
770 | // | |
771 | // | |
772 | PulserOutlierMap(fPulserOutlier,fPulserTmean, fPulserQmean); | |
773 | } | |
774 | //_____________________________________________________________________________________ | |
775 | void AliTPCcalibDButil::UpdateRefPulserOutlierMap() | |
776 | { | |
777 | // | |
778 | // | |
779 | // | |
780 | PulserOutlierMap(fRefPulserOutlier,fRefPulserTmean, fRefPulserQmean); | |
781 | } | |
782 | //_____________________________________________________________________________________ | |
783 | void AliTPCcalibDButil::PulserOutlierMap(AliTPCCalPad *pulOut, const AliTPCCalPad *pulT, const AliTPCCalPad *pulQ) | |
892226be | 784 | { |
785 | // | |
786 | // Create a map that contains outliers from the Pulser calibration data. | |
787 | // The outliers include masked channels, edge pads and pads with | |
788 | // too large timing and charge variations. | |
7390f655 | 789 | // fNpulserOutliers is the number of outliers in the Pulser calibration data. |
892226be | 790 | // those do not contain masked and edge pads |
791 | // | |
7390f655 | 792 | if (!pulT||!pulQ) { |
892226be | 793 | //reset map |
7390f655 | 794 | pulOut->Multiply(0.); |
892226be | 795 | fNpulserOutliers=-1; |
796 | return; | |
797 | } | |
798 | AliTPCCalROC *rocMasked=0x0; | |
799 | fNpulserOutliers=0; | |
800 | ||
801 | //Create Outlier Map | |
802 | for (UInt_t isec=0;isec<AliTPCCalPad::kNsec;++isec){ | |
7390f655 | 803 | AliTPCCalROC *tmeanROC=pulT->GetCalROC(isec); |
804 | AliTPCCalROC *qmeanROC=pulQ->GetCalROC(isec); | |
805 | AliTPCCalROC *outROC=pulOut->GetCalROC(isec); | |
892226be | 806 | if (!tmeanROC||!qmeanROC) { |
807 | //reset outliers in this ROC | |
808 | outROC->Multiply(0.); | |
809 | continue; | |
810 | } | |
811 | if (fALTROMasked) rocMasked=fALTROMasked->GetCalROC(isec); | |
812 | // Double_t dummy=0; | |
813 | // Float_t qmedian=qmeanROC->GetLTM(&dummy,.5); | |
814 | // Float_t tmedian=tmeanROC->GetLTM(&dummy,.5); | |
815 | UInt_t nrows=tmeanROC->GetNrows(); | |
816 | for (UInt_t irow=0;irow<nrows;++irow){ | |
817 | UInt_t npads=tmeanROC->GetNPads(irow); | |
818 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
819 | Int_t outlier=0,masked=0; | |
820 | Float_t q=qmeanROC->GetValue(irow,ipad); | |
821 | Float_t t=tmeanROC->GetValue(irow,ipad); | |
822 | //masked channels are outliers | |
823 | if (rocMasked && rocMasked->GetValue(irow,ipad)) masked=1; | |
824 | //edge pads are outliers | |
825 | if (ipad==0||ipad==npads-1) masked=1; | |
826 | //channels with too large charge or timing deviation from the meadian are outliers | |
827 | // if (TMath::Abs(q-qmedian)>fPulQmaxLimitAbs || TMath::Abs(t-tmedian)>fPulTmaxLimitAbs) outlier=1; | |
828 | if (q<fPulQminLimit && !masked) outlier=1; | |
829 | //check for nan | |
830 | if ( !(q<10000000) || !(t<10000000)) outlier=1; | |
831 | outROC->SetValue(irow,ipad,outlier+masked); | |
832 | fNpulserOutliers+=outlier; | |
833 | } | |
834 | } | |
835 | } | |
836 | } | |
837 | //_____________________________________________________________________________________ | |
2cb269df | 838 | AliTPCCalPad* AliTPCcalibDButil::CreatePadTime0(Int_t model, Double_t &gyA, Double_t &gyC, Double_t &chi2A, Double_t &chi2C ) |
892226be | 839 | { |
840 | // | |
841 | // Create pad time0 object from pulser and/or CE data, depending on the selected model | |
842 | // Model 0: normalise each readout chamber to its mean, outlier cutted, only Pulser | |
843 | // Model 1: normalise IROCs/OROCs of each readout side to its mean, only Pulser | |
732e90a8 | 844 | // Model 2: use CE data and a combination CE fit + pulser in the outlier regions. |
892226be | 845 | // |
2cb269df | 846 | // In case model 2 is invoked - gy arival time gradient is also returned |
847 | // | |
848 | gyA=0; | |
849 | gyC=0; | |
892226be | 850 | AliTPCCalPad *padTime0=new AliTPCCalPad("PadTime0",Form("PadTime0-Model_%d",model)); |
851 | // decide between different models | |
852 | if (model==0||model==1){ | |
853 | TVectorD vMean; | |
854 | if (model==1) ProcessPulser(vMean); | |
855 | for (UInt_t isec=0;isec<AliTPCCalPad::kNsec;++isec){ | |
856 | AliTPCCalROC *rocPulTmean=fPulserTmean->GetCalROC(isec); | |
857 | if (!rocPulTmean) continue; | |
858 | AliTPCCalROC *rocTime0=padTime0->GetCalROC(isec); | |
859 | AliTPCCalROC *rocOut=fPulserOutlier->GetCalROC(isec); | |
860 | Float_t mean=rocPulTmean->GetMean(rocOut); | |
861 | //treat case where a whole partition is masked | |
862 | if (mean==0) mean=rocPulTmean->GetMean(); | |
863 | if (model==1) { | |
864 | Int_t type=isec/18; | |
865 | mean=vMean[type]; | |
866 | } | |
867 | UInt_t nrows=rocTime0->GetNrows(); | |
868 | for (UInt_t irow=0;irow<nrows;++irow){ | |
869 | UInt_t npads=rocTime0->GetNPads(irow); | |
870 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
871 | Float_t time=rocPulTmean->GetValue(irow,ipad); | |
872 | //in case of an outlier pad use the mean of the altro values. | |
873 | //This should be the most precise guess in that case. | |
874 | if (rocOut->GetValue(irow,ipad)) { | |
875 | time=GetMeanAltro(rocPulTmean,irow,ipad,rocOut); | |
876 | if (time==0) time=mean; | |
877 | } | |
878 | Float_t val=time-mean; | |
879 | rocTime0->SetValue(irow,ipad,val); | |
880 | } | |
881 | } | |
882 | } | |
2cb269df | 883 | } else if (model==2){ |
884 | Double_t pgya,pgyc,pchi2a,pchi2c; | |
885 | AliTPCCalPad * padPulser = CreatePadTime0(1,pgya,pgyc,pchi2a,pchi2c); | |
886 | fCETmean->Add(padPulser,-1.); | |
732e90a8 | 887 | TVectorD vA,vC; |
888 | AliTPCCalPad outCE("outCE","outCE"); | |
889 | Int_t nOut; | |
2cb269df | 890 | ProcessCEdata("(sector<36)++gy++gx++(lx-134)++(sector<36)*(lx-134)++(ly/lx)^2",vA,vC,nOut,chi2A, chi2C,&outCE); |
891 | AliTPCCalPad *padFit=AliTPCCalPad::CreateCalPadFit("1++0++gy++0++(lx-134)++0++0",vA,vC); | |
732e90a8 | 892 | // AliTPCCalPad *padFit=AliTPCCalPad::CreateCalPadFit("1++(sector<36)++gy++gx++(lx-134)++(sector<36)*(lx-134)",vA,vC); |
2cb269df | 893 | if (!padFit) { delete padPulser; return 0;} |
894 | gyA=vA[2]; | |
895 | gyC=vC[2]; | |
896 | fCETmean->Add(padPulser,1.); | |
732e90a8 | 897 | padTime0->Add(fCETmean); |
2cb269df | 898 | padTime0->Add(padFit,-1); |
899 | delete padPulser; | |
732e90a8 | 900 | TVectorD vFitROC; |
901 | TMatrixD mFitROC; | |
902 | Float_t chi2; | |
903 | for (UInt_t isec=0;isec<AliTPCCalPad::kNsec;++isec){ | |
904 | AliTPCCalROC *rocPulTmean=fPulserTmean->GetCalROC(isec); | |
905 | AliTPCCalROC *rocTime0=padTime0->GetCalROC(isec); | |
906 | AliTPCCalROC *rocOutPul=fPulserOutlier->GetCalROC(isec); | |
907 | AliTPCCalROC *rocOutCE=outCE.GetCalROC(isec); | |
908 | rocTime0->GlobalFit(rocOutCE,kFALSE,vFitROC,mFitROC,chi2); | |
909 | AliTPCCalROC *rocCEfit=AliTPCCalROC::CreateGlobalFitCalROC(vFitROC, isec); | |
910 | Float_t mean=rocPulTmean->GetMean(rocOutPul); | |
911 | if (mean==0) mean=rocPulTmean->GetMean(); | |
912 | UInt_t nrows=rocTime0->GetNrows(); | |
913 | for (UInt_t irow=0;irow<nrows;++irow){ | |
914 | UInt_t npads=rocTime0->GetNPads(irow); | |
915 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
916 | Float_t timePulser=rocPulTmean->GetValue(irow,ipad)-mean; | |
917 | if (rocOutCE->GetValue(irow,ipad)){ | |
918 | Float_t valOut=rocCEfit->GetValue(irow,ipad); | |
919 | if (!rocOutPul->GetValue(irow,ipad)) valOut+=timePulser; | |
920 | rocTime0->SetValue(irow,ipad,valOut); | |
921 | } | |
922 | } | |
923 | } | |
924 | delete rocCEfit; | |
925 | } | |
926 | delete padFit; | |
892226be | 927 | } |
2cb269df | 928 | Double_t median = padTime0->GetMedian(); |
929 | padTime0->Add(-median); // normalize to median | |
892226be | 930 | return padTime0; |
931 | } | |
932 | //_____________________________________________________________________________________ | |
933 | Float_t AliTPCcalibDButil::GetMeanAltro(const AliTPCCalROC *roc, const Int_t row, const Int_t pad, AliTPCCalROC *rocOut) | |
934 | { | |
935 | if (roc==0) return 0.; | |
936 | const Int_t sector=roc->GetSector(); | |
937 | AliTPCROC *tpcRoc=AliTPCROC::Instance(); | |
938 | const UInt_t altroRoc=fMapper->GetFEC(sector,row,pad)*8+fMapper->GetChip(sector,row,pad); | |
939 | Float_t mean=0; | |
940 | Int_t n=0; | |
941 | ||
942 | //loop over a small range around the requested pad (+-10 rows/pads) | |
943 | for (Int_t irow=row-10;irow<row+10;++irow){ | |
944 | if (irow<0||irow>(Int_t)tpcRoc->GetNRows(sector)-1) continue; | |
945 | for (Int_t ipad=pad-10; ipad<pad+10;++ipad){ | |
946 | if (ipad<0||ipad>(Int_t)tpcRoc->GetNPads(sector,irow)-1) continue; | |
947 | const UInt_t altroCurr=fMapper->GetFEC(sector,irow,ipad)*8+fMapper->GetChip(sector,irow,ipad); | |
948 | if (altroRoc!=altroCurr) continue; | |
949 | if ( rocOut && rocOut->GetValue(irow,ipad) ) continue; | |
950 | Float_t val=roc->GetValue(irow,ipad); | |
951 | mean+=val; | |
952 | ++n; | |
953 | } | |
954 | } | |
955 | if (n>0) mean/=n; | |
956 | return mean; | |
957 | } | |
7390f655 | 958 | //_____________________________________________________________________________________ |
959 | void AliTPCcalibDButil::SetRefFile(const char* filename) | |
960 | { | |
961 | // | |
962 | // load cal pad objects form the reference file | |
963 | // | |
964 | TDirectory *currDir=gDirectory; | |
965 | TFile f(filename); | |
966 | fRefPedestals=(AliTPCCalPad*)f.Get("Pedestals"); | |
967 | fRefPadNoise=(AliTPCCalPad*)f.Get("PadNoise"); | |
968 | //pulser data | |
969 | fRefPulserTmean=(AliTPCCalPad*)f.Get("PulserTmean"); | |
970 | fRefPulserTrms=(AliTPCCalPad*)f.Get("PulserTrms"); | |
971 | fRefPulserQmean=(AliTPCCalPad*)f.Get("PulserQmean"); | |
972 | //CE data | |
973 | fRefCETmean=(AliTPCCalPad*)f.Get("CETmean"); | |
974 | fRefCETrms=(AliTPCCalPad*)f.Get("CETrms"); | |
975 | fRefCEQmean=(AliTPCCalPad*)f.Get("CEQmean"); | |
976 | //Altro data | |
977 | // fRefALTROAcqStart=(AliTPCCalPad*)f.Get("ALTROAcqStart"); | |
978 | // fRefALTROZsThr=(AliTPCCalPad*)f.Get("ALTROZsThr"); | |
979 | // fRefALTROFPED=(AliTPCCalPad*)f.Get("ALTROFPED"); | |
980 | // fRefALTROAcqStop=(AliTPCCalPad*)f.Get("ALTROAcqStop"); | |
981 | fRefALTROMasked=(AliTPCCalPad*)f.Get("ALTROMasked"); | |
982 | f.Close(); | |
983 | currDir->cd(); | |
984 | } | |
949d8707 | 985 | //_____________________________________________________________________________________ |
986 | void AliTPCcalibDButil::UpdateRefDataFromOCDB() | |
987 | { | |
988 | // | |
989 | // set reference data from OCDB Reference map | |
990 | // | |
991 | if (!fRefMap) { | |
992 | AliWarning("Referenc map not set!"); | |
993 | return; | |
994 | } | |
995 | ||
996 | TString cdbPath; | |
997 | AliCDBEntry* entry = 0x0; | |
998 | Bool_t hasAnyChanged=kFALSE; | |
999 | ||
1000 | //pedestals | |
1001 | cdbPath="TPC/Calib/Pedestals"; | |
1002 | if (HasRefChanged(cdbPath.Data())){ | |
1003 | hasAnyChanged=kTRUE; | |
1004 | //delete old entries | |
1005 | if (fRefPedestals) delete fRefPedestals; | |
1006 | if (fRefPedestalMasked) delete fRefPedestalMasked; | |
1007 | fRefPedestals=fRefPedestalMasked=0x0; | |
1008 | //get new entries | |
1009 | entry=GetRefEntry(cdbPath.Data()); | |
1010 | if (entry){ | |
1011 | entry->SetOwner(kTRUE); | |
1012 | fRefPedestals=GetRefCalPad(entry); | |
1013 | delete entry; | |
1014 | fRefPedestalMasked=GetAltroMasked(cdbPath, "MaskedPedestals"); | |
1015 | } | |
1016 | } | |
7390f655 | 1017 | |
949d8707 | 1018 | //noise |
1019 | cdbPath="TPC/Calib/PadNoise"; | |
1020 | if (HasRefChanged(cdbPath.Data())){ | |
1021 | hasAnyChanged=kTRUE; | |
1022 | //delete old entry | |
1023 | if (fRefPadNoise) delete fRefPadNoise; | |
1024 | fRefPadNoise=0x0; | |
1025 | //get new entry | |
1026 | entry=GetRefEntry(cdbPath.Data()); | |
1027 | if (entry){ | |
1028 | entry->SetOwner(kTRUE); | |
1029 | fRefPadNoise=GetRefCalPad(entry); | |
1030 | delete entry; | |
1031 | } | |
1032 | } | |
1033 | ||
1034 | //pulser | |
1035 | cdbPath="TPC/Calib/Pulser"; | |
1036 | if (HasRefChanged(cdbPath.Data())){ | |
1037 | hasAnyChanged=kTRUE; | |
1038 | //delete old entries | |
1039 | if (fRefPulserTmean) delete fRefPulserTmean; | |
1040 | if (fRefPulserTrms) delete fRefPulserTrms; | |
1041 | if (fRefPulserQmean) delete fRefPulserQmean; | |
1042 | if (fRefPulserMasked) delete fRefPulserMasked; | |
1043 | fRefPulserTmean=fRefPulserTrms=fRefPulserQmean=fRefPulserMasked=0x0; | |
1044 | //get new entries | |
1045 | entry=GetRefEntry(cdbPath.Data()); | |
1046 | if (entry){ | |
1047 | entry->SetOwner(kTRUE); | |
1048 | fRefPulserTmean=GetRefCalPad(entry,"PulserTmean"); | |
1049 | fRefPulserTrms=GetRefCalPad(entry,"PulserTrms"); | |
1050 | fRefPulserQmean=GetRefCalPad(entry,"PulserQmean"); | |
1051 | delete entry; | |
1052 | fRefPulserMasked=GetAltroMasked(cdbPath, "MaskedPulser"); | |
1053 | } | |
1054 | } | |
2cb269df | 1055 | |
949d8707 | 1056 | //ce |
1057 | cdbPath="TPC/Calib/CE"; | |
1058 | if (HasRefChanged(cdbPath.Data())){ | |
1059 | hasAnyChanged=kTRUE; | |
1060 | //delete old entries | |
1061 | if (fRefCETmean) delete fRefCETmean; | |
1062 | if (fRefCETrms) delete fRefCETrms; | |
1063 | if (fRefCEQmean) delete fRefCEQmean; | |
1064 | if (fRefCEMasked) delete fRefCEMasked; | |
1065 | fRefCETmean=fRefCETrms=fRefCEQmean=fRefCEMasked=0x0; | |
1066 | //get new entries | |
1067 | entry=GetRefEntry(cdbPath.Data()); | |
1068 | if (entry){ | |
1069 | entry->SetOwner(kTRUE); | |
1070 | fRefCETmean=GetRefCalPad(entry,"CETmean"); | |
1071 | fRefCETrms=GetRefCalPad(entry,"CETrms"); | |
1072 | fRefCEQmean=GetRefCalPad(entry,"CEQmean"); | |
1073 | delete entry; | |
1074 | fRefCEMasked=GetAltroMasked(cdbPath, "MaskedCE"); | |
1075 | } | |
1076 | } | |
1077 | ||
1078 | //altro data | |
1079 | cdbPath="TPC/Calib/AltroConfig"; | |
1080 | if (HasRefChanged(cdbPath.Data())){ | |
1081 | hasAnyChanged=kTRUE; | |
1082 | //delete old entries | |
1083 | if (fRefALTROFPED) delete fRefALTROFPED; | |
1084 | if (fRefALTROZsThr) delete fRefALTROZsThr; | |
1085 | if (fRefALTROAcqStart) delete fRefALTROAcqStart; | |
1086 | if (fRefALTROAcqStop) delete fRefALTROAcqStop; | |
1087 | if (fRefALTROMasked) delete fRefALTROMasked; | |
1088 | fRefALTROFPED=fRefALTROZsThr=fRefALTROAcqStart=fRefALTROAcqStop=fRefALTROMasked=0x0; | |
1089 | //get new entries | |
1090 | entry=GetRefEntry(cdbPath.Data()); | |
1091 | if (entry){ | |
1092 | entry->SetOwner(kTRUE); | |
1093 | fRefALTROFPED=GetRefCalPad(entry,"FPED"); | |
1094 | fRefALTROZsThr=GetRefCalPad(entry,"ZsThr"); | |
1095 | fRefALTROAcqStart=GetRefCalPad(entry,"AcqStart"); | |
1096 | fRefALTROAcqStop=GetRefCalPad(entry,"AcqStop"); | |
1097 | fRefALTROMasked=GetRefCalPad(entry,"Masked"); | |
1098 | delete entry; | |
1099 | } | |
1100 | } | |
1101 | ||
1102 | //raw data | |
1103 | /* | |
1104 | cdbPath="TPC/Calib/Raw"; | |
1105 | if (HasRefChanged(cdbPath.Data())){ | |
1106 | hasAnyChanged=kTRUE; | |
1107 | //delete old entry | |
1108 | if (fRefCalibRaw) delete fRefCalibRaw; | |
1109 | //get new entry | |
1110 | entry=GetRefEntry(cdbPath.Data()); | |
1111 | if (entry){ | |
1112 | entry->SetOwner(kTRUE); | |
1113 | TObjArray *arr=(TObjArray*)entry->GetObject(); | |
1114 | if (!arr){ | |
1115 | AliError(Form("Could not get object from entry '%s'\nPlese check!!!",entry->GetId().GetPath().Data())); | |
1116 | } else { | |
1117 | fRefCalibRaw=(AliTPCCalibRaw*)arr->At(0)->Clone(); | |
1118 | } | |
1119 | } | |
1120 | } | |
1121 | */ | |
2cb269df | 1122 | |
949d8707 | 1123 | //data qa |
1124 | cdbPath="TPC/Calib/QA"; | |
1125 | if (HasRefChanged(cdbPath.Data())){ | |
1126 | hasAnyChanged=kTRUE; | |
1127 | //delete old entry | |
1128 | if (fRefDataQA) delete fRefDataQA; | |
1129 | //get new entry | |
1130 | entry=GetRefEntry(cdbPath.Data()); | |
1131 | if (entry){ | |
1132 | entry->SetOwner(kTRUE); | |
1133 | fDataQA=dynamic_cast<AliTPCdataQA*>(entry->GetObject()); | |
1134 | if (!fDataQA){ | |
1135 | AliError(Form("Could not get object from entry '%s'\nPlese check!!!",entry->GetId().GetPath().Data())); | |
1136 | } else { | |
1137 | fRefDataQA=(AliTPCdataQA*)fDataQA->Clone(); | |
1138 | } | |
1139 | delete entry; | |
1140 | } | |
1141 | } | |
1142 | ||
1143 | ||
1144 | //update current reference maps | |
1145 | if (hasAnyChanged){ | |
1146 | if (fCurrentRefMap) delete fCurrentRefMap; | |
1147 | fCurrentRefMap=(TMap*)fRefMap->Clone(); | |
1148 | } | |
1149 | } | |
1150 | //_____________________________________________________________________________________ | |
1151 | AliTPCCalPad* AliTPCcalibDButil::GetRefCalPad(AliCDBEntry *entry, const char* objName) | |
1152 | { | |
1153 | // | |
1154 | // TObjArray object type case | |
1155 | // find 'objName' in 'arr' cast is to a calPad and store it in 'pad' | |
1156 | // | |
1157 | AliTPCCalPad *pad=0x0; | |
1158 | TObjArray *arr=(TObjArray*)entry->GetObject(); | |
1159 | if (!arr){ | |
1160 | AliError(Form("Could not get object from entry '%s'\nPlese check!!!",entry->GetId().GetPath().Data())); | |
1161 | return pad; | |
1162 | } | |
1163 | pad=(AliTPCCalPad*)arr->FindObject(objName); | |
1164 | if (!pad) { | |
1165 | AliError(Form("Could not get '%s' from TObjArray in entry '%s'\nPlese check!!!",objName,entry->GetId().GetPath().Data())); | |
1166 | return pad; | |
1167 | } | |
1168 | return (AliTPCCalPad*)pad->Clone(); | |
1169 | } | |
1170 | //_____________________________________________________________________________________ | |
1171 | AliTPCCalPad* AliTPCcalibDButil::GetRefCalPad(AliCDBEntry *entry) | |
1172 | { | |
1173 | // | |
1174 | // AliTPCCalPad object type case | |
1175 | // cast object to a calPad and store it in 'pad' | |
1176 | // | |
1177 | AliTPCCalPad *pad=(AliTPCCalPad*)entry->GetObject(); | |
1178 | if (!pad) { | |
1179 | AliError(Form("Could not get object from entry '%s'\nPlese check!!!",entry->GetId().GetPath().Data())); | |
1180 | return 0x0; | |
1181 | } | |
1182 | pad=(AliTPCCalPad*)pad->Clone(); | |
1183 | return pad; | |
1184 | } | |
1185 | //_____________________________________________________________________________________ | |
1186 | AliTPCCalPad* AliTPCcalibDButil::GetAltroMasked(const char* cdbPath, const char* name) | |
1187 | { | |
1188 | // | |
1189 | // set altro masked channel map for 'cdbPath' | |
1190 | // | |
1191 | AliTPCCalPad* pad=0x0; | |
1192 | const Int_t run=GetReferenceRun(cdbPath); | |
1193 | if (run<0) { | |
1194 | AliError(Form("Could not get reference run number for object '%s'\nPlese check availability!!!",cdbPath)); | |
1195 | return pad; | |
1196 | } | |
1197 | AliCDBEntry *entry=AliCDBManager::Instance()->Get("TPC/Calib/AltroConfig", run); | |
1198 | if (!entry) { | |
1199 | AliError(Form("Could not get reference object '%s'\nPlese check availability!!!",cdbPath)); | |
1200 | return pad; | |
1201 | } | |
1202 | pad=GetRefCalPad(entry,"Masked"); | |
1203 | if (pad) pad->SetNameTitle(name,name); | |
1204 | entry->SetOwner(kTRUE); | |
1205 | delete entry; | |
1206 | return pad; | |
1207 | } | |
1208 | //_____________________________________________________________________________________ | |
1209 | void AliTPCcalibDButil::SetReferenceRun(Int_t run){ | |
1210 | // | |
1211 | // Get Reference map | |
1212 | // | |
1213 | if (run<0) run=fCalibDB->GetRun(); | |
1214 | TString cdbPath="TPC/Calib/Ref"; | |
1215 | AliCDBEntry *entry=AliCDBManager::Instance()->Get(cdbPath.Data(), run); | |
1216 | if (!entry) { | |
1217 | AliError(Form("Could not get reference object '%s'\nPlese check availability!!!",cdbPath.Data())); | |
1218 | fRefMap=0; | |
1219 | return; | |
1220 | } | |
1221 | entry->SetOwner(kTRUE); | |
1222 | fRefMap=(TMap*)(entry->GetObject()); | |
1223 | AliCDBId &id=entry->GetId(); | |
1224 | fRefValidity.Form("%d_%d_v%d_s%d",id.GetFirstRun(),id.GetLastRun(),id.GetVersion(),id.GetSubVersion()); | |
1225 | } | |
1226 | //_____________________________________________________________________________________ | |
1227 | Bool_t AliTPCcalibDButil::HasRefChanged(const char *cdbPath) | |
1228 | { | |
1229 | // | |
1230 | // check whether a reference cdb entry has changed | |
1231 | // | |
1232 | if (!fCurrentRefMap) return kTRUE; | |
1233 | if (GetReferenceRun(cdbPath)!=GetCurrentReferenceRun(cdbPath)) return kTRUE; | |
1234 | return kFALSE; | |
1235 | } | |
1236 | //_____________________________________________________________________________________ | |
1237 | AliCDBEntry* AliTPCcalibDButil::GetRefEntry(const char* cdbPath) | |
1238 | { | |
1239 | // | |
1240 | // get the reference AliCDBEntry for 'cdbPath' | |
1241 | // | |
1242 | const Int_t run=GetReferenceRun(cdbPath); | |
1243 | if (run<0) { | |
1244 | AliError(Form("Could not get reference run number for object '%s'\nPlese check availability!!!",cdbPath)); | |
1245 | return 0; | |
1246 | } | |
1247 | AliCDBEntry *entry=AliCDBManager::Instance()->Get(cdbPath, run); | |
1248 | if (!entry) { | |
1249 | AliError(Form("Could not get reference object '%s'\nPlese check availability!!!",cdbPath)); | |
1250 | return 0; | |
1251 | } | |
1252 | return entry; | |
1253 | } | |
1254 | //_____________________________________________________________________________________ | |
1255 | const Int_t AliTPCcalibDButil::GetCurrentReferenceRun(const char* type){ | |
1256 | // | |
1257 | // Get reference run number for the specified OCDB path | |
1258 | // | |
1259 | if (!fCurrentRefMap) return -2; | |
1260 | TObjString *str=dynamic_cast<TObjString*>(fCurrentRefMap->GetValue(type)); | |
1261 | if (!str) return -2; | |
1262 | return str->GetString().Atoi(); | |
1263 | } | |
1264 | //_____________________________________________________________________________________ | |
1265 | const Int_t AliTPCcalibDButil::GetReferenceRun(const char* type) const{ | |
1266 | // | |
1267 | // Get reference run number for the specified OCDB path | |
1268 | // | |
1269 | if (!fRefMap) return -1; | |
1270 | TObjString *str=dynamic_cast<TObjString*>(fRefMap->GetValue(type)); | |
1271 | if (!str) return -1; | |
1272 | return str->GetString().Atoi(); | |
1273 | } | |
1274 | //_____________________________________________________________________________________ | |
2cb269df | 1275 | AliTPCCalPad *AliTPCcalibDButil::CreateCEOutlyerMap( Int_t & noutliersCE, AliTPCCalPad *ceOut, Float_t minSignal, Float_t cutTrmsMin, Float_t cutTrmsMax, Float_t cutMaxDistT){ |
1276 | // | |
1277 | // Author: marian.ivanov@cern.ch | |
1278 | // | |
1279 | // Create outlier map for CE study | |
1280 | // Parameters: | |
1281 | // Return value - outlyer map | |
1282 | // noutlyersCE - number of outlyers | |
1283 | // minSignal - minimal total Q signal | |
1284 | // cutRMSMin - minimal width of the signal in respect to the median | |
1285 | // cutRMSMax - maximal width of the signal in respect to the median | |
1286 | // cutMaxDistT - maximal deviation from time median per chamber | |
1287 | // | |
1288 | // Outlyers criteria: | |
1289 | // 0. Exclude masked pads | |
1290 | // 1. Exclude first two rows in IROC and last two rows in OROC | |
1291 | // 2. Exclude edge pads | |
1292 | // 3. Exclude channels with too large variations | |
1293 | // 4. Exclude pads with too small signal | |
1294 | // 5. Exclude signal with outlyers RMS | |
1295 | // 6. Exclude channels to far from the chamber median | |
1296 | noutliersCE=0; | |
1297 | //create outlier map | |
1298 | AliTPCCalPad *out=ceOut; | |
1299 | if (!out) out= new AliTPCCalPad("outCE","outCE"); | |
1300 | AliTPCCalROC *rocMasked=0x0; | |
1301 | if (!fCETmean) return 0; | |
1302 | if (!fCETrms) return 0; | |
1303 | if (!fCEQmean) return 0; | |
1304 | // | |
1305 | //loop over all channels | |
1306 | // | |
1307 | Double_t rmsMedian = fCETrms->GetMedian(); | |
1308 | for (UInt_t iroc=0;iroc<fCETmean->kNsec;++iroc){ | |
1309 | AliTPCCalROC *rocData=fCETmean->GetCalROC(iroc); | |
1310 | if (fALTROMasked) rocMasked= fALTROMasked->GetCalROC(iroc); | |
1311 | AliTPCCalROC *rocOut = out->GetCalROC(iroc); | |
1312 | AliTPCCalROC *rocCEQ = fCEQmean->GetCalROC(iroc); | |
1313 | AliTPCCalROC *rocCETrms = fCETrms->GetCalROC(iroc); | |
1314 | Double_t trocMedian = rocData->GetMedian(); | |
1315 | // | |
1316 | if (!rocData) { | |
1317 | noutliersCE+=AliTPCROC::Instance()->GetNChannels(iroc); | |
1318 | rocOut->Add(1.); | |
1319 | continue; | |
1320 | } | |
1321 | // | |
1322 | //select outliers | |
1323 | UInt_t nrows=rocData->GetNrows(); | |
1324 | for (UInt_t irow=0;irow<nrows;++irow){ | |
1325 | UInt_t npads=rocData->GetNPads(irow); | |
1326 | for (UInt_t ipad=0;ipad<npads;++ipad){ | |
1327 | rocOut->SetValue(irow,ipad,0); | |
1328 | Float_t valTmean=rocData->GetValue(irow,ipad); | |
1329 | Float_t valQmean=rocCEQ->GetValue(irow,ipad); | |
1330 | Float_t valTrms =rocCETrms->GetValue(irow,ipad); | |
1331 | //0. exclude masked pads | |
1332 | if (rocMasked && rocMasked->GetValue(irow,ipad)) { | |
1333 | rocOut->SetValue(irow,ipad,1); | |
1334 | continue; | |
1335 | } | |
1336 | //1. exclude first two rows in IROC and last two rows in OROC | |
1337 | if (iroc<36){ | |
1338 | if (irow<2) rocOut->SetValue(irow,ipad,1); | |
1339 | } else { | |
1340 | if (irow>nrows-3) rocOut->SetValue(irow,ipad,1); | |
1341 | } | |
1342 | //2. exclude edge pads | |
1343 | if (ipad==0||ipad==npads-1) rocOut->SetValue(irow,ipad,1); | |
1344 | //exclude values that are exactly 0 | |
1345 | if (valTmean==0) { | |
1346 | rocOut->SetValue(irow,ipad,1); | |
1347 | ++noutliersCE; | |
1348 | } | |
1349 | //3. exclude channels with too large variations | |
1350 | if (TMath::Abs(valTmean)>fCETmaxLimitAbs) { | |
1351 | rocOut->SetValue(irow,ipad,1); | |
1352 | ++noutliersCE; | |
1353 | } | |
1354 | // | |
1355 | //4. exclude channels with too small signal | |
1356 | if (valQmean<minSignal) { | |
1357 | rocOut->SetValue(irow,ipad,1); | |
1358 | ++noutliersCE; | |
1359 | } | |
1360 | // | |
1361 | //5. exclude channels with too small rms | |
1362 | if (valTrms<cutTrmsMin*rmsMedian || valTrms>cutTrmsMax*rmsMedian){ | |
1363 | rocOut->SetValue(irow,ipad,1); | |
1364 | ++noutliersCE; | |
1365 | } | |
1366 | // | |
1367 | //6. exclude channels to far from the chamber median | |
1368 | if (TMath::Abs(valTmean-trocMedian)>cutMaxDistT){ | |
1369 | rocOut->SetValue(irow,ipad,1); | |
1370 | ++noutliersCE; | |
1371 | } | |
1372 | } | |
1373 | } | |
1374 | } | |
1375 | // | |
1376 | return out; | |
1377 | } | |
1378 | ||
1379 | ||
1380 | AliTPCCalPad *AliTPCcalibDButil::CreatePulserOutlyerMap(Int_t &noutliersPulser, AliTPCCalPad *pulserOut,Float_t cutTime, Float_t cutnRMSQ, Float_t cutnRMSrms){ | |
1381 | // | |
1382 | // Author: marian.ivanov@cern.ch | |
1383 | // | |
1384 | // Create outlier map for Pulser | |
1385 | // Parameters: | |
1386 | // Return value - outlyer map | |
1387 | // noutlyersPulser - number of outlyers | |
1388 | // cutTime - absolute cut - distance to the median of chamber | |
1389 | // cutnRMSQ - nsigma cut from median q distribution per chamber | |
1390 | // cutnRMSrms - nsigma cut from median rms distribution | |
1391 | // Outlyers criteria: | |
1392 | // 0. Exclude masked pads | |
1393 | // 1. Exclude time outlyers (default 3 time bins) | |
1394 | // 2. Exclude q outlyers (default 5 sigma) | |
1395 | // 3. Exclude rms outlyers (default 5 sigma) | |
1396 | noutliersPulser=0; | |
1397 | AliTPCCalPad *out=pulserOut; | |
1398 | if (!out) out= new AliTPCCalPad("outPulser","outPulser"); | |
1399 | AliTPCCalROC *rocMasked=0x0; | |
1400 | if (!fPulserTmean) return 0; | |
1401 | if (!fPulserTrms) return 0; | |
1402 | if (!fPulserQmean) return 0; | |
1403 | // | |
1404 | //loop over all channels | |
1405 | // | |
1406 | for (UInt_t iroc=0;iroc<fCETmean->kNsec;++iroc){ | |
1407 | if (fALTROMasked) rocMasked= fALTROMasked->GetCalROC(iroc); | |
1408 | AliTPCCalROC *rocData = fPulserTmean->GetCalROC(iroc); | |
1409 | AliTPCCalROC *rocOut = out->GetCalROC(iroc); | |
1410 | AliTPCCalROC *rocPulserQ = fPulserQmean->GetCalROC(iroc); | |
1411 | AliTPCCalROC *rocPulserTrms = fPulserTrms->GetCalROC(iroc); | |
1412 | // | |
1413 | Double_t rocMedianT = rocData->GetMedian(); | |
1414 | Double_t rocMedianQ = rocPulserQ->GetMedian(); | |
1415 | Double_t rocRMSQ = rocPulserQ->GetRMS(); | |
1416 | Double_t rocMedianTrms = rocPulserTrms->GetMedian(); | |
1417 | Double_t rocRMSTrms = rocPulserTrms->GetRMS(); | |
1418 | for (UInt_t ichannel=0;ichannel<rocData->GetNchannels();++ichannel){ | |
1419 | rocOut->SetValue(ichannel,0); | |
1420 | Float_t valTmean=rocData->GetValue(ichannel); | |
1421 | Float_t valQmean=rocPulserQ->GetValue(ichannel); | |
1422 | Float_t valTrms =rocPulserTrms->GetValue(ichannel); | |
1423 | Int_t isOut=0; | |
1424 | if (TMath::Abs(valTmean-rocMedianT)>cutTime) isOut=1; | |
1425 | if (TMath::Abs(valQmean-rocMedianQ)>cutnRMSQ*rocRMSQ) isOut=1; | |
1426 | if (TMath::Abs(valTrms-rocMedianTrms)>cutnRMSrms*rocRMSTrms) isOut=1; | |
1427 | rocOut->SetValue(ichannel,isOut); | |
1428 | if (isOut) noutliersPulser++; | |
1429 | } | |
1430 | } | |
1431 | return out; | |
1432 | } | |
1433 | ||
1434 | ||
1435 | AliTPCCalPad *AliTPCcalibDButil::CreatePadTime0CE(TVectorD &fitResultsA, TVectorD&fitResultsC, Int_t &nOut, Double_t &chi2A, Double_t &chi2C, const char *dumpfile){ | |
1436 | // | |
1437 | // Author : Marian Ivanov | |
1438 | // Create pad time0 correction map using information from the CE and from pulser | |
1439 | // | |
1440 | // | |
1441 | // Return PadTime0 to be used for time0 relative alignment | |
1442 | // if dump file specified intermediat results are dumped to the fiel and can be visualized | |
1443 | // using $ALICE_ROOT/TPC/script/gui application | |
1444 | // | |
1445 | // fitResultsA - fitParameters A side | |
1446 | // fitResultsC - fitParameters C side | |
1447 | // chi2A - chi2/ndf for A side (assuming error 1 time bin) | |
1448 | // chi2C - chi2/ndf for C side (assuming error 1 time bin) | |
1449 | // | |
1450 | // | |
1451 | // Algorithm: | |
1452 | // 1. Find outlier map for CE | |
1453 | // 2. Find outlier map for Pulser | |
1454 | // 3. Replace outlier by median at given sector (median without outliers) | |
1455 | // 4. Substract from the CE data pulser | |
1456 | // 5. Fit the CE with formula | |
1457 | // 5.1) (IROC-OROC) offset | |
1458 | // 5.2) gx | |
1459 | // 5.3) gy | |
1460 | // 5.4) (lx-xmid) | |
1461 | // 5.5) (IROC-OROC)*(lx-xmid) | |
1462 | // 5.6) (ly/lx)^2 | |
1463 | // 6. Substract gy fit dependence from the CE data | |
1464 | // 7. Add pulser back to CE data | |
1465 | // 8. Replace outliers by fit value - median of diff per given chamber -GY fit | |
1466 | // 9. return CE data | |
1467 | // | |
1468 | // Time0 <= padCE = padCEin -padCEfitGy - if not outlier | |
1469 | // Time0 <= padCE = padFitAll-padCEfitGy - if outlier | |
1470 | ||
1471 | // fit formula | |
1472 | const char *formulaIn="(-1.+2.*(sector<36))*0.5++gx++gy++(lx-134.)++(-1.+2.*(sector<36))*0.5*(lx-134)++((ly/lx)^2/(0.1763)^2)"; | |
1473 | // output for fit formula | |
1474 | const char *formulaAll="1++(-1.+2.*(sector<36))*0.5++gx++gy++(lx-134.)++(-1.+2.*(sector<36))*0.5*(lx-134)++((ly/lx)^2/(0.1763)^2)"; | |
1475 | // gy part of formula | |
1476 | const char *formulaOut="0++0*(-1.+2.*(sector<36))*0.5++0*gx++gy++0*(lx-134.)++0*(-1.+2.*(sector<36))*0.5*(lx-134)++0*((ly/lx)^2/(0.1763)^2)"; | |
1477 | // | |
1478 | // | |
1479 | if (!fCETmean) return 0; | |
1480 | Double_t pgya,pgyc,pchi2a,pchi2c; | |
1481 | AliTPCCalPad * padPulserOut = CreatePulserOutlyerMap(nOut); | |
1482 | AliTPCCalPad * padCEOut = CreateCEOutlyerMap(nOut); | |
1483 | ||
1484 | AliTPCCalPad * padPulser = CreatePadTime0(1,pgya,pgyc,pchi2a,pchi2c); | |
1485 | AliTPCCalPad * padCE = new AliTPCCalPad(*fCETmean); | |
1486 | AliTPCCalPad * padCEIn = new AliTPCCalPad(*fCETmean); | |
1487 | AliTPCCalPad * padOut = new AliTPCCalPad("padOut","padOut"); | |
1488 | padPulser->SetName("padPulser"); | |
1489 | padPulserOut->SetName("padPulserOut"); | |
1490 | padCE->SetName("padCE"); | |
1491 | padCEIn->SetName("padCEIn"); | |
1492 | padCEOut->SetName("padCEOut"); | |
1493 | padOut->SetName("padOut"); | |
1494 | ||
1495 | // | |
1496 | // make combined outlyers map | |
1497 | // and replace outlyers in maps with median for chamber | |
1498 | // | |
1499 | for (UInt_t iroc=0;iroc<fCETmean->kNsec;++iroc){ | |
1500 | AliTPCCalROC * rocOut = padOut->GetCalROC(iroc); | |
1501 | AliTPCCalROC * rocPulser = padPulser->GetCalROC(iroc); | |
1502 | AliTPCCalROC * rocPulserOut = padPulserOut->GetCalROC(iroc); | |
1503 | AliTPCCalROC * rocCEOut = padCEOut->GetCalROC(iroc); | |
1504 | AliTPCCalROC * rocCE = padCE->GetCalROC(iroc); | |
1505 | Double_t ceMedian = rocCE->GetMedian(rocCEOut); | |
1506 | Double_t pulserMedian = rocPulser->GetMedian(rocCEOut); | |
1507 | for (UInt_t ichannel=0;ichannel<rocOut->GetNchannels();++ichannel){ | |
1508 | if (rocPulserOut->GetValue(ichannel)>0) { | |
1509 | rocPulser->SetValue(ichannel,pulserMedian); | |
1510 | rocOut->SetValue(ichannel,1); | |
1511 | } | |
1512 | if (rocCEOut->GetValue(ichannel)>0) { | |
1513 | rocCE->SetValue(ichannel,ceMedian); | |
1514 | rocOut->SetValue(ichannel,1); | |
1515 | } | |
1516 | } | |
1517 | } | |
1518 | // | |
1519 | // remove pulser time 0 | |
1520 | // | |
1521 | padCE->Add(padPulser,-1); | |
1522 | // | |
1523 | // Make fits | |
1524 | // | |
1525 | TMatrixD dummy; | |
1526 | Float_t chi2Af,chi2Cf; | |
1527 | padCE->GlobalSidesFit(padOut,formulaIn,fitResultsA,fitResultsC,dummy,dummy,chi2Af,chi2Cf); | |
1528 | chi2A=chi2Af; | |
1529 | chi2C=chi2Cf; | |
1530 | // | |
1531 | AliTPCCalPad *padCEFitGY=AliTPCCalPad::CreateCalPadFit(formulaOut,fitResultsA,fitResultsC); | |
1532 | padCEFitGY->SetName("padCEFitGy"); | |
1533 | // | |
1534 | AliTPCCalPad *padCEFit =AliTPCCalPad::CreateCalPadFit(formulaAll,fitResultsA,fitResultsC); | |
1535 | padCEFit->SetName("padCEFit"); | |
1536 | // | |
1537 | AliTPCCalPad* padCEDiff = new AliTPCCalPad(*padCE); | |
1538 | padCEDiff->SetName("padCEDiff"); | |
1539 | padCEDiff->Add(padCEFit,-1.); | |
1540 | // | |
1541 | // | |
1542 | padCE->Add(padCEFitGY,-1.); | |
1543 | ||
1544 | padCE->Add(padPulser,1.); | |
1545 | Double_t padmedian = padCE->GetMedian(); | |
1546 | padCE->Add(-padmedian); // normalize to median | |
1547 | // | |
1548 | // Replace outliers by fit value - median of diff per given chamber -GY fit | |
1549 | // | |
1550 | for (UInt_t iroc=0;iroc<fCETmean->kNsec;++iroc){ | |
1551 | AliTPCCalROC * rocOut = padOut->GetCalROC(iroc); | |
1552 | AliTPCCalROC * rocCE = padCE->GetCalROC(iroc); | |
1553 | AliTPCCalROC * rocCEFit = padCEFit->GetCalROC(iroc); | |
1554 | AliTPCCalROC * rocCEFitGY = padCEFitGY->GetCalROC(iroc); | |
1555 | AliTPCCalROC * rocCEDiff = padCEDiff->GetCalROC(iroc); | |
1556 | // | |
1557 | Double_t diffMedian = rocCEDiff->GetMedian(rocOut); | |
1558 | for (UInt_t ichannel=0;ichannel<rocOut->GetNchannels();++ichannel){ | |
1559 | if (rocOut->GetValue(ichannel)==0) continue; | |
1560 | Float_t value=rocCEFit->GetValue(ichannel)-rocCEFitGY->GetValue(ichannel)-diffMedian-padmedian; | |
1561 | rocCE->SetValue(ichannel,value); | |
1562 | } | |
1563 | } | |
1564 | // | |
1565 | // | |
1566 | if (dumpfile){ | |
1567 | //dump to the file - result can be visualized | |
1568 | AliTPCPreprocessorOnline preprocesor; | |
1569 | preprocesor.AddComponent(new AliTPCCalPad(*padCE)); | |
1570 | preprocesor.AddComponent(new AliTPCCalPad(*padCEIn)); | |
1571 | preprocesor.AddComponent(new AliTPCCalPad(*padCEFit)); | |
1572 | preprocesor.AddComponent(new AliTPCCalPad(*padOut)); | |
1573 | // | |
1574 | preprocesor.AddComponent(new AliTPCCalPad(*padCEFitGY)); | |
1575 | preprocesor.AddComponent(new AliTPCCalPad(*padCEDiff)); | |
1576 | // | |
1577 | preprocesor.AddComponent(new AliTPCCalPad(*padCEOut)); | |
1578 | preprocesor.AddComponent(new AliTPCCalPad(*padPulser)); | |
1579 | preprocesor.AddComponent(new AliTPCCalPad(*padPulserOut)); | |
1580 | preprocesor.DumpToFile(dumpfile); | |
1581 | } | |
1582 | delete padPulser; | |
1583 | delete padPulserOut; | |
1584 | delete padCEIn; | |
1585 | delete padCEOut; | |
1586 | delete padOut; | |
1587 | delete padCEDiff; | |
1588 | delete padCEFitGY; | |
1589 | return padCE; | |
1590 | } | |
1591 | ||
817766d5 | 1592 | |
1593 | ||
1594 | ||
1595 | ||
1596 | Int_t AliTPCcalibDButil::GetNearest(TGraph *graph, Double_t xref, Double_t &dx, Double_t &y){ | |
1597 | // | |
1598 | // find the closest point to xref in x direction | |
1599 | // return dx and value | |
1600 | Int_t index=0; | |
1601 | index = TMath::BinarySearch(graph->GetN(), graph->GetX(),xref); | |
1602 | if (index<0) index=0; | |
1603 | if (index>=graph->GetN()-1) index=graph->GetN()-2; | |
1604 | if (xref-graph->GetX()[index]>graph->GetX()[index]-xref) index++; | |
1605 | dx = xref-graph->GetX()[index]; | |
1606 | y = graph->GetY()[index]; | |
1607 | return index; | |
1608 | } | |
1609 | ||
1610 | ||
1611 | Double_t AliTPCcalibDButil::GetTriggerOffsetTPC(Int_t run, Int_t timeStamp, Double_t deltaT, Double_t deltaTLaser, Int_t valType){ | |
1612 | // | |
1613 | // Get the correction of the trigger offset | |
1614 | // combining information from the laser track calibration | |
1615 | // and from cosmic calibration | |
1616 | // | |
1617 | // run - run number | |
1618 | // timeStamp - tim stamp in seconds | |
1619 | // deltaT - integration period to calculate offset | |
1620 | // deltaTLaser -max validity of laser data | |
1621 | // valType - 0 - median, 1- mean | |
1622 | // | |
1623 | // Integration vaues are just recomendation - if not possible to get points | |
1624 | // automatically increase the validity by factor 2 | |
1625 | // (recursive algorithm until one month of data taking) | |
1626 | // | |
1627 | // | |
1628 | const Float_t kLaserCut=0.0005; | |
1629 | const Int_t kMaxPeriod=3600*24*30*3; // 3 month max | |
1630 | const Int_t kMinPoints=20; | |
1631 | // | |
1632 | TObjArray *array =AliTPCcalibDB::Instance()->GetTimeVdriftSplineRun(run); | |
1633 | if (!array) { | |
1634 | AliTPCcalibDB::Instance()->UpdateRunInformations(run,kFALSE); | |
1635 | } | |
1636 | array =AliTPCcalibDB::Instance()->GetTimeVdriftSplineRun(run); | |
1637 | if (!array) return 0; | |
1638 | // | |
1639 | TGraphErrors *laserA[3]={0,0,0}; | |
1640 | TGraphErrors *laserC[3]={0,0,0}; | |
1641 | TGraphErrors *cosmicAll=0; | |
1642 | laserA[1]=(TGraphErrors*)array->FindObject("GRAPH_MEAN_DRIFT_LASER_ALL_A"); | |
1643 | laserC[1]=(TGraphErrors*)array->FindObject("GRAPH_MEAN_DRIFT_LASER_ALL_C"); | |
1644 | cosmicAll =(TGraphErrors*)array->FindObject("TGRAPHERRORS_MEAN_VDRIFT_COSMICS_ALL"); | |
1645 | // | |
1646 | // | |
1647 | if (!cosmicAll) return 0; | |
1648 | Int_t nmeasC=cosmicAll->GetN(); | |
1649 | Float_t *tdelta = new Float_t[nmeasC]; | |
1650 | Int_t nused=0; | |
1651 | for (Int_t i=0;i<nmeasC;i++){ | |
1652 | if (TMath::Abs(cosmicAll->GetX()[i]-timeStamp)>deltaT) continue; | |
1653 | Float_t ccosmic=cosmicAll->GetY()[i]; | |
1654 | Double_t yA=0,yC=0,dA=0,dC=0; | |
1655 | if (laserA[1]) GetNearest(laserA[1], cosmicAll->GetX()[i],dA,yA); | |
1656 | if (laserC[1]) GetNearest(laserC[1], cosmicAll->GetX()[i],dC,yC); | |
1657 | //yA=laserA[1]->Eval(cosmicAll->GetX()[i]); | |
1658 | //yC=laserC[1]->Eval(cosmicAll->GetX()[i]); | |
1659 | // | |
1660 | if (TMath::Sqrt(dA*dA+dC*dC)>deltaTLaser) continue; | |
1661 | Float_t claser=0; | |
1662 | if (TMath::Abs(yA-yC)<kLaserCut) { | |
1663 | claser=(yA-yC)*0.5; | |
1664 | }else{ | |
1665 | if (i%2==0) claser=yA; | |
1666 | if (i%2==1) claser=yC; | |
1667 | } | |
1668 | tdelta[nused]=ccosmic-claser; | |
1669 | nused++; | |
1670 | } | |
1671 | if (nused<kMinPoints &&deltaT<kMaxPeriod) return AliTPCcalibDButil::GetTriggerOffsetTPC(run, timeStamp, deltaT*2,deltaTLaser); | |
1672 | Double_t median = TMath::Median(nused,tdelta); | |
1673 | Double_t mean = TMath::Mean(nused,tdelta); | |
1674 | delete tdelta; | |
1675 | return (valType==0) ? median:mean; | |
1676 | } | |
1677 | ||
a23ba1c3 | 1678 | Double_t AliTPCcalibDButil::GetVDriftTPC(Double_t &dist, Int_t run, Int_t timeStamp, Double_t deltaT, Double_t deltaTLaser, Int_t valType){ |
817766d5 | 1679 | // |
1680 | // Get the correction of the drift velocity | |
1681 | // combining information from the laser track calibration | |
1682 | // and from cosmic calibration | |
1683 | // | |
a23ba1c3 | 1684 | // dist - return value - distance to closest point in graph |
817766d5 | 1685 | // run - run number |
1686 | // timeStamp - tim stamp in seconds | |
1687 | // deltaT - integration period to calculate time0 offset | |
1688 | // deltaTLaser -max validity of laser data | |
1689 | // valType - 0 - median, 1- mean | |
1690 | // | |
1691 | // Integration vaues are just recomendation - if not possible to get points | |
1692 | // automatically increase the validity by factor 2 | |
1693 | // (recursive algorithm until one month of data taking) | |
1694 | // | |
1695 | // | |
1696 | // | |
1697 | TObjArray *array =AliTPCcalibDB::Instance()->GetTimeVdriftSplineRun(run); | |
1698 | if (!array) { | |
1699 | AliTPCcalibDB::Instance()->UpdateRunInformations(run,kFALSE); | |
1700 | } | |
1701 | array =AliTPCcalibDB::Instance()->GetTimeVdriftSplineRun(run); | |
1702 | if (!array) return 0; | |
1703 | TGraphErrors *cosmicAll=0; | |
1704 | cosmicAll =(TGraphErrors*)array->FindObject("TGRAPHERRORS_MEAN_VDRIFT_COSMICS_ALL"); | |
1705 | if (!cosmicAll) return 0; | |
a23ba1c3 | 1706 | Double_t grY=0; |
1707 | AliTPCcalibDButil::GetNearest(cosmicAll,timeStamp,dist,grY); | |
1708 | ||
817766d5 | 1709 | Double_t t0= AliTPCcalibDButil::GetTriggerOffsetTPC(run,timeStamp, deltaT, deltaTLaser,valType); |
a23ba1c3 | 1710 | Double_t vcosmic= AliTPCcalibDButil::EvalGraphConst(cosmicAll, timeStamp); |
1e722a63 | 1711 | if (timeStamp>cosmicAll->GetX()[cosmicAll->GetN()-1]) vcosmic=cosmicAll->GetY()[cosmicAll->GetN()-1]; |
817766d5 | 1712 | if (timeStamp<cosmicAll->GetX()[0]) vcosmic=cosmicAll->GetY()[0]; |
1713 | return vcosmic+t0; | |
1714 | ||
1715 | /* | |
1716 | Example usage: | |
1717 | ||
1718 | Int_t run=89000 | |
1719 | TObjArray *array =AliTPCcalibDB::Instance()->GetTimeVdriftSplineRun(run); | |
1720 | cosmicAll =(TGraphErrors*)array->FindObject("TGRAPHERRORS_MEAN_VDRIFT_COSMICS_ALL"); | |
1721 | laserA=(TGraphErrors*)array->FindObject("GRAPH_MEAN_DRIFT_LASER_ALL_A"); | |
1722 | // | |
1723 | Double_t *yvd= new Double_t[cosmicAll->GetN()]; | |
1724 | Double_t *yt0= new Double_t[cosmicAll->GetN()]; | |
1725 | for (Int_t i=0; i<cosmicAll->GetN();i++) yvd[i]=AliTPCcalibDButil::GetVDriftTPC(run,cosmicAll->GetX()[i]); | |
1726 | for (Int_t i=0; i<cosmicAll->GetN();i++) yt0[i]=AliTPCcalibDButil::GetTriggerOffsetTPC(run,cosmicAll->GetX()[i]); | |
1727 | ||
1728 | TGraph *pcosmicVd=new TGraph(cosmicAll->GetN(), cosmicAll->GetX(), yvd); | |
1729 | TGraph *pcosmicT0=new TGraph(cosmicAll->GetN(), cosmicAll->GetX(), yt0); | |
1730 | ||
1731 | */ | |
1732 | ||
1733 | } | |
1734 | ||
949d8707 | 1735 | const char* AliTPCcalibDButil::GetGUIRefTreeDefaultName() |
1736 | { | |
1737 | // | |
1738 | // Create a default name for the gui file | |
1739 | // | |
1740 | ||
1741 | return Form("guiRefTreeRun%s.root",GetRefValidity()); | |
1742 | } | |
1743 | ||
1744 | Bool_t AliTPCcalibDButil::CreateGUIRefTree(const char* filename) | |
1745 | { | |
1746 | // | |
1747 | // Create a gui reference tree | |
1748 | // if dirname and filename are empty default values will be used | |
1749 | // this is the recommended way of using this function | |
1750 | // it allows to check whether a file with the given run validity alredy exists | |
1751 | // | |
1752 | if (!AliCDBManager::Instance()->GetDefaultStorage()){ | |
1753 | AliError("Default Storage not set. Cannot create reference calibration Tree!"); | |
1754 | return kFALSE; | |
1755 | } | |
1756 | ||
1757 | TString file=filename; | |
1758 | if (file.IsNull()) file=GetGUIRefTreeDefaultName(); | |
1759 | ||
1760 | AliTPCPreprocessorOnline prep; | |
1761 | //noise and pedestals | |
1762 | if (fRefPedestals) prep.AddComponent(new AliTPCCalPad(*(fRefPedestals))); | |
1763 | if (fRefPadNoise ) prep.AddComponent(new AliTPCCalPad(*(fRefPadNoise))); | |
1764 | if (fRefPedestalMasked) prep.AddComponent(new AliTPCCalPad(*fRefPedestalMasked)); | |
1765 | //pulser data | |
1766 | if (fRefPulserTmean) prep.AddComponent(new AliTPCCalPad(*(fRefPulserTmean))); | |
1767 | if (fRefPulserTrms ) prep.AddComponent(new AliTPCCalPad(*(fRefPulserTrms))); | |
1768 | if (fRefPulserQmean) prep.AddComponent(new AliTPCCalPad(*(fRefPulserQmean))); | |
1769 | if (fRefPulserMasked) prep.AddComponent(new AliTPCCalPad(*fRefPulserMasked)); | |
1770 | //CE data | |
1771 | if (fRefCETmean) prep.AddComponent(new AliTPCCalPad(*(fRefCETmean))); | |
1772 | if (fRefCETrms ) prep.AddComponent(new AliTPCCalPad(*(fRefCETrms))); | |
1773 | if (fRefCEQmean) prep.AddComponent(new AliTPCCalPad(*(fRefCEQmean))); | |
1774 | if (fRefCEMasked) prep.AddComponent(new AliTPCCalPad(*fRefCEMasked)); | |
1775 | //Altro data | |
1776 | if (fRefALTROAcqStart ) prep.AddComponent(new AliTPCCalPad(*(fRefALTROAcqStart ))); | |
1777 | if (fRefALTROZsThr ) prep.AddComponent(new AliTPCCalPad(*(fRefALTROZsThr ))); | |
1778 | if (fRefALTROFPED ) prep.AddComponent(new AliTPCCalPad(*(fRefALTROFPED ))); | |
1779 | if (fRefALTROAcqStop ) prep.AddComponent(new AliTPCCalPad(*(fRefALTROAcqStop ))); | |
1780 | if (fRefALTROMasked ) prep.AddComponent(new AliTPCCalPad(*(fRefALTROMasked ))); | |
1781 | //QA | |
1782 | AliTPCdataQA *dataQA=fRefDataQA; | |
1783 | if (dataQA) { | |
1784 | if (dataQA->GetNLocalMaxima()) | |
1785 | prep.AddComponent(new AliTPCCalPad(*(dataQA->GetNLocalMaxima()))); | |
1786 | if (dataQA->GetMaxCharge()) | |
1787 | prep.AddComponent(new AliTPCCalPad(*(dataQA->GetMaxCharge()))); | |
1788 | if (dataQA->GetMeanCharge()) | |
1789 | prep.AddComponent(new AliTPCCalPad(*(dataQA->GetMeanCharge()))); | |
1790 | if (dataQA->GetNoThreshold()) | |
1791 | prep.AddComponent(new AliTPCCalPad(*(dataQA->GetNoThreshold()))); | |
1792 | if (dataQA->GetNTimeBins()) | |
1793 | prep.AddComponent(new AliTPCCalPad(*(dataQA->GetNTimeBins()))); | |
1794 | if (dataQA->GetNPads()) | |
1795 | prep.AddComponent(new AliTPCCalPad(*(dataQA->GetNPads()))); | |
1796 | if (dataQA->GetTimePosition()) | |
1797 | prep.AddComponent(new AliTPCCalPad(*(dataQA->GetTimePosition()))); | |
1798 | } | |
1799 | prep.DumpToFile(file.Data()); | |
1800 | return kTRUE; | |
1801 | } | |
1802 | ||
a23ba1c3 | 1803 | Double_t AliTPCcalibDButil::GetVDriftTPCLaserTracks(Double_t &dist, Int_t run, Int_t timeStamp, Double_t deltaT, Int_t side){ |
1804 | // | |
1805 | // Get the correction of the drift velocity using the laser tracks calbration | |
1806 | // | |
1807 | // run - run number | |
1808 | // timeStamp - tim stamp in seconds | |
1809 | // deltaT - integration period to calculate time0 offset | |
1810 | // side - 0 - A side, 1 - C side, 2 - mean from both sides | |
1811 | // Note in case no data form both A and C side - the value from active side used | |
1812 | TObjArray *array =AliTPCcalibDB::Instance()->GetTimeVdriftSplineRun(run); | |
1813 | TGraphErrors *grlaserA=0; | |
1814 | TGraphErrors *grlaserC=0; | |
1815 | Double_t vlaserA=0, vlaserC=0; | |
1816 | if (!array) return 0; | |
1817 | grlaserA=(TGraphErrors*)array->FindObject("GRAPH_MEAN_DRIFT_LASER_ALL_A"); | |
1818 | grlaserC=(TGraphErrors*)array->FindObject("GRAPH_MEAN_DRIFT_LASER_ALL_C"); | |
1819 | Double_t deltaY; | |
1820 | if (grlaserA) { | |
1821 | AliTPCcalibDButil::GetNearest(grlaserA,timeStamp,dist,deltaY); | |
1822 | if (TMath::Abs(dist)>deltaT) vlaserA= deltaY; | |
1823 | else vlaserA = AliTPCcalibDButil::EvalGraphConst(grlaserA,timeStamp); | |
1824 | } | |
1825 | if (grlaserC) { | |
1826 | AliTPCcalibDButil::GetNearest(grlaserC,timeStamp,dist,deltaY); | |
1827 | if (TMath::Abs(dist)>deltaT) vlaserC= deltaY; | |
1828 | else vlaserC = AliTPCcalibDButil::EvalGraphConst(grlaserC,timeStamp); | |
1829 | } | |
1830 | if (side==0) return vlaserA; | |
1831 | if (side==1) return vlaserC; | |
1832 | Double_t mdrift=(vlaserA+vlaserC)*0.5; | |
1833 | if (!grlaserA) return vlaserC; | |
1834 | if (!grlaserC) return vlaserA; | |
1835 | return mdrift; | |
1836 | } | |
1837 | ||
1838 | ||
1839 | Double_t AliTPCcalibDButil::GetVDriftTPCCE(Double_t &dist,Int_t run, Int_t timeStamp, Double_t deltaT, Int_t side){ | |
1840 | // | |
1841 | // Get the correction of the drift velocity using the CE laser data | |
1842 | // combining information from the CE, laser track calibration | |
1843 | // and P/T calibration | |
1844 | // | |
1845 | // run - run number | |
1846 | // timeStamp - tim stamp in seconds | |
1847 | // deltaT - integration period to calculate time0 offset | |
1848 | // side - 0 - A side, 1 - C side, 2 - mean from both sides | |
1849 | TObjArray *arrT =AliTPCcalibDB::Instance()->GetCErocTtime(); | |
0d1b4cf8 | 1850 | if (!arrT) return 0; |
a23ba1c3 | 1851 | AliTPCParam *param =AliTPCcalibDB::Instance()->GetParameters(); |
1852 | TObjArray* cearray =AliTPCcalibDB::Instance()->GetCEData(); | |
1853 | AliTPCCalibVdrift * driftCalib = (AliTPCCalibVdrift *)cearray->FindObject("driftPTCE"); | |
1854 | // | |
1855 | // | |
1856 | Double_t corrPTA = 0, corrPTC=0; | |
1857 | Double_t ltime0A = 0, ltime0C=0; | |
1858 | Double_t gry=0; | |
1859 | Double_t corrA=0, corrC=0; | |
1860 | Double_t timeA=0, timeC=0; | |
1861 | TGraph *graphA = (TGraph*)arrT->At(72); | |
1862 | TGraph *graphC = (TGraph*)arrT->At(73); | |
1863 | if (!graphA && !graphC) return 0.; | |
1864 | if (graphA &&graphA->GetN()>0) { | |
1865 | AliTPCcalibDButil::GetNearest(graphA,timeStamp,dist,gry); | |
1866 | timeA = AliTPCcalibDButil::EvalGraphConst(graphA,timeStamp); | |
1867 | Int_t mtime =TMath::Nint((graphA->GetX()[0]+graphA->GetX()[graphA->GetN()-1])*0.5); | |
1868 | ltime0A = GetLaserTime0(run,mtime,TMath::Nint(deltaT),0); | |
1869 | if (driftCalib) corrPTA = driftCalib->GetPTRelative(timeStamp,0); | |
1e722a63 | 1870 | corrA = (param->GetZLength(36)/(timeA*param->GetTSample()*(1.-ltime0A)-param->GetL1Delay()-0*param->GetZSigma()/param->GetDriftV()))/param->GetDriftV()-1; |
a23ba1c3 | 1871 | corrA-=corrPTA; |
1872 | } | |
1873 | if (graphC&&graphC->GetN()>0){ | |
1874 | AliTPCcalibDButil::GetNearest(graphC,timeStamp,dist,gry); | |
1875 | timeC=AliTPCcalibDButil::EvalGraphConst(graphC,timeStamp); | |
1876 | Int_t mtime=TMath::Nint((graphC->GetX()[0]+graphC->GetX()[graphC->GetN()-1])*0.5); | |
1877 | ltime0C = GetLaserTime0(run,mtime,TMath::Nint(deltaT),0); | |
1878 | if (driftCalib) corrPTC = driftCalib->GetPTRelative(timeStamp,0); | |
1e722a63 | 1879 | corrC = (param->GetZLength(54)/(timeC*param->GetTSample()*(1.-ltime0C)-param->GetL1Delay()-0*param->GetZSigma()/param->GetDriftV()))/param->GetDriftV()-1; |
a23ba1c3 | 1880 | corrC-=corrPTC; |
1881 | } | |
1882 | ||
1883 | if (side ==0 ) return corrA; | |
1884 | if (side ==1 ) return corrC; | |
1885 | Double_t corrM= (corrA+corrC)*0.5; | |
1886 | if (!graphA) corrM=corrC; | |
1887 | if (!graphC) corrM=corrA; | |
1888 | return corrM; | |
1889 | } | |
1890 | ||
1891 | ||
1892 | ||
1893 | ||
1894 | Int_t AliTPCcalibDButil::MakeRunList(Int_t startRun, Int_t stopRun){ | |
1895 | // | |
1896 | // VERY obscure method - we need something in framework | |
1897 | // Find the TPC runs with temperature OCDB entry | |
1898 | // cache the start and end of the run | |
1899 | // | |
1900 | AliCDBStorage* storage = AliCDBManager::Instance()->GetSpecificStorage("TPC/Calib/Temperature"); | |
1901 | if (!storage) storage = AliCDBManager::Instance()->GetDefaultStorage(); | |
1902 | if (!storage) return 0; | |
1903 | TString path=storage->GetURI(); | |
1904 | TString runsT; | |
1905 | { | |
1906 | TString command; | |
1907 | if (path.Contains("local")){ // find the list if local system | |
1908 | path.ReplaceAll("local://",""); | |
1909 | path+="TPC/Calib/Temperature"; | |
1910 | command=Form("ls %s | sed s/_/\\ /g | awk '{print \"r\"$2}' ",path.Data()); | |
1911 | } | |
1912 | runsT=gSystem->GetFromPipe(command); | |
1913 | } | |
1914 | TObjArray *arr= runsT.Tokenize("r"); | |
1915 | if (!arr) return 0; | |
1916 | // | |
1917 | TArrayI indexes(arr->GetEntries()); | |
1918 | TArrayI runs(arr->GetEntries()); | |
1919 | Int_t naccept=0; | |
1920 | {for (Int_t irun=0;irun<arr->GetEntries();irun++){ | |
1921 | Int_t irunN = atoi(arr->At(irun)->GetName()); | |
1922 | if (irunN<startRun) continue; | |
1923 | if (irunN>stopRun) continue; | |
1924 | runs[naccept]=irunN; | |
1925 | naccept++; | |
1926 | }} | |
1927 | fRuns.Set(naccept); | |
1928 | fRunsStart.Set(fRuns.fN); | |
1929 | fRunsStop.Set(fRuns.fN); | |
1930 | TMath::Sort(fRuns.fN, runs.fArray, indexes.fArray,kFALSE); | |
1931 | for (Int_t irun=0; irun<fRuns.fN; irun++) fRuns[irun]=runs[indexes[irun]]; | |
1932 | ||
1933 | // | |
1934 | AliCDBEntry * entry = 0; | |
1935 | {for (Int_t irun=0;irun<fRuns.fN; irun++){ | |
1936 | entry = AliCDBManager::Instance()->Get("TPC/Calib/Temperature",fRuns[irun]); | |
1937 | if (!entry) continue; | |
1938 | AliTPCSensorTempArray * tmpRun = dynamic_cast<AliTPCSensorTempArray*>(entry->GetObject()); | |
1939 | if (!tmpRun) continue; | |
1940 | fRunsStart[irun]=tmpRun->GetStartTime().GetSec(); | |
1941 | fRunsStop[irun]=tmpRun->GetEndTime().GetSec(); | |
1942 | // printf("irun\t%d\tRun\t%d\t%d\t%d\n",irun,fRuns[irun],tmpRun->GetStartTime().GetSec(),tmpRun->GetEndTime().GetSec()); | |
1943 | }} | |
1944 | return fRuns.fN; | |
1945 | } | |
1946 | ||
1947 | ||
1948 | Int_t AliTPCcalibDButil::FindRunTPC(Int_t itime, Bool_t debug){ | |
1949 | // | |
1950 | // binary search - find the run for given time stamp | |
1951 | // | |
1952 | Int_t index0 = TMath::BinarySearch(fRuns.fN, fRunsStop.fArray,itime); | |
1953 | Int_t index1 = TMath::BinarySearch(fRuns.fN, fRunsStart.fArray,itime); | |
1954 | Int_t cindex = -1; | |
1955 | for (Int_t index=index0; index<=index1; index++){ | |
1956 | if (fRunsStart[index]<=itime && fRunsStop[index]>=itime) cindex=index; | |
1957 | if (debug) { | |
1958 | printf("%d\t%d\t%d\n",fRuns[index], fRunsStart[index]-itime, fRunsStop[index]-itime); | |
1959 | } | |
1960 | } | |
1961 | if (cindex<0) cindex =(index0+index1)/2; | |
1962 | if (cindex<0) { | |
1963 | return 0; | |
1964 | } | |
1965 | return fRuns[cindex]; | |
1966 | } | |
1967 | ||
1968 | ||
1969 | ||
1970 | ||
1971 | ||
1972 | TGraph* AliTPCcalibDButil::FilterGraphMedian(TGraph * graph, Float_t sigmaCut,Double_t &medianY){ | |
1973 | // | |
1974 | // filter outlyer measurement | |
1975 | // Only points around median +- sigmaCut filtered | |
1976 | if (!graph) return 0; | |
1977 | Int_t kMinPoints=2; | |
1978 | Int_t npoints0 = graph->GetN(); | |
1979 | Int_t npoints=0; | |
1980 | Float_t rmsY=0; | |
1981 | Double_t *outx=new Double_t[npoints0]; | |
1982 | Double_t *outy=new Double_t[npoints0]; | |
1983 | // | |
1984 | // | |
1985 | if (npoints0<kMinPoints) return 0; | |
1986 | for (Int_t iter=0; iter<3; iter++){ | |
1987 | npoints=0; | |
1988 | for (Int_t ipoint=0; ipoint<npoints0; ipoint++){ | |
1989 | if (graph->GetY()[ipoint]==0) continue; | |
1990 | if (iter>0 &&TMath::Abs(graph->GetY()[ipoint]-medianY)>sigmaCut*rmsY) continue; | |
1991 | outx[npoints] = graph->GetX()[ipoint]; | |
1992 | outy[npoints] = graph->GetY()[ipoint]; | |
1993 | npoints++; | |
1994 | } | |
1995 | if (npoints<=1) break; | |
1996 | medianY =TMath::Median(npoints,outy); | |
1997 | rmsY =TMath::RMS(npoints,outy); | |
1998 | } | |
1999 | TGraph *graphOut=0; | |
2000 | if (npoints>1) graphOut= new TGraph(npoints,outx,outy); | |
2001 | return graphOut; | |
2002 | } | |
2003 | ||
2004 | ||
2005 | TGraph* AliTPCcalibDButil::FilterGraphMedianAbs(TGraph * graph, Float_t cut,Double_t &medianY){ | |
2006 | // | |
2007 | // filter outlyer measurement | |
2008 | // Only points around median +- cut filtered | |
2009 | if (!graph) return 0; | |
2010 | Int_t kMinPoints=2; | |
2011 | Int_t npoints0 = graph->GetN(); | |
2012 | Int_t npoints=0; | |
2013 | Float_t rmsY=0; | |
2014 | Double_t *outx=new Double_t[npoints0]; | |
2015 | Double_t *outy=new Double_t[npoints0]; | |
2016 | // | |
2017 | // | |
2018 | if (npoints0<kMinPoints) return 0; | |
2019 | for (Int_t iter=0; iter<3; iter++){ | |
2020 | npoints=0; | |
2021 | for (Int_t ipoint=0; ipoint<npoints0; ipoint++){ | |
2022 | if (graph->GetY()[ipoint]==0) continue; | |
2023 | if (iter>0 &&TMath::Abs(graph->GetY()[ipoint]-medianY)>cut) continue; | |
2024 | outx[npoints] = graph->GetX()[ipoint]; | |
2025 | outy[npoints] = graph->GetY()[ipoint]; | |
2026 | npoints++; | |
2027 | } | |
2028 | if (npoints<=1) break; | |
2029 | medianY =TMath::Median(npoints,outy); | |
2030 | rmsY =TMath::RMS(npoints,outy); | |
2031 | } | |
2032 | TGraph *graphOut=0; | |
2033 | if (npoints>1) graphOut= new TGraph(npoints,outx,outy); | |
2034 | return graphOut; | |
2035 | } | |
2036 | ||
2037 | ||
2038 | ||
2039 | TGraphErrors* AliTPCcalibDButil::FilterGraphMedianErr(TGraphErrors * graph, Float_t sigmaCut,Double_t &medianY){ | |
2040 | // | |
2041 | // filter outlyer measurement | |
2042 | // Only points with normalized errors median +- sigmaCut filtered | |
2043 | // | |
2044 | Int_t kMinPoints=10; | |
2045 | Int_t npoints0 = graph->GetN(); | |
2046 | Int_t npoints=0; | |
2047 | Float_t medianErr=0, rmsErr=0; | |
2048 | Double_t *outx=new Double_t[npoints0]; | |
2049 | Double_t *outy=new Double_t[npoints0]; | |
2050 | Double_t *erry=new Double_t[npoints0]; | |
2051 | Double_t *nerry=new Double_t[npoints0]; | |
2052 | Double_t *errx=new Double_t[npoints0]; | |
2053 | // | |
2054 | // | |
2055 | if (npoints0<kMinPoints) return 0; | |
2056 | for (Int_t iter=0; iter<3; iter++){ | |
2057 | npoints=0; | |
2058 | for (Int_t ipoint=0; ipoint<npoints0; ipoint++){ | |
2059 | nerry[npoints] = graph->GetErrorY(ipoint); | |
2060 | if (iter>0 &&TMath::Abs(nerry[npoints]-medianErr)>sigmaCut*rmsErr) continue; | |
2061 | erry[npoints] = graph->GetErrorY(ipoint); | |
2062 | outx[npoints] = graph->GetX()[ipoint]; | |
2063 | outy[npoints] = graph->GetY()[ipoint]; | |
2064 | errx[npoints] = graph->GetErrorY(ipoint); | |
2065 | npoints++; | |
2066 | } | |
2067 | if (npoints==0) break; | |
2068 | medianErr=TMath::Median(npoints,erry); | |
2069 | medianY =TMath::Median(npoints,outy); | |
2070 | rmsErr =TMath::RMS(npoints,erry); | |
2071 | } | |
2072 | TGraphErrors *graphOut=0; | |
2073 | if (npoints>1) graphOut= new TGraphErrors(npoints,outx,outy,errx,erry); | |
2074 | delete []outx; | |
2075 | delete []outy; | |
2076 | delete []errx; | |
2077 | delete []erry; | |
2078 | return graphOut; | |
2079 | } | |
2080 | ||
2081 | ||
2082 | void AliTPCcalibDButil::Sort(TGraph *graph){ | |
2083 | // | |
2084 | // sort array - neccessay for approx | |
2085 | // | |
2086 | Int_t npoints = graph->GetN(); | |
2087 | Int_t *indexes=new Int_t[npoints]; | |
2088 | Double_t *outx=new Double_t[npoints]; | |
2089 | Double_t *outy=new Double_t[npoints]; | |
2090 | TMath::Sort(npoints, graph->GetX(),indexes,kFALSE); | |
2091 | for (Int_t i=0;i<npoints;i++) outx[i]=graph->GetX()[indexes[i]]; | |
2092 | for (Int_t i=0;i<npoints;i++) outy[i]=graph->GetY()[indexes[i]]; | |
2093 | for (Int_t i=0;i<npoints;i++) graph->GetX()[i]=outx[i]; | |
2094 | for (Int_t i=0;i<npoints;i++) graph->GetY()[i]=outy[i]; | |
2095 | ||
2096 | } | |
2097 | void AliTPCcalibDButil::SmoothGraph(TGraph *graph, Double_t delta){ | |
2098 | // | |
2099 | // smmoth graph - mean on the interval | |
2100 | // | |
2101 | Sort(graph); | |
2102 | Int_t npoints = graph->GetN(); | |
2103 | Double_t *outy=new Double_t[npoints]; | |
0d1b4cf8 | 2104 | |
a23ba1c3 | 2105 | for (Int_t ipoint=0; ipoint<npoints; ipoint++){ |
2106 | Double_t lx=graph->GetX()[ipoint]; | |
2107 | Int_t index0=TMath::BinarySearch(npoints, graph->GetX(),lx-delta); | |
2108 | Int_t index1=TMath::BinarySearch(npoints, graph->GetX(),lx+delta); | |
2109 | if (index0<0) index0=0; | |
2110 | if (index1>=npoints-1) index1=npoints-1; | |
2111 | if ((index1-index0)>1){ | |
2112 | outy[ipoint] = TMath::Mean(index1-index0, &(graph->GetY()[index0])); | |
2113 | }else{ | |
2114 | outy[ipoint]=graph->GetY()[ipoint]; | |
2115 | } | |
2116 | } | |
0d1b4cf8 | 2117 | // TLinearFitter fitter(3,"pol2"); |
2118 | // for (Int_t ipoint=0; ipoint<npoints; ipoint++){ | |
2119 | // Double_t lx=graph->GetX()[ipoint]; | |
2120 | // Int_t index0=TMath::BinarySearch(npoints, graph->GetX(),lx-delta); | |
2121 | // Int_t index1=TMath::BinarySearch(npoints, graph->GetX(),lx+delta); | |
2122 | // if (index0<0) index0=0; | |
2123 | // if (index1>=npoints-1) index1=npoints-1; | |
2124 | // fitter.ClearPoints(); | |
2125 | // for (Int_t jpoint=0;jpoint<index1-index0; jpoint++) | |
2126 | // if ((index1-index0)>1){ | |
2127 | // outy[ipoint] = TMath::Mean(index1-index0, &(graph->GetY()[index0])); | |
2128 | // }else{ | |
2129 | // outy[ipoint]=graph->GetY()[ipoint]; | |
2130 | // } | |
2131 | // } | |
2132 | ||
2133 | ||
2134 | ||
a23ba1c3 | 2135 | for (Int_t ipoint=0; ipoint<npoints; ipoint++){ |
2136 | graph->GetY()[ipoint] = outy[ipoint]; | |
2137 | } | |
2138 | delete[] outy; | |
2139 | } | |
2140 | ||
2141 | Double_t AliTPCcalibDButil::EvalGraphConst(TGraph *graph, Double_t xref){ | |
2142 | // | |
2143 | // Use constant interpolation outside of range | |
2144 | // | |
2145 | if (!graph) { | |
2146 | printf("AliTPCcalibDButil::EvalGraphConst: 0 pointer\n"); | |
2147 | return 0; | |
2148 | } | |
2149 | if (graph->GetN()<1){ | |
2150 | printf("AliTPCcalibDButil::EvalGraphConst: Empty graph"); | |
2151 | return 0; | |
2152 | } | |
2153 | if (xref<graph->GetX()[0]) return graph->GetY()[0]; | |
2154 | if (xref>graph->GetX()[graph->GetN()-1]) return graph->GetY()[graph->GetN()-1]; | |
2155 | return graph->Eval( xref); | |
2156 | } | |
2157 | ||
1e722a63 | 2158 | Float_t AliTPCcalibDButil::FilterSensor(AliDCSSensor * sensor, Double_t ymin, Double_t ymax, Double_t maxdy, Double_t sigmaCut){ |
2159 | // | |
2160 | // Filter DCS sensor information | |
2161 | // ymin - minimal value | |
2162 | // ymax - max value | |
2163 | // maxdy - maximal deirivative | |
2164 | // sigmaCut - cut on values and derivative in terms of RMS distribution | |
2165 | // Return value - accepted fraction | |
2166 | // | |
2167 | // Algorithm: | |
2168 | // | |
2169 | // 0. Calculate median and rms of values in specified range | |
2170 | // 1. Filter out outliers - median+-sigmaCut*rms | |
2171 | // values replaced by median | |
2172 | // | |
2173 | AliSplineFit * fit = sensor->GetFit(); | |
2174 | if (!fit) return 0.; | |
2175 | Int_t nknots = fit->GetKnots(); | |
2176 | if (nknots==0) { | |
2177 | delete fit; | |
2178 | sensor->SetFit(0); | |
2179 | return 0; | |
2180 | } | |
2181 | // | |
2182 | Double_t *yin0 = new Double_t[nknots]; | |
2183 | Double_t *yin1 = new Double_t[nknots]; | |
2184 | Int_t naccept=0; | |
2185 | ||
2186 | for (Int_t iknot=0; iknot< nknots; iknot++){ | |
2187 | if (fit->GetY0()[iknot]>ymin && fit->GetY0()[iknot]<ymax){ | |
2188 | yin0[naccept] = fit->GetY0()[iknot]; | |
2189 | yin1[naccept] = fit->GetY1()[iknot]; | |
2190 | if (TMath::Abs(fit->GetY1()[iknot])>maxdy) yin1[naccept]=0; | |
2191 | naccept++; | |
2192 | } | |
2193 | } | |
2194 | if (naccept<1) { | |
2195 | delete fit; | |
2196 | sensor->SetFit(0); | |
2197 | return 0.; | |
2198 | } | |
0d1b4cf8 | 2199 | |
1e722a63 | 2200 | Double_t medianY0=0, medianY1=0; |
2201 | Double_t rmsY0 =0, rmsY1=0; | |
2202 | medianY0 = TMath::Median(naccept, yin0); | |
2203 | medianY1 = TMath::Median(naccept, yin1); | |
2204 | rmsY0 = TMath::RMS(naccept, yin0); | |
2205 | rmsY1 = TMath::RMS(naccept, yin1); | |
2206 | naccept=0; | |
2207 | // | |
2208 | // 1. Filter out outliers - median+-sigmaCut*rms | |
2209 | // values replaced by median | |
2210 | // if replaced the derivative set to 0 | |
2211 | // | |
2212 | for (Int_t iknot=0; iknot< nknots; iknot++){ | |
2213 | Bool_t isOK=kTRUE; | |
2214 | if (TMath::Abs(fit->GetY0()[iknot]-medianY0)>sigmaCut*rmsY0) isOK=kFALSE; | |
2215 | if (TMath::Abs(fit->GetY1()[iknot]-medianY1)>sigmaCut*rmsY1) isOK=kFALSE; | |
2216 | if (nknots<2) fit->GetY1()[iknot]=0; | |
2217 | if (TMath::Abs(fit->GetY1()[iknot])>maxdy) fit->GetY1()[iknot]=0; | |
2218 | if (!isOK){ | |
2219 | fit->GetY0()[iknot]=medianY0; | |
2220 | fit->GetY1()[iknot]=0; | |
2221 | }else{ | |
2222 | naccept++; | |
2223 | } | |
2224 | } | |
2225 | delete [] yin0; | |
2226 | delete [] yin1; | |
2227 | return Float_t(naccept)/Float_t(nknots); | |
2228 | } | |
2229 | ||
2230 | Float_t AliTPCcalibDButil::FilterTemperature(AliTPCSensorTempArray *tempArray, Double_t ymin, Double_t ymax, Double_t sigmaCut){ | |
2231 | // | |
2232 | // Filter temperature array | |
2233 | // tempArray - array of temperatures - | |
2234 | // ymin - minimal accepted temperature - default 15 | |
2235 | // ymax - maximal accepted temperature - default 22 | |
2236 | // sigmaCut - values filtered on interval median+-sigmaCut*rms - defaut 5 | |
2237 | // return value - fraction of filtered sensors | |
2238 | const Double_t kMaxDy=0.1; | |
2239 | Int_t nsensors=tempArray->NumSensors(); | |
2240 | if (nsensors==0) return 0.; | |
2241 | Int_t naccept=0; | |
2242 | for (Int_t isensor=0; isensor<nsensors; isensor++){ | |
2243 | AliDCSSensor *sensor = tempArray->GetSensorNum(isensor); | |
2244 | if (!sensor) continue; | |
2245 | //printf("%d\n",isensor); | |
2246 | FilterSensor(sensor,ymin,ymax,kMaxDy, sigmaCut); | |
2247 | if (sensor->GetFit()==0){ | |
0d1b4cf8 | 2248 | //delete sensor; |
1e722a63 | 2249 | tempArray->RemoveSensorNum(isensor); |
2250 | }else{ | |
2251 | naccept++; | |
2252 | } | |
2253 | } | |
2254 | return Float_t(naccept)/Float_t(nsensors); | |
2255 | } | |
2256 | ||
a23ba1c3 | 2257 | |
2258 | void AliTPCcalibDButil::FilterCE(Double_t deltaT, Double_t cutAbs, Double_t cutSigma, TTreeSRedirector *pcstream){ | |
2259 | // | |
2260 | // Filter CE data | |
1e722a63 | 2261 | // Input parameters: |
2262 | // deltaT - smoothing window (in seconds) | |
2263 | // cutAbs - max distance of the time info to the median (in time bins) | |
2264 | // cutSigma - max distance (in the RMS) | |
2265 | // pcstream - optional debug streamer to store original and filtered info | |
2266 | // Hardwired parameters: | |
2267 | // kMinPoints =10; // minimal number of points to define the CE | |
2268 | // kMinSectors=12; // minimal number of sectors to define sideCE | |
2269 | // Algorithm: | |
2270 | // 0. Filter almost emty graphs (kMinPoints=10) | |
2271 | // 1. calculate median and RMS per side | |
2272 | // 2. Filter graphs - in respect with side medians | |
2273 | // - cutAbs and cutDelta used | |
2274 | // 3. Cut in respect wit the graph median - cutAbs and cutRMS used | |
2275 | // 4. Calculate mean for A side and C side | |
2276 | // | |
2277 | const Int_t kMinPoints =10; // minimal number of points to define the CE | |
2278 | const Int_t kMinSectors=12; // minimal number of sectors to define sideCE | |
2279 | const Int_t kMinTime =400; // minimal arrival time of CE | |
2280 | TObjArray *arrT=AliTPCcalibDB::Instance()->GetCErocTtime(); | |
a23ba1c3 | 2281 | Double_t medianY=0; |
1e722a63 | 2282 | TObjArray* cearray =AliTPCcalibDB::Instance()->GetCEData(); |
a23ba1c3 | 2283 | if (!cearray) return; |
1e722a63 | 2284 | Double_t tmin=-1; |
2285 | Double_t tmax=-1; | |
2286 | // | |
2287 | // | |
a23ba1c3 | 2288 | AliTPCSensorTempArray *tempMapCE = (AliTPCSensorTempArray *)cearray->FindObject("TempMap"); |
2289 | AliDCSSensor * cavernPressureCE = (AliDCSSensor *) cearray->FindObject("CavernPressure"); | |
2290 | if ( tempMapCE && cavernPressureCE){ | |
1e722a63 | 2291 | // |
2292 | Bool_t isOK = FilterTemperature(tempMapCE)>0.1; | |
2293 | FilterSensor(cavernPressureCE,960,1050,10, 5.); | |
2294 | if (cavernPressureCE->GetFit()==0) isOK=kFALSE; | |
2295 | if (isOK) { | |
2296 | // recalculate P/T correction map for time of the CE | |
2297 | AliTPCCalibVdrift * driftCalib = new AliTPCCalibVdrift(tempMapCE,cavernPressureCE ,0); | |
2298 | driftCalib->SetName("driftPTCE"); | |
2299 | driftCalib->SetTitle("driftPTCE"); | |
2300 | cearray->AddLast(driftCalib); | |
2301 | } | |
a23ba1c3 | 2302 | } |
1e722a63 | 2303 | // |
2304 | // 0. Filter almost emty graphs | |
2305 | // | |
a23ba1c3 | 2306 | |
1e722a63 | 2307 | for (Int_t i=0; i<72;i++){ |
a23ba1c3 | 2308 | TGraph *graph= (TGraph*)arrT->At(i); |
2309 | if (!graph) continue; | |
2310 | if (graph->GetN()<kMinPoints){ | |
2311 | arrT->AddAt(0,i); | |
2312 | delete graph; // delete empty graph | |
2313 | continue; | |
2314 | } | |
1e722a63 | 2315 | if (tmin<0) tmin = graph->GetX()[0]; |
2316 | if (tmax<0) tmax = graph->GetX()[graph->GetN()-1]; | |
2317 | // | |
2318 | if (tmin>graph->GetX()[0]) tmin=graph->GetX()[0]; | |
2319 | if (tmax<graph->GetX()[graph->GetN()-1]) tmax=graph->GetX()[graph->GetN()-1]; | |
2320 | } | |
2321 | // | |
2322 | // 1. calculate median and RMS per side | |
2323 | // | |
2324 | TArrayF arrA(100000), arrC(100000); | |
2325 | Int_t nA=0, nC=0; | |
2326 | Double_t medianA=0, medianC=0; | |
2327 | Double_t rmsA=0, rmsC=0; | |
2328 | for (Int_t isec=0; isec<72;isec++){ | |
2329 | TGraph *graph= (TGraph*)arrT->At(isec); | |
2330 | if (!graph) continue; | |
2331 | for (Int_t ipoint=kMinPoints-1; ipoint<graph->GetN();ipoint++){ | |
2332 | if (graph->GetY()[ipoint]<kMinTime) continue; | |
2333 | if (nA>=arrA.fN) arrA.Set(nA*2); | |
2334 | if (nC>=arrC.fN) arrC.Set(nC*2); | |
2335 | if (isec%36<18) arrA[nA++]= graph->GetY()[ipoint]; | |
2336 | if (isec%36>=18) arrC[nC++]= graph->GetY()[ipoint]; | |
2337 | } | |
2338 | } | |
2339 | if (nA>0){ | |
2340 | medianA=TMath::Median(nA,arrA.fArray); | |
2341 | rmsA =TMath::RMS(nA,arrA.fArray); | |
2342 | } | |
2343 | if (nC>0){ | |
2344 | medianC=TMath::Median(nC,arrC.fArray); | |
2345 | rmsC =TMath::RMS(nC,arrC.fArray); | |
2346 | } | |
2347 | // | |
2348 | // 2. Filter graphs - in respect with side medians | |
2349 | // | |
2350 | TArrayD vecX(100000), vecY(100000); | |
2351 | for (Int_t isec=0; isec<72;isec++){ | |
2352 | TGraph *graph= (TGraph*)arrT->At(isec); | |
2353 | if (!graph) continue; | |
2354 | Double_t median = (isec%36<18) ? medianA: medianC; | |
2355 | Double_t rms = (isec%36<18) ? rmsA: rmsC; | |
2356 | Int_t naccept=0; | |
2357 | for (Int_t ipoint=kMinPoints-1; ipoint<graph->GetN();ipoint++){ | |
2358 | if (TMath::Abs(graph->GetY()[ipoint]-median)>cutAbs) continue; | |
2359 | if (TMath::Abs(graph->GetY()[ipoint]-median)>cutSigma*rms) continue; | |
2360 | vecX[naccept]= graph->GetX()[ipoint]; | |
2361 | vecY[naccept]= graph->GetY()[ipoint]; | |
2362 | naccept++; | |
2363 | } | |
2364 | if (naccept<kMinPoints){ | |
2365 | arrT->AddAt(0,isec); | |
2366 | delete graph; // delete empty graph | |
2367 | continue; | |
2368 | } | |
2369 | TGraph *graph2 = new TGraph(naccept, vecX.fArray, vecY.fArray); | |
2370 | delete graph; | |
2371 | arrT->AddAt(graph2,isec); | |
2372 | } | |
2373 | // | |
2374 | // 3. Cut in respect wit the graph median | |
2375 | // | |
2376 | for (Int_t i=0; i<72;i++){ | |
2377 | TGraph *graph= (TGraph*)arrT->At(i); | |
2378 | if (!graph) continue; | |
2379 | // | |
2380 | // filter in range | |
2381 | // | |
2382 | TGraph* graphTS0= FilterGraphMedianAbs(graph,cutAbs,medianY); | |
a23ba1c3 | 2383 | if (!graphTS0) continue; |
2384 | if (graphTS0->GetN()<kMinPoints) { | |
2385 | delete graphTS0; | |
2386 | delete graph; | |
2387 | arrT->AddAt(0,i); | |
2388 | continue; | |
2389 | } | |
1e722a63 | 2390 | TGraph* graphTS= FilterGraphMedian(graphTS0,cutSigma,medianY); |
a23ba1c3 | 2391 | graphTS->Sort(); |
2392 | AliTPCcalibDButil::SmoothGraph(graphTS,deltaT); | |
2393 | if (pcstream){ | |
2394 | Int_t run = AliTPCcalibDB::Instance()->GetRun(); | |
2395 | (*pcstream)<<"filterCE"<< | |
2396 | "run="<<run<< | |
2397 | "isec="<<i<< | |
2398 | "mY="<<medianY<< | |
2399 | "graph.="<<graph<< | |
2400 | "graphTS0.="<<graphTS0<< | |
2401 | "graphTS.="<<graphTS<< | |
2402 | "\n"; | |
2403 | } | |
2404 | delete graphTS0; | |
2405 | if (!graphTS) continue; | |
2406 | arrT->AddAt(graphTS,i); | |
2407 | delete graph; | |
2408 | } | |
1e722a63 | 2409 | // |
2410 | // Recalculate the mean time A side C side | |
2411 | // | |
2412 | TArrayF xA(200), yA(200), eA(200), xC(200),yC(200), eC(200); | |
2413 | Int_t meanPoints=(nA+nC)/72; // mean number of points | |
2414 | for (Int_t itime=0; itime<200; itime++){ | |
2415 | nA=0, nC=0; | |
2416 | Double_t time=tmin+(tmax-tmin)*Float_t(itime)/200.; | |
2417 | for (Int_t i=0; i<72;i++){ | |
2418 | TGraph *graph= (TGraph*)arrT->At(i); | |
2419 | if (!graph) continue; | |
2420 | if (graph->GetN()<(meanPoints/4)) continue; | |
2421 | if ( (i%36)<18 ) arrA[nA++]=graph->Eval(time); | |
2422 | if ( (i%36)>=18 ) arrC[nC++]=graph->Eval(time); | |
2423 | } | |
2424 | xA[itime]=time; | |
2425 | xC[itime]=time; | |
2426 | yA[itime]=(nA>0)? TMath::Mean(nA,arrA.fArray):0; | |
2427 | yC[itime]=(nC>0)? TMath::Mean(nC,arrC.fArray):0; | |
2428 | eA[itime]=(nA>0)? TMath::RMS(nA,arrA.fArray):0; | |
2429 | eC[itime]=(nC>0)? TMath::RMS(nC,arrC.fArray):0; | |
2430 | } | |
2431 | // | |
2432 | Double_t rmsTA = TMath::RMS(200,yA.fArray)+TMath::Mean(200,eA.fArray); | |
2433 | Double_t rmsTC = TMath::RMS(200,yC.fArray)+TMath::Mean(200,eC.fArray); | |
2434 | if (pcstream){ | |
2435 | Int_t run = AliTPCcalibDB::Instance()->GetRun(); | |
2436 | (*pcstream)<<"filterAC"<< | |
2437 | "run="<<run<< | |
2438 | "nA="<<nA<< | |
2439 | "nC="<<nC<< | |
2440 | "rmsTA="<<rmsTA<< | |
2441 | "rmsTC="<<rmsTC<< | |
2442 | "\n"; | |
2443 | } | |
2444 | // | |
2445 | TGraphErrors *grA = new TGraphErrors(200,xA.fArray,yA.fArray,0, eA.fArray); | |
2446 | TGraphErrors *grC = new TGraphErrors(200,xC.fArray,yC.fArray,0, eC.fArray); | |
2447 | TGraph* graphTSA= FilterGraphMedian(grA,cutSigma,medianY); | |
2448 | if (graphTSA&&graphTSA->GetN()) SmoothGraph(graphTSA,deltaT); | |
2449 | TGraph* graphTSC= FilterGraphMedian(grC,cutSigma,medianY); | |
2450 | if (graphTSC&&graphTSC->GetN()>0) SmoothGraph(graphTSC,deltaT); | |
2451 | delete grA; | |
2452 | delete grC; | |
2453 | if (nA<kMinSectors) arrT->AddAt(0,72); | |
2454 | else arrT->AddAt(graphTSA,72); | |
2455 | if (nC<kMinSectors) arrT->AddAt(0,73); | |
2456 | else arrT->AddAt(graphTSC,73); | |
a23ba1c3 | 2457 | } |
2458 | ||
2459 | ||
2460 | void AliTPCcalibDButil::FilterTracks(Int_t run, Double_t cutSigma, TTreeSRedirector *pcstream){ | |
2461 | // | |
2462 | // Filter Drift velocity measurement using the tracks | |
2463 | // 0. remove outlyers - error based | |
2464 | // cutSigma | |
2465 | // | |
2466 | // | |
2467 | const Int_t kMinPoints=1; // minimal number of points to define value | |
2468 | TObjArray *arrT=AliTPCcalibDB::Instance()->GetTimeVdriftSplineRun(run); | |
2469 | Double_t medianY=0; | |
2470 | if (!arrT) return; | |
2471 | for (Int_t i=0; i<arrT->GetEntries();i++){ | |
2472 | TGraphErrors *graph= (TGraphErrors*)arrT->At(i); | |
2473 | if (!graph) continue; | |
2474 | if (graph->GetN()<kMinPoints){ | |
2475 | delete graph; | |
2476 | arrT->AddAt(0,i); | |
2477 | continue; | |
2478 | } | |
2479 | TGraphErrors *graph2= FilterGraphMedianErr(graph,cutSigma,medianY); | |
2480 | if (!graph2) { | |
2481 | delete graph; arrT->AddAt(0,i); continue; | |
2482 | } | |
2483 | if (graph2->GetN()<1) { | |
2484 | delete graph; arrT->AddAt(0,i); continue; | |
2485 | } | |
2486 | graph2->SetName(graph->GetName()); | |
2487 | graph2->SetTitle(graph->GetTitle()); | |
2488 | arrT->AddAt(graph2,i); | |
2489 | if (pcstream){ | |
2490 | (*pcstream)<<"filterTracks"<< | |
2491 | "run="<<run<< | |
2492 | "isec="<<i<< | |
2493 | "mY="<<medianY<< | |
2494 | "graph.="<<graph<< | |
2495 | "graph2.="<<graph2<< | |
2496 | "\n"; | |
2497 | } | |
2498 | delete graph; | |
2499 | } | |
2500 | } | |
2501 | ||
2502 | ||
a23ba1c3 | 2503 | |
2504 | ||
2505 | ||
2506 | Double_t AliTPCcalibDButil::GetLaserTime0(Int_t run, Int_t timeStamp, Int_t deltaT, Int_t side){ | |
2507 | // | |
2508 | // | |
2509 | // get laser time offset | |
2510 | // median around timeStamp+-deltaT | |
2511 | // QA - chi2 needed for later usage - to be added | |
2512 | // - currently cut on error | |
2513 | // | |
2514 | Int_t kMinPoints=1; | |
2515 | Double_t kMinDelay=0.01; | |
2516 | Double_t kMinDelayErr=0.0001; | |
2517 | ||
2518 | TObjArray *array =AliTPCcalibDB::Instance()->GetTimeVdriftSplineRun(run); | |
2519 | if (!array) return 0; | |
2520 | TGraphErrors *tlaser=0; | |
2521 | if (array){ | |
2522 | if (side==0) tlaser=(TGraphErrors*)array->FindObject("GRAPH_MEAN_DELAY_LASER_ALL_A"); | |
2523 | if (side==1) tlaser=(TGraphErrors*)array->FindObject("GRAPH_MEAN_DELAY_LASER_ALL_C"); | |
2524 | } | |
2525 | if (!tlaser) return 0; | |
2526 | Int_t npoints0= tlaser->GetN(); | |
2527 | if (npoints0==0) return 0; | |
2528 | Double_t *xlaser = new Double_t[npoints0]; | |
2529 | Double_t *ylaser = new Double_t[npoints0]; | |
2530 | Int_t npoints=0; | |
2531 | for (Int_t i=0;i<npoints0;i++){ | |
2532 | //printf("%d\n",i); | |
2533 | if (tlaser->GetY()[i]<=kMinDelay) continue; // filter zeros | |
2534 | if (tlaser->GetErrorY(i)>TMath::Abs(kMinDelayErr)) continue; | |
2535 | xlaser[npoints]=tlaser->GetX()[npoints]; | |
2536 | ylaser[npoints]=tlaser->GetY()[npoints]; | |
2537 | npoints++; | |
2538 | } | |
2539 | // | |
2540 | // | |
2541 | Int_t index0=TMath::BinarySearch(npoints, xlaser, Double_t(timeStamp-deltaT))-1; | |
2542 | Int_t index1=TMath::BinarySearch(npoints, xlaser, Double_t(timeStamp+deltaT))+1; | |
2543 | //if (index1-index0 <kMinPoints) { index1+=kMinPoints; index0-=kMinPoints;} | |
2544 | if (index0<0) index0=0; | |
2545 | if (index1>=npoints-1) index1=npoints-1; | |
2546 | if (index1-index0<kMinPoints) return 0; | |
2547 | // | |
2548 | //Double_t median = TMath::Median(index1-index0, &(ylaser[index0])); | |
2549 | Double_t mean = TMath::Mean(index1-index0, &(ylaser[index0])); | |
2550 | delete [] ylaser; | |
2551 | delete [] xlaser; | |
2552 | return mean; | |
2553 | } | |
0d1b4cf8 | 2554 | |
2555 | ||
2556 | ||
2557 | ||
1fabc823 | 2558 | void AliTPCcalibDButil::FilterGoofie(AliDCSSensorArray * goofieArray, Double_t deltaT, Double_t cutSigma, Double_t minVd, Double_t maxVd, TTreeSRedirector *pcstream){ |
0d1b4cf8 | 2559 | // |
2560 | // Filter Goofie data | |
1fabc823 | 2561 | // goofieArray - points will be filtered |
2562 | // deltaT - smmothing time window | |
2563 | // cutSigma - outler sigma cut in rms | |
2564 | // minVn, maxVd- range absolute cut for variable vd/pt | |
2565 | // - to be tuned | |
0d1b4cf8 | 2566 | // |
0d1b4cf8 | 2567 | // Ignore goofie if not enough points |
2568 | // | |
2569 | const Int_t kMinPoints = 3; | |
2570 | // | |
2571 | ||
2572 | TGraph *graphvd = goofieArray->GetSensorNum(2)->GetGraph(); | |
2573 | TGraph *graphan = goofieArray->GetSensorNum(8)->GetGraph(); | |
2574 | TGraph *graphaf = goofieArray->GetSensorNum(9)->GetGraph(); | |
2575 | TGraph *graphpt = goofieArray->GetSensorNum(15)->GetGraph(); | |
2576 | if (!graphvd) return; | |
2577 | if (graphvd->GetN()<kMinPoints){ | |
2578 | delete graphvd; | |
2579 | goofieArray->GetSensorNum(2)->SetGraph(0); | |
2580 | return; | |
2581 | } | |
2582 | // | |
2583 | // 1. Caluclate medians of critical variables | |
2584 | // drift velcocity | |
2585 | // P/T | |
2586 | // area near peak | |
2587 | // area far peak | |
2588 | // | |
2589 | Double_t medianpt=0; | |
1fabc823 | 2590 | Double_t medianvd=0, sigmavd=0; |
0d1b4cf8 | 2591 | Double_t medianan=0; |
2592 | Double_t medianaf=0; | |
1fabc823 | 2593 | Int_t entries=graphvd->GetN(); |
2594 | Double_t yvdn[10000]; | |
2595 | Int_t nvd=0; | |
2596 | // | |
2597 | for (Int_t ipoint=0; ipoint<entries; ipoint++){ | |
2598 | if (graphpt->GetY()[ipoint]<=0.0000001) continue; | |
2599 | if (graphvd->GetY()[ipoint]/graphpt->GetY()[ipoint]<minVd) continue; | |
2600 | if (graphvd->GetY()[ipoint]/graphpt->GetY()[ipoint]>maxVd) continue; | |
2601 | yvdn[nvd++]=graphvd->GetY()[ipoint]; | |
2602 | } | |
2603 | if (nvd<kMinPoints){ | |
2604 | delete graphvd; | |
2605 | goofieArray->GetSensorNum(2)->SetGraph(0); | |
2606 | return; | |
2607 | } | |
2608 | // | |
2609 | Int_t nuni = TMath::Min(TMath::Nint(nvd*0.4+2), nvd-1); | |
2610 | if (nuni>=kMinPoints){ | |
2611 | AliMathBase::EvaluateUni(nvd, yvdn, medianvd,sigmavd,nuni); | |
2612 | }else{ | |
2613 | medianvd = TMath::Median(nvd, yvdn); | |
2614 | } | |
2615 | ||
0d1b4cf8 | 2616 | TGraph * graphpt0 = AliTPCcalibDButil::FilterGraphMedianAbs(graphpt,10,medianpt); |
2617 | TGraph * graphpt1 = AliTPCcalibDButil::FilterGraphMedian(graphpt0,2,medianpt); | |
2618 | TGraph * graphan0 = AliTPCcalibDButil::FilterGraphMedianAbs(graphan,10,medianan); | |
2619 | TGraph * graphan1 = AliTPCcalibDButil::FilterGraphMedian(graphan0,2,medianan); | |
2620 | TGraph * graphaf0 = AliTPCcalibDButil::FilterGraphMedianAbs(graphaf,10,medianaf); | |
2621 | TGraph * graphaf1 = AliTPCcalibDButil::FilterGraphMedian(graphaf0,2,medianaf); | |
0d1b4cf8 | 2622 | delete graphpt0; |
2623 | delete graphpt1; | |
2624 | delete graphan0; | |
2625 | delete graphan1; | |
2626 | delete graphaf0; | |
2627 | delete graphaf1; | |
2628 | // | |
2629 | // 2. Make outlyer graph | |
2630 | // | |
1fabc823 | 2631 | Int_t nOK=0; |
0d1b4cf8 | 2632 | TGraph graphOut(*graphvd); |
2633 | for (Int_t i=0; i<entries;i++){ | |
2634 | // | |
2635 | Bool_t isOut=kFALSE; | |
1fabc823 | 2636 | if (graphpt->GetY()[i]<=0.0000001) { graphOut.GetY()[i]=1; continue;} |
2637 | if (graphvd->GetY()[i]/graphpt->GetY()[i]<minVd || graphvd->GetY()[i]/graphpt->GetY()[i]>maxVd) { graphOut.GetY()[i]=1; continue;} | |
2638 | ||
2639 | if (TMath::Abs((graphvd->GetY()[i]/graphpt->GetY()[i])/medianvd-1.)<0.05) | |
2640 | isOut|=kTRUE; | |
0d1b4cf8 | 2641 | if (TMath::Abs(graphpt->GetY()[i]/medianpt-1.)>0.02) isOut|=kTRUE; |
1fabc823 | 2642 | if (TMath::Abs(graphan->GetY()[i]/medianan-1.)>0.2) isOut|=kTRUE; |
2643 | if (TMath::Abs(graphaf->GetY()[i]/medianaf-1.)>0.2) isOut|=kTRUE; | |
0d1b4cf8 | 2644 | graphOut.GetY()[i]= (isOut)?1:0; |
1fabc823 | 2645 | if (!isOut) nOK++; |
0d1b4cf8 | 2646 | } |
1fabc823 | 2647 | if (nOK<kMinPoints) { |
2648 | delete graphvd; | |
2649 | goofieArray->GetSensorNum(2)->SetGraph(0); | |
2650 | return; | |
2651 | } | |
0d1b4cf8 | 2652 | // |
2653 | // 3. Filter out outlyers - and smooth | |
2654 | // | |
2655 | TVectorF vmedianArray(goofieArray->NumSensors()); | |
2656 | TVectorF vrmsArray(goofieArray->NumSensors()); | |
2657 | Double_t xnew[10000]; | |
2658 | Double_t ynew[10000]; | |
2659 | TObjArray junk; | |
2660 | junk.SetOwner(kTRUE); | |
2661 | Bool_t isOK=kTRUE; | |
2662 | // | |
2663 | // | |
2664 | for (Int_t isensor=0; isensor<goofieArray->NumSensors();isensor++){ | |
2665 | isOK=kTRUE; | |
2666 | AliDCSSensor *sensor = goofieArray->GetSensorNum(isensor); | |
2667 | TGraph *graphOld=0, *graphNew=0, * graphNew0=0,*graphNew1=0,*graphNew2=0; | |
2668 | // | |
2669 | if (!sensor) continue; | |
2670 | graphOld = sensor->GetGraph(); | |
2671 | if (graphOld) { | |
2672 | sensor->SetGraph(0); | |
2673 | Int_t nused=0; | |
2674 | for (Int_t i=0;i<entries;i++){ | |
2675 | if (graphOut.GetY()[i]>0.5) continue; | |
2676 | xnew[nused]=graphOld->GetX()[i]; | |
2677 | ynew[nused]=graphOld->GetY()[i]; | |
2678 | nused++; | |
2679 | } | |
2680 | graphNew = new TGraph(nused,xnew,ynew); | |
2681 | junk.AddLast(graphNew); | |
2682 | junk.AddLast(graphOld); | |
2683 | Double_t median=0; | |
2684 | graphNew0 = AliTPCcalibDButil::FilterGraphMedian(graphNew,cutSigma,median); | |
2685 | if (graphNew0!=0){ | |
2686 | junk.AddLast(graphNew0); | |
2687 | graphNew1 = AliTPCcalibDButil::FilterGraphMedian(graphNew0,cutSigma,median); | |
2688 | if (graphNew1!=0){ | |
1fabc823 | 2689 | junk.AddLast(graphNew1); |
0d1b4cf8 | 2690 | graphNew2 = AliTPCcalibDButil::FilterGraphMedian(graphNew1,cutSigma,median); |
2691 | if (graphNew2!=0) { | |
1fabc823 | 2692 | vrmsArray[isensor] =TMath::RMS(graphNew2->GetN(),graphNew2->GetY()); |
0d1b4cf8 | 2693 | AliTPCcalibDButil::SmoothGraph(graphNew2,deltaT); |
2694 | AliTPCcalibDButil::SmoothGraph(graphNew2,deltaT); | |
2695 | AliTPCcalibDButil::SmoothGraph(graphNew2,deltaT); | |
1fabc823 | 2696 | printf("%d\t%f\t%f\n",isensor, median,vrmsArray[isensor]); |
0d1b4cf8 | 2697 | vmedianArray[isensor]=median; |
0d1b4cf8 | 2698 | // |
2699 | } | |
2700 | } | |
2701 | } | |
2702 | } | |
2703 | if (!graphOld) { isOK=kFALSE; graphOld =&graphOut;} | |
2704 | if (!graphNew0) { isOK=kFALSE; graphNew0=graphOld;} | |
2705 | if (!graphNew1) { isOK=kFALSE; graphNew1=graphOld;} | |
2706 | if (!graphNew2) { isOK=kFALSE; graphNew2=graphOld;} | |
2707 | (*pcstream)<<"goofieA"<< | |
2708 | Form("isOK_%d.=",isensor)<<isOK<< | |
2709 | Form("s_%d.=",isensor)<<sensor<< | |
2710 | Form("gr_%d.=",isensor)<<graphOld<< | |
2711 | Form("gr0_%d.=",isensor)<<graphNew0<< | |
2712 | Form("gr1_%d.=",isensor)<<graphNew1<< | |
2713 | Form("gr2_%d.=",isensor)<<graphNew2; | |
1fabc823 | 2714 | if (isOK) sensor->SetGraph(graphNew2); |
2715 | } | |
2716 | (*pcstream)<<"goofieA"<< | |
2717 | "vmed.="<<&vmedianArray<< | |
2718 | "vrms.="<<&vrmsArray<< | |
2719 | "\n"; | |
2720 | junk.Delete(); // delete temoprary graphs | |
0d1b4cf8 | 2721 | |
2722 | } | |
2723 | ||
2724 |