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a42992b7 | 1 | /************************************************************************** |
2 | * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * | |
3 | * * | |
4 | * Author: The ALICE Off-line Project. * | |
5 | * Contributors are mentioned in the code where appropriate. * | |
6 | * * | |
7 | * Permission to use, copy, modify and distribute this software and its * | |
8 | * documentation strictly for non-commercial purposes is hereby granted * | |
9 | * without fee, provided that the above copyright notice appears in all * | |
10 | * copies and that both the copyright notice and this permission notice * | |
11 | * appear in the supporting documentation. The authors make no claims * | |
12 | * about the suitability of this software for any purpose. It is * | |
13 | * provided "as is" without express or implied warranty. * | |
14 | **************************************************************************/ | |
15 | ||
16 | /* $Id: AliEMCALCalibTimeDep.cxx $ */ | |
17 | ||
18 | //_________________________________________________________________________ | |
19 | ///*-- Author: | |
20 | /////////////////////////////////////////////////////////////////////////////// | |
21 | // // | |
0ce5c45d | 22 | // class for EMCAL time-dep calibration |
23 | // - supposed to run in preprocessor | |
24 | // we use input from the following sources: | |
ed3db319 | 25 | // AliEMCALCalibTempCoeff (APD temperature coefficients), |
0ce5c45d | 26 | // AliCaloCalibSignal (LED DA), AliEMCALSensorTempArray (ELMB DCS) |
27 | // AliEMCALCalibReference: LED amplitude and temperature info at reference time | |
28 | // | |
29 | // output/result is in AliEMCALCalibTimeDepCorrection | |
a42992b7 | 30 | // // |
31 | /////////////////////////////////////////////////////////////////////////////// | |
32 | ||
33 | #include <iostream> | |
34 | #include <TGraphSmooth.h> | |
e1a60af4 | 35 | #include <TMath.h> |
a42992b7 | 36 | #include "AliLog.h" |
37 | #include "AliCDBEntry.h" | |
38 | #include "AliCDBManager.h" | |
39 | #include "AliEMCALSensorTempArray.h" | |
d81e6423 | 40 | #include "AliCaloCalibSignal.h" |
ed3db319 | 41 | #include "AliEMCALCalibTempCoeff.h" |
82d90a2f | 42 | #include "AliEMCALCalibReference.h" |
d81e6423 | 43 | #include "AliEMCALCalibTimeDepCorrection.h" |
a42992b7 | 44 | #include "AliEMCALCalibTimeDep.h" |
45 | ||
46 | /* first a bunch of constants.. */ | |
0ce5c45d | 47 | const double kSecToHour = 1.0/3600.0; // conversion factor from seconds to hours |
a42992b7 | 48 | |
d81e6423 | 49 | // some global variables for APD handling; values from Catania studies, best fit |
50 | // TempCoeff = p0+p1*M (M=gain), where p0 and and p1 are functions of the dark current | |
0ce5c45d | 51 | const double kTempCoeffP0Const = -0.903; // |
52 | const double kTempCoeffP0Factor = -1.381e7; // | |
53 | const double kTempCoeffP1Const = -0.023; // | |
54 | const double kTempCoeffP1Factor = -4.966e5; // | |
d81e6423 | 55 | |
0ce5c45d | 56 | const double kErrorCode = -999; // to indicate that something went wrong |
621ff010 | 57 | |
a42992b7 | 58 | using namespace std; |
59 | ||
60 | ClassImp(AliEMCALCalibTimeDep) | |
61 | ||
62 | //________________________________________________________________ | |
63 | AliEMCALCalibTimeDep::AliEMCALCalibTimeDep() : | |
64 | fRun(0), | |
65 | fStartTime(0), | |
66 | fEndTime(0), | |
67 | fMinTemp(0), | |
68 | fMaxTemp(0), | |
716fca62 | 69 | fMinTempVariation(0), |
70 | fMaxTempVariation(0), | |
a42992b7 | 71 | fMinTime(0), |
72 | fMaxTime(0), | |
d81e6423 | 73 | fTemperatureResolution(0.1), // 0.1 deg C is default |
ed3db319 | 74 | fMaxTemperatureDiff(5), // 5 deg C is default max diff relative to reference |
d81e6423 | 75 | fTimeBinsPerHour(2), // 2 30-min bins per hour is default |
82d90a2f | 76 | fHighLowGainFactor(16), // factor ~16 between High gain and low gain |
d81e6423 | 77 | fTempArray(NULL), |
78 | fCalibSignal(NULL), | |
ed3db319 | 79 | fCalibTempCoeff(NULL), |
82d90a2f | 80 | fCalibReference(NULL), |
716fca62 | 81 | fCalibTimeDepCorrection(NULL), |
82 | fVerbosity(0) | |
a42992b7 | 83 | { |
84 | // Constructor | |
85 | } | |
86 | ||
87 | //________________________________________________________________ | |
88 | AliEMCALCalibTimeDep::AliEMCALCalibTimeDep(const AliEMCALCalibTimeDep& calibt) : | |
621ff010 | 89 | TObject(calibt), |
a42992b7 | 90 | fRun(calibt.GetRunNumber()), |
91 | fStartTime(calibt.GetStartTime()), | |
92 | fEndTime(calibt.GetEndTime()), | |
93 | fMinTemp(calibt.GetMinTemp()), | |
94 | fMaxTemp(calibt.GetMaxTemp()), | |
716fca62 | 95 | fMinTempVariation(calibt.GetMinTempVariation()), |
96 | fMaxTempVariation(calibt.GetMaxTempVariation()), | |
a42992b7 | 97 | fMinTime(calibt.GetMinTime()), |
98 | fMaxTime(calibt.GetMaxTime()), | |
d81e6423 | 99 | fTemperatureResolution(calibt.GetTemperatureResolution()), |
ed3db319 | 100 | fMaxTemperatureDiff(calibt.GetMaxTemperatureDiff()), |
d81e6423 | 101 | fTimeBinsPerHour(calibt.GetTimeBinsPerHour()), |
82d90a2f | 102 | fHighLowGainFactor(calibt.GetHighLowGainFactor()), |
d81e6423 | 103 | fTempArray(calibt.GetTempArray()), |
104 | fCalibSignal(calibt.GetCalibSignal()), | |
ed3db319 | 105 | fCalibTempCoeff(calibt.GetCalibTempCoeff()), |
82d90a2f | 106 | fCalibReference(calibt.GetCalibReference()), |
716fca62 | 107 | fCalibTimeDepCorrection(calibt.GetCalibTimeDepCorrection()), |
108 | fVerbosity(calibt.GetVerbosity()) | |
a42992b7 | 109 | { |
110 | // copy constructor | |
111 | } | |
112 | ||
113 | ||
114 | //________________________________________________________________ | |
115 | AliEMCALCalibTimeDep &AliEMCALCalibTimeDep::operator =(const AliEMCALCalibTimeDep& calibt) | |
116 | { | |
117 | // assignment operator; use copy ctor | |
118 | if (&calibt == this) return *this; | |
119 | ||
120 | new (this) AliEMCALCalibTimeDep(calibt); | |
121 | return *this; | |
122 | } | |
123 | ||
124 | //________________________________________________________________ | |
125 | AliEMCALCalibTimeDep::~AliEMCALCalibTimeDep() | |
126 | { | |
127 | // Destructor | |
128 | } | |
129 | ||
130 | //________________________________________________________________ | |
131 | void AliEMCALCalibTimeDep::Reset() | |
132 | { | |
133 | // clear variables to default | |
134 | fRun = 0; | |
135 | fStartTime = 0; | |
136 | fEndTime = 0; | |
137 | fMinTemp = 0; | |
138 | fMaxTemp = 0; | |
716fca62 | 139 | fMinTempVariation = 0; |
140 | fMaxTempVariation = 0; | |
a42992b7 | 141 | fMinTime = 0; |
142 | fMaxTime = 0; | |
d81e6423 | 143 | fTemperatureResolution = 0.1; // 0.1 deg C is default |
ed3db319 | 144 | fMaxTemperatureDiff = 5; // 5 deg C is default max diff relative to reference |
d81e6423 | 145 | fTimeBinsPerHour = 2; // 2 30-min bins per hour is default |
a42992b7 | 146 | fTempArray = NULL; |
d81e6423 | 147 | fCalibSignal = NULL; |
ed3db319 | 148 | fCalibTempCoeff = NULL; |
82d90a2f | 149 | fCalibReference = NULL; |
d81e6423 | 150 | fCalibTimeDepCorrection = NULL; |
716fca62 | 151 | fVerbosity = 0; |
a42992b7 | 152 | return; |
153 | } | |
154 | ||
155 | //________________________________________________________________ | |
621ff010 | 156 | void AliEMCALCalibTimeDep::PrintInfo() const |
a42992b7 | 157 | { |
158 | // print some info | |
d81e6423 | 159 | cout << endl << " AliEMCALCalibTimeDep::PrintInfo() " << endl; |
a42992b7 | 160 | // basic variables, all 'publicly available' also |
161 | cout << " VARIABLE DUMP: " << endl | |
162 | << " GetStartTime() " << GetStartTime() << endl | |
163 | << " GetEndTime() " << GetEndTime() << endl | |
716fca62 | 164 | << " GetMinTime() " << GetMinTime() << endl |
165 | << " GetMaxTime() " << GetMaxTime() << endl | |
a42992b7 | 166 | << " GetMinTemp() " << GetMinTemp() << endl |
716fca62 | 167 | << " GetMaxTemp() " << GetMaxTemp() << endl |
168 | << " GetMinTempVariation() " << GetMinTempVariation() << endl | |
169 | << " GetMaxTempVariation() " << GetMaxTempVariation() << endl; | |
a42992b7 | 170 | // run ranges |
171 | cout << " RUN INFO: " << endl | |
716fca62 | 172 | << " runnumber " << GetRunNumber() << endl |
a42992b7 | 173 | << " length (in hours) " << GetLengthOfRunInHours() << endl |
ed3db319 | 174 | << " length (in bins) " << GetLengthOfRunInBins() << endl |
a42992b7 | 175 | << " range of temperature measurements (in hours) " << GetRangeOfTempMeasureInHours() |
176 | << " (in deg. C) " << GetRangeOfTempMeasureInDegrees() | |
177 | << endl; | |
a42992b7 | 178 | |
179 | return; | |
180 | } | |
d81e6423 | 181 | |
a42992b7 | 182 | //________________________________________________________________ |
d81e6423 | 183 | Double_t AliEMCALCalibTimeDep::GetLengthOfRunInHours() const |
a42992b7 | 184 | { |
0ce5c45d | 185 | return (fEndTime - fStartTime)*kSecToHour; |
a42992b7 | 186 | } |
d81e6423 | 187 | |
188 | //________________________________________________________________ | |
189 | Double_t AliEMCALCalibTimeDep::GetLengthOfRunInBins() const | |
190 | { | |
0ce5c45d | 191 | return (fEndTime - fStartTime)*kSecToHour*fTimeBinsPerHour; |
d81e6423 | 192 | } |
193 | ||
a42992b7 | 194 | //________________________________________________________________ |
d81e6423 | 195 | Double_t AliEMCALCalibTimeDep::GetRangeOfTempMeasureInHours() const |
a42992b7 | 196 | { |
0ce5c45d | 197 | return (fMaxTime - fMinTime)*kSecToHour; |
a42992b7 | 198 | } |
d81e6423 | 199 | |
a42992b7 | 200 | //________________________________________________________________ |
d81e6423 | 201 | Double_t AliEMCALCalibTimeDep::GetRangeOfTempMeasureInDegrees() const |
a42992b7 | 202 | { |
203 | return (fMaxTemp - fMinTemp); | |
204 | } | |
205 | ||
206 | //________________________________________________________________ | |
207 | void AliEMCALCalibTimeDep::Initialize(Int_t run, | |
208 | UInt_t startTime, UInt_t endTime) | |
0ce5c45d | 209 | { // setup, and get temperature info |
a42992b7 | 210 | Reset(); // start fresh |
211 | ||
212 | fRun = run; | |
213 | fStartTime = startTime; | |
214 | fEndTime = endTime; | |
215 | ||
216 | // collect the needed information | |
217 | GetTemperatureInfo(); // temperature readings during the run | |
d81e6423 | 218 | ScanTemperatureInfo(); // see what the boundaries are (Min/Max Time/Temp) |
a42992b7 | 219 | |
220 | return; | |
221 | } | |
222 | ||
a42992b7 | 223 | //________________________________________________________________ |
d81e6423 | 224 | Double_t AliEMCALCalibTimeDep::GetTemperatureSM(int imod, UInt_t timeStamp) const |
a42992b7 | 225 | {// return estimate for this one SuperModule, if it had data |
226 | ||
227 | // first convert from seconds to hours.. | |
0ce5c45d | 228 | Double_t timeHour = (timeStamp - fStartTime) * kSecToHour; |
621ff010 | 229 | |
d81e6423 | 230 | Double_t average = 0; |
621ff010 | 231 | int n = 0; |
232 | ||
233 | for (int i=0; i<fTempArray->NumSensors(); i++) { | |
234 | ||
235 | AliEMCALSensorTemp *st = fTempArray->GetSensor(i); | |
236 | int module = st->GetSector()*2 + st->GetSide(); | |
237 | if ( module == imod ) { // right module | |
238 | // check if we had valid data for the time that is being asked for | |
239 | if ( timeStamp>=st->GetStartTime() && timeStamp<=st->GetEndTime() ) { | |
240 | AliSplineFit *f = st->GetFit(); | |
241 | if (f) { // ok, looks like we have valid data/info | |
242 | // let's check what the expected value at the time appears to be | |
d81e6423 | 243 | Double_t val = f->Eval(timeHour); |
716fca62 | 244 | if ( fVerbosity > 0 ) { |
245 | cout << " sensor i " << i << " val " << val << endl; | |
246 | } | |
621ff010 | 247 | average += val; |
248 | n++; | |
249 | } | |
250 | } // time | |
251 | } | |
252 | ||
253 | } // loop over fTempArray | |
254 | ||
255 | if (n>0) { // some valid data was found | |
256 | average /= n; | |
257 | return average; | |
258 | } | |
259 | else { // no good data | |
0ce5c45d | 260 | return kErrorCode; |
621ff010 | 261 | } |
a42992b7 | 262 | |
a42992b7 | 263 | } |
264 | ||
a42992b7 | 265 | //________________________________________________________________ |
d81e6423 | 266 | Int_t AliEMCALCalibTimeDep::CalcCorrection() |
267 | { // OK, this is where the real action takes place - the heart of this class.. | |
268 | /* The philosophy is as follows: | |
716fca62 | 269 | 0. Init corrections to 1.0 values, and see how many correction bins we need |
270 | 1. Check how large temperature variations we have through the run - do we really need all the correction bias (otherwise adjust to single bin) | |
ed3db319 | 271 | 2. try to use temperature info + APD temperature coefficient info, to estimate correction. |
272 | For now (from Dec 2009), we do not use LED info. | |
d81e6423 | 273 | */ |
274 | ||
275 | // 0: Init | |
276 | // how many SuperModules do we have? | |
82d90a2f | 277 | Int_t nSM = fCalibReference->GetNSuperModule(); |
d81e6423 | 278 | // how many time-bins should we have for this run? |
ed3db319 | 279 | Int_t nBins = (Int_t) (GetLengthOfRunInBins() + 1); // round-up (from double to int; always at least 1) |
220ed45a | 280 | Int_t binSize = (Int_t) (3600/fTimeBinsPerHour); // in seconds |
716fca62 | 281 | |
282 | // 1: get info on how much individual sensors might have changed during | |
283 | // the run (compare max-min for each sensor separately) | |
284 | if (fMaxTempVariation < fTemperatureResolution) { | |
285 | nBins = 1; // just one bin needed.. | |
2c62d6a3 | 286 | } |
287 | if (nBins == 1) { | |
716fca62 | 288 | binSize = fEndTime - fStartTime; |
289 | } | |
2c62d6a3 | 290 | if (fVerbosity > 1) { |
291 | cout << " nBins " << nBins << " binSize " << binSize << endl; | |
292 | } | |
716fca62 | 293 | |
d81e6423 | 294 | // set up a reasonable default (correction = 1.0) |
716fca62 | 295 | fCalibTimeDepCorrection = new AliEMCALCalibTimeDepCorrection(nSM); |
d81e6423 | 296 | fCalibTimeDepCorrection->InitCorrection(nSM, nBins, 1.0); |
220ed45a | 297 | fCalibTimeDepCorrection->SetStartTime(fStartTime); |
298 | fCalibTimeDepCorrection->SetNTimeBins(nBins); | |
299 | fCalibTimeDepCorrection->SetTimeBinSize(binSize); | |
d81e6423 | 300 | |
716fca62 | 301 | // 2: try with Temperature correction |
302 | Int_t nRemaining = CalcTemperatureCorrection(nSM, nBins, binSize); | |
d81e6423 | 303 | |
304 | return nRemaining; | |
a42992b7 | 305 | } |
306 | ||
d81e6423 | 307 | |
308 | //________________________________________________________________ | |
309 | Double_t AliEMCALCalibTimeDep::GetTempCoeff(Double_t IDark, Double_t M) const | |
310 | { // estimate the Temperature Coefficient, based on the dark current (IDark) | |
311 | // and the gain (M), based on Catania parameterizations | |
312 | ||
0ce5c45d | 313 | Double_t dP0 = kTempCoeffP0Const + kTempCoeffP0Factor * IDark; |
314 | Double_t dP1 = kTempCoeffP1Const + kTempCoeffP1Factor * IDark; | |
d81e6423 | 315 | |
0ce5c45d | 316 | Double_t dTC = dP0 + dP1*M; |
ed3db319 | 317 | // from % numbers to regular ones..: |
318 | dTC *= 0.01; | |
d81e6423 | 319 | |
e1a60af4 | 320 | return TMath::Abs(dTC); // return the absolute value, to avoid any sign confusion |
d81e6423 | 321 | } |
322 | ||
323 | /* Next come the methods that do the work in picking up all the needed info..*/ | |
a42992b7 | 324 | //________________________________________________________________ |
325 | void AliEMCALCalibTimeDep::GetTemperatureInfo() | |
326 | { | |
327 | // pick up Preprocessor output, based on fRun (most recent version) | |
328 | AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/Temperature", fRun); | |
329 | if (entry) { | |
330 | fTempArray = (AliEMCALSensorTempArray *) entry->GetObject(); | |
331 | } | |
332 | ||
621ff010 | 333 | if (fTempArray) { |
a42992b7 | 334 | AliInfo( Form("NumSensors %d - IdDCS: first %d last %d", |
335 | fTempArray->NumSensors(), | |
336 | fTempArray->GetFirstIdDCS(), fTempArray->GetLastIdDCS() ) ); | |
621ff010 | 337 | } |
338 | else { | |
339 | AliWarning( Form("AliEMCALSensorTempArray not found!") ); | |
a42992b7 | 340 | } |
341 | ||
342 | return; | |
343 | } | |
d81e6423 | 344 | |
345 | //________________________________________________________________ | |
346 | Int_t AliEMCALCalibTimeDep::ScanTemperatureInfo() | |
347 | {// assign max/min time and temperature values | |
348 | ||
349 | fMinTemp = 999; // init to some large value (999 deg C) | |
350 | fMaxTemp = 0; | |
716fca62 | 351 | fMinTempVariation = 999; // init to some large value (999 deg C) |
352 | fMaxTempVariation = 0; | |
d81e6423 | 353 | fMinTime = 2147483647; // init to a large value in the far future (0x7fffffff), year 2038 times.. |
354 | fMaxTime = 0; | |
355 | ||
356 | Int_t n = 0; // number of valid readings | |
357 | ||
358 | for (int i=0; i<fTempArray->NumSensors(); i++) { | |
359 | ||
360 | AliEMCALSensorTemp *st = fTempArray->GetSensor(i); | |
716fca62 | 361 | if ( st->GetStartTime() == 0 ) { // no valid data |
362 | continue; | |
363 | } | |
d81e6423 | 364 | |
365 | // check time ranges | |
366 | if (fMinTime > st->GetStartTime()) { fMinTime = st->GetStartTime(); } | |
367 | if (fMaxTime < st->GetEndTime()) { fMaxTime = st->GetEndTime(); } | |
716fca62 | 368 | |
d81e6423 | 369 | // check temperature ranges |
716fca62 | 370 | AliSplineFit *f = st->GetFit(); |
371 | ||
372 | if (f) { // ok, looks like we have valid data/info | |
373 | int np = f->GetKnots(); | |
374 | Double_t *y0 = f->GetY0(); | |
375 | // min and max values within the single sensor | |
376 | Double_t min = 999; | |
377 | Double_t max = 0; | |
378 | for (int ip=0; ip<np; ip++) { | |
379 | if (min > y0[ip]) { min = y0[ip]; } | |
380 | if (max < y0[ip]) { max = y0[ip]; } | |
381 | } | |
382 | if (fMinTemp > min) { fMinTemp = min; } | |
383 | if (fMaxTemp < max) { fMaxTemp = max; } | |
384 | Double_t variation = max - min; | |
385 | if (fMinTempVariation > variation) { fMinTempVariation = variation; } | |
386 | if (fMaxTempVariation < variation) { fMaxTempVariation = variation; } | |
387 | ||
d81e6423 | 388 | n++; |
389 | } | |
390 | } // loop over fTempArray | |
391 | ||
392 | if (n>0) { // some valid data was found | |
393 | return n; | |
394 | } | |
395 | else { // no good data | |
0ce5c45d | 396 | return (Int_t) kErrorCode; |
d81e6423 | 397 | } |
398 | ||
399 | } | |
400 | ||
401 | //________________________________________________________________ | |
402 | void AliEMCALCalibTimeDep::GetCalibSignalInfo() | |
403 | { | |
404 | // pick up Preprocessor output, based on fRun (most recent version) | |
405 | AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/LED", fRun); | |
406 | if (entry) { | |
407 | fCalibSignal = (AliCaloCalibSignal *) entry->GetObject(); | |
408 | } | |
409 | ||
410 | if (fCalibSignal) { | |
29b7e56e | 411 | AliInfo( Form("CalibSignal: NEvents %d NAcceptedEvents %d Entries %lld AvgEntries LEDRefEntries %lld LEDRefEntries %lld, LEDRefAvgEntries %lld", |
d81e6423 | 412 | fCalibSignal->GetNEvents(), fCalibSignal->GetNAcceptedEvents(), |
413 | fCalibSignal->GetTreeAmpVsTime()->GetEntries(), | |
414 | fCalibSignal->GetTreeAvgAmpVsTime()->GetEntries(), | |
29b7e56e | 415 | fCalibSignal->GetTreeLEDAmpVsTime()->GetEntries(), |
d81e6423 | 416 | fCalibSignal->GetTreeLEDAvgAmpVsTime()->GetEntries() ) ); |
417 | } | |
418 | else { | |
419 | AliWarning( Form("AliCaloCalibSignal not found!") ); | |
420 | } | |
421 | ||
422 | return; | |
423 | } | |
424 | ||
425 | //________________________________________________________________ | |
ed3db319 | 426 | void AliEMCALCalibTimeDep::GetCalibTempCoeffInfo() |
d81e6423 | 427 | { |
428 | // pick up Preprocessor output, based on fRun (most recent version) | |
ed3db319 | 429 | AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/TempCoeff", fRun); |
61917ab3 | 430 | // stored object should be a TTree; read the info |
d81e6423 | 431 | if (entry) { |
ed3db319 | 432 | fCalibTempCoeff = (AliEMCALCalibTempCoeff *) entry->GetObject(); |
d81e6423 | 433 | } |
434 | ||
ed3db319 | 435 | if (fCalibTempCoeff) { |
436 | AliInfo( Form("CalibTempCoeff: NSuperModule %d ", fCalibTempCoeff->GetNSuperModule() ) ); | |
d81e6423 | 437 | } |
438 | else { | |
ed3db319 | 439 | AliWarning( Form("AliEMCALCalibTempCoeff not found!") ); |
d81e6423 | 440 | } |
441 | ||
442 | return; | |
443 | } | |
444 | ||
445 | //________________________________________________________________ | |
82d90a2f | 446 | void AliEMCALCalibTimeDep::GetCalibReferenceInfo() |
d81e6423 | 447 | { |
448 | // pick up Preprocessor output, based on fRun (most recent version) | |
716fca62 | 449 | AliCDBEntry* entry = AliCDBManager::Instance()->Get("EMCAL/Calib/Reference", fRun); |
d81e6423 | 450 | if (entry) { |
82d90a2f | 451 | fCalibReference = (AliEMCALCalibReference *) entry->GetObject(); |
d81e6423 | 452 | } |
453 | ||
82d90a2f | 454 | if (fCalibReference) { |
455 | AliInfo( Form("CalibReference: NSuperModule %d ", fCalibReference->GetNSuperModule() ) ); | |
d81e6423 | 456 | } |
457 | else { | |
82d90a2f | 458 | AliWarning( Form("AliEMCALCalibReference not found!") ); |
d81e6423 | 459 | } |
460 | ||
461 | return; | |
462 | } | |
463 | ||
464 | //________________________________________________________________ | |
465 | Int_t AliEMCALCalibTimeDep::CalcLEDCorrection(Int_t nSM, Int_t nBins) | |
466 | {// Construct normalized ratios R(t)=LED(t)/LEDRef(t), for current time T and calibration time t0 | |
467 | // The correction factor we keep is c(T) = R(t0)/R(T) | |
82d90a2f | 468 | // T info from fCalibSignal, t0 info from fCalibReference |
d81e6423 | 469 | |
82d90a2f | 470 | // NOTE: for now we don't use the RMS info either from fCalibSignal or fCalibReference |
d81e6423 | 471 | // but one could upgrade this in the future |
472 | Int_t nRemaining = 0; // we count the towers for which we could not get valid data | |
473 | ||
474 | // sanity check; same SuperModule indices for corrections as for regular calibrations | |
d81e6423 | 475 | for (int i = 0; i < nSM; i++) { |
0ce5c45d | 476 | AliEMCALSuperModuleCalibReference * dataCalibReference = fCalibReference->GetSuperModuleCalibReferenceNum(i); |
477 | AliEMCALSuperModuleCalibTimeDepCorrection * dataCalibTimeDepCorrection = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i); | |
2f17a269 | 478 | |
0ce5c45d | 479 | int iSMRef = dataCalibReference->GetSuperModuleNum(); |
480 | int iSMCorr = dataCalibTimeDepCorrection->GetSuperModuleNum(); | |
82d90a2f | 481 | if (iSMRef != iSMCorr) { |
482 | AliWarning( Form("AliEMCALCalibTimeDep - SuperModule index mismatch: %d != %d", iSMRef, iSMCorr) ); | |
d81e6423 | 483 | nRemaining = nSM * AliEMCALGeoParams::fgkEMCALCols * AliEMCALGeoParams::fgkEMCALRows * nBins; |
484 | return nRemaining; | |
485 | } | |
486 | } | |
487 | ||
488 | int iSM = 0; | |
489 | int iCol = 0; | |
490 | int iRow = 0; | |
491 | int iStrip = 0; | |
492 | int iGain = 0; | |
493 | ||
494 | // The fCalibSignal info is stored in TTrees | |
495 | // Note that the time-bins for the TTree's may not exactly match with our correction time bins | |
496 | int timeDiff = fCalibSignal->GetStartTime() - fStartTime; // in seconds | |
0ce5c45d | 497 | // fCalibSignal time info in seconds: Hour/kSecToHour |
498 | // corrected for startTime difference: Hour/kSecToHour + timeDiff | |
499 | // converted into a time-bin we use: (Hour + timeDiff*kSecToHour) * fTimeBinsPerHour | |
d81e6423 | 500 | |
501 | // values for R(T), size of TArray = nBins | |
502 | // the [2] dimension below is for the low or high gain | |
503 | TArrayF ampT[AliEMCALGeoParams::fgkEMCALModules][AliEMCALGeoParams::fgkEMCALCols][AliEMCALGeoParams::fgkEMCALRows][2]; | |
504 | TArrayF nT[AliEMCALGeoParams::fgkEMCALModules][AliEMCALGeoParams::fgkEMCALCols][AliEMCALGeoParams::fgkEMCALRows][2]; | |
505 | TArrayF ampLEDRefT[AliEMCALGeoParams::fgkEMCALModules][AliEMCALGeoParams::fgkEMCALLEDRefs][2]; | |
506 | TArrayF nLEDRefT[AliEMCALGeoParams::fgkEMCALModules][AliEMCALGeoParams::fgkEMCALLEDRefs][2]; | |
507 | ||
508 | // set up TArray's first | |
509 | for (iSM = 0; iSM < AliEMCALGeoParams::fgkEMCALModules; iSM++) { | |
510 | for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) { | |
511 | for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) { | |
512 | for (iGain = 0; iGain < 2; iGain++) { | |
513 | // length of arrays | |
514 | ampT[iSM][iCol][iRow][iGain].Set(nBins); | |
515 | nT[iSM][iCol][iRow][iGain].Set(nBins); | |
516 | // content of arrys | |
517 | for (int j = 0; j < nBins; j++) { | |
518 | ampT[iSM][iCol][iRow][iGain].AddAt(0, j); | |
519 | nT[iSM][iCol][iRow][iGain].AddAt(0, j); | |
520 | } | |
521 | } | |
522 | } | |
523 | }//iCol | |
524 | for (iStrip = 0; iStrip < AliEMCALGeoParams::fgkEMCALLEDRefs; iStrip++) { | |
525 | for (iGain = 0; iGain < 2; iGain++) { | |
526 | // length of arrays | |
527 | ampLEDRefT[iSM][iStrip][iGain].Set(nBins); | |
528 | nLEDRefT[iSM][iStrip][iGain].Set(nBins); | |
529 | // content of arrys | |
530 | for (int j = 0; j < nBins; j++) { | |
531 | ampLEDRefT[iSM][iStrip][iGain].AddAt(0, j); | |
532 | nLEDRefT[iSM][iStrip][iGain].AddAt(0, j); | |
533 | } | |
534 | } | |
535 | }//iStrip | |
536 | } | |
537 | ||
538 | // OK, now loop over the TTrees and fill the arrays needed for R(T) | |
0ce5c45d | 539 | TTree *treeAvg = fCalibSignal->GetTreeAvgAmpVsTime(); |
540 | TTree *treeLEDRefAvg = fCalibSignal->GetTreeAvgAmpVsTime(); | |
d81e6423 | 541 | |
18831b6c | 542 | int iChannelNum = 0; // for regular towers |
543 | int iRefNum = 0; // for LED | |
544 | double dHour = 0; | |
545 | double dAvgAmp = 0; | |
d81e6423 | 546 | |
0ce5c45d | 547 | treeAvg->SetBranchAddress("fChannelNum", &iChannelNum); |
548 | treeAvg->SetBranchAddress("fHour", &dHour); | |
549 | treeAvg->SetBranchAddress("fAvgAmp",&dAvgAmp); | |
d81e6423 | 550 | |
551 | int iBin = 0; | |
552 | // counters for how many values were seen per SuperModule | |
553 | int nCount[AliEMCALGeoParams::fgkEMCALModules] = {0}; | |
554 | int nCountLEDRef[AliEMCALGeoParams::fgkEMCALModules] = {0}; | |
555 | ||
0ce5c45d | 556 | for (int ient=0; ient<treeAvg->GetEntries(); ient++) { |
557 | treeAvg->GetEntry(ient); | |
d81e6423 | 558 | // figure out where this info comes from |
0ce5c45d | 559 | fCalibSignal->DecodeChannelNum(iChannelNum, &iSM, &iCol, &iRow, &iGain); |
560 | iBin = (int) ( (dHour + timeDiff*kSecToHour) * fTimeBinsPerHour ); // CHECK!!! | |
d81e6423 | 561 | // add value in the arrays |
0ce5c45d | 562 | ampT[iSM][iCol][iRow][iGain].AddAt( ampT[iSM][iCol][iRow][iGain].At(iBin)+dAvgAmp, iBin ); |
d81e6423 | 563 | nT[iSM][iCol][iRow][iGain].AddAt( nT[iSM][iCol][iRow][iGain].At(iBin)+1, iBin ); |
564 | nCount[iSM]++; | |
565 | } | |
566 | ||
0ce5c45d | 567 | treeLEDRefAvg->SetBranchAddress("fRefNum", &iRefNum); |
568 | treeLEDRefAvg->SetBranchAddress("fHour", &dHour); | |
569 | treeLEDRefAvg->SetBranchAddress("fAvgAmp",&dAvgAmp); | |
d81e6423 | 570 | |
0ce5c45d | 571 | for (int ient=0; ient<treeLEDRefAvg->GetEntries(); ient++) { |
572 | treeLEDRefAvg->GetEntry(ient); | |
d81e6423 | 573 | // figure out where this info comes from |
0ce5c45d | 574 | fCalibSignal->DecodeRefNum(iRefNum, &iSM, &iStrip, &iGain); |
575 | iBin = (int) ( (dHour + timeDiff*kSecToHour) * fTimeBinsPerHour ); // CHECK!!! | |
d81e6423 | 576 | // add value in the arrays |
0ce5c45d | 577 | ampLEDRefT[iSM][iStrip][iGain].AddAt( ampLEDRefT[iSM][iStrip][iGain].At(iBin)+dAvgAmp, iBin ); |
d81e6423 | 578 | nLEDRefT[iSM][iStrip][iGain].AddAt( nLEDRefT[iSM][iStrip][iGain].At(iBin)+1, iBin ); |
579 | nCountLEDRef[iSM]++; | |
580 | } | |
581 | ||
582 | // Normalize TArray values, and calculate average also | |
583 | Float_t norm = 0; // extra var, for readability | |
584 | ||
585 | for (iSM = 0; iSM < AliEMCALGeoParams::fgkEMCALModules; iSM++) { | |
586 | if (nCount[iSM]>0 && nCountLEDRef[iSM]>0) { // avoid SuperModules with no data.. | |
587 | for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) { | |
588 | // iStrip = AliEMCALGeoParams::GetStripModule(iSM, iCol); | |
589 | iStrip = (iSM%2==0) ? iCol/2 : AliEMCALGeoParams::fgkEMCALLEDRefs - 1 - iCol/2; //TMP, FIXME | |
590 | for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) { | |
591 | for (iGain = 0; iGain < 2; iGain++) { | |
592 | // content of arrys | |
593 | for (int j = 0; j < nBins; j++) { | |
594 | if (nT[iSM][iCol][iRow][iGain].At(j) > 0) { | |
595 | norm = ampT[iSM][iCol][iRow][iGain].At(j) / nT[iSM][iCol][iRow][iGain].At(j); | |
596 | ampT[iSM][iCol][iRow][iGain].AddAt(norm, j); // AddAt = SetAt | |
597 | } | |
598 | } | |
599 | } | |
600 | } | |
601 | }//iCol | |
602 | for (iStrip = 0; iStrip < AliEMCALGeoParams::fgkEMCALLEDRefs; iStrip++) { | |
603 | for (iGain = 0; iGain < 2; iGain++) { | |
604 | for (int j = 0; j < nBins; j++) { | |
605 | if (nLEDRefT[iSM][iStrip][iGain].At(j) > 0) { | |
606 | norm = ampLEDRefT[iSM][iStrip][iGain].At(j) / nLEDRefT[iSM][iStrip][iGain].At(j); | |
607 | ampLEDRefT[iSM][iStrip][iGain].AddAt(norm, j); // AddAt = SetAt | |
608 | } | |
609 | } | |
610 | } | |
611 | }//iStrip | |
612 | } | |
613 | } // iSM | |
614 | ||
615 | ||
616 | // Calculate correction values, and store them | |
0ce5c45d | 617 | // set kErrorCode values for those that could not be set |
d81e6423 | 618 | |
0ce5c45d | 619 | Float_t ratiot0 = 0; |
620 | Float_t ratioT = 0; | |
d81e6423 | 621 | Float_t correction = 0; // c(T) = R(t0)/R(T) |
622 | Int_t refGain = 0; // typically use low gain for LED reference amplitude (high gain typically well beyond saturation) | |
623 | ||
624 | for (int i = 0; i < nSM; i++) { | |
0ce5c45d | 625 | AliEMCALSuperModuleCalibReference * dataCalibReference = fCalibReference->GetSuperModuleCalibReferenceNum(i); |
626 | AliEMCALSuperModuleCalibTimeDepCorrection * dataCalibTimeDepCorrection = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i); | |
627 | iSM = dataCalibReference->GetSuperModuleNum(); | |
2f17a269 | 628 | |
d81e6423 | 629 | for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) { |
630 | // iStrip = AliEMCALGeoParams::GetStripModule(iSM, iCol); | |
631 | iStrip = (iSM%2==0) ? iCol/2 : AliEMCALGeoParams::fgkEMCALLEDRefs - 1 - iCol/2; //TMP, FIXME | |
0ce5c45d | 632 | refGain = dataCalibReference->GetLEDRefHighLow(iStrip); // LED reference gain value used for reference calibration |
82d90a2f | 633 | |
d81e6423 | 634 | for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) { |
635 | ||
636 | // Calc. R(t0): | |
0ce5c45d | 637 | AliEMCALCalibReferenceVal * refVal = dataCalibReference->GetAPDVal(iCol, iRow); |
82d90a2f | 638 | iGain = refVal->GetHighLow(); // gain value used for reference calibration |
d81e6423 | 639 | // valid amplitude values should be larger than 0 |
0ce5c45d | 640 | if (refVal->GetLEDAmp()>0 && dataCalibReference->GetLEDRefAmp(iStrip)>0) { |
641 | ratiot0 = refVal->GetLEDAmp() / dataCalibReference->GetLEDRefAmp(iStrip); | |
d81e6423 | 642 | } |
643 | else { | |
0ce5c45d | 644 | ratiot0 = kErrorCode; |
d81e6423 | 645 | } |
646 | ||
82d90a2f | 647 | // Calc. R(T) |
d81e6423 | 648 | for (int j = 0; j < nBins; j++) { |
649 | ||
650 | // calculate R(T) also; first try with individual tower: | |
82d90a2f | 651 | // same gain as for reference calibration is the default |
d81e6423 | 652 | if (ampT[iSM][iCol][iRow][iGain].At(j)>0 && ampLEDRefT[iSM][iStrip][refGain].At(j)>0) { |
653 | // looks like valid data with the right gain combination | |
0ce5c45d | 654 | ratioT = ampT[iSM][iCol][iRow][iGain].At(j) / ampLEDRefT[iSM][iStrip][refGain].At(j); |
d81e6423 | 655 | |
656 | // if data appears to be saturated, and we are in high gain, then try with low gain instead | |
82d90a2f | 657 | int newGain = iGain; |
658 | int newRefGain = refGain; | |
659 | if ( ampT[iSM][iCol][iRow][iGain].At(j)>AliEMCALGeoParams::fgkOverflowCut && iGain==1 ) { | |
660 | newGain = 0; | |
661 | } | |
662 | if ( ampLEDRefT[iSM][iStrip][refGain].At(j)>AliEMCALGeoParams::fgkOverflowCut && refGain==1 ) { | |
663 | newRefGain = 0; | |
664 | } | |
665 | ||
666 | if (newGain!=iGain || newRefGain!=refGain) { | |
667 | // compensate for using different gain than in the reference calibration | |
668 | // we may need to have a custom H/L ratio value for each tower | |
669 | // later, but for now just use a common value, as the rest of the code does.. | |
0ce5c45d | 670 | ratioT = ampT[iSM][iCol][iRow][newGain].At(j) / ampLEDRefT[iSM][iStrip][newRefGain].At(j); |
82d90a2f | 671 | |
672 | if (newGain<iGain) { | |
0ce5c45d | 673 | ratioT *= fHighLowGainFactor; |
82d90a2f | 674 | } |
675 | else if (newRefGain<refGain) { | |
0ce5c45d | 676 | ratioT /= fHighLowGainFactor; |
82d90a2f | 677 | } |
d81e6423 | 678 | } |
679 | } | |
680 | else { | |
0ce5c45d | 681 | ratioT = kErrorCode; |
d81e6423 | 682 | } |
683 | ||
684 | // Calc. correction factor | |
0ce5c45d | 685 | if (ratiot0>0 && ratioT>0) { |
686 | correction = ratiot0/ratioT; | |
d81e6423 | 687 | } |
688 | else { | |
0ce5c45d | 689 | correction = kErrorCode; |
d81e6423 | 690 | nRemaining++; |
691 | } | |
692 | ||
693 | // Store the value | |
0ce5c45d | 694 | dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->AddAt(correction, j); |
d81e6423 | 695 | /* Check that |
696 | fTimeDepCorrection->SetCorrection(i, iCol, iRow, j, correction); | |
697 | also works OK */ | |
698 | } // nBins | |
699 | } | |
700 | } | |
701 | } | |
702 | ||
703 | nRemaining = CalcLEDCorrectionStripBasis(nSM, nBins); | |
704 | return nRemaining; | |
705 | } | |
706 | ||
707 | //________________________________________________________________ | |
708 | Int_t AliEMCALCalibTimeDep::CalcLEDCorrectionStripBasis(Int_t nSM, Int_t nBins) | |
709 | { // use averages for each strip if no good values exist for some single tower | |
710 | ||
711 | // go over fTimeDepCorrection info | |
712 | Int_t nRemaining = 0; // we count the towers for which we could not get valid data | |
713 | ||
d81e6423 | 714 | // for calculating StripAverage info |
715 | int nValidTower = 0; | |
0ce5c45d | 716 | Float_t stripAverage = 0; |
d81e6423 | 717 | Float_t val = 0; |
718 | ||
719 | int iSM = 0; | |
720 | int iCol = 0; | |
721 | int iRow = 0; | |
722 | int iStrip = 0; | |
723 | int firstCol = 0; | |
724 | int lastCol = 0; | |
725 | ||
726 | for (int i = 0; i < nSM; i++) { | |
0ce5c45d | 727 | AliEMCALSuperModuleCalibTimeDepCorrection * dataCalibTimeDepCorrection = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i); |
728 | iSM = dataCalibTimeDepCorrection->GetSuperModuleNum(); | |
2f17a269 | 729 | |
d81e6423 | 730 | for (int j = 0; j < nBins; j++) { |
731 | ||
732 | nValidTower = 0; | |
0ce5c45d | 733 | stripAverage = 0; |
d81e6423 | 734 | |
735 | for (iStrip = 0; iStrip < AliEMCALGeoParams::fgkEMCALLEDRefs; iStrip++) { | |
736 | firstCol = iStrip*2; | |
737 | if ((iSM%2)==1) { // C side | |
738 | firstCol = (AliEMCALGeoParams::fgkEMCALLEDRefs-1 - iStrip)*2; | |
739 | } | |
740 | lastCol = firstCol+1; | |
741 | ||
742 | for (iCol = firstCol; iCol <= lastCol; iCol++) { | |
743 | for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) { | |
0ce5c45d | 744 | val = dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->At(j); |
d81e6423 | 745 | if (val>0) { // valid value; error code is negative |
0ce5c45d | 746 | stripAverage += val; |
d81e6423 | 747 | nValidTower++; |
748 | } | |
749 | } | |
750 | } | |
751 | ||
752 | // calc average over strip | |
753 | if (nValidTower>0) { | |
0ce5c45d | 754 | stripAverage /= nValidTower; |
d81e6423 | 755 | for (iCol = firstCol; iCol <= lastCol; iCol++) { |
756 | for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) { | |
0ce5c45d | 757 | val = dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->At(j); |
d81e6423 | 758 | if (val<0) { // invalid value; error code is negative |
0ce5c45d | 759 | dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->AddAt(val, j); |
d81e6423 | 760 | } |
761 | } | |
762 | } | |
763 | } | |
764 | else { // could not fill in unvalid entries | |
765 | nRemaining += 2*AliEMCALGeoParams::fgkEMCALRows; | |
766 | } | |
767 | ||
768 | } // iStrip | |
769 | } // j, bins | |
770 | } // iSM | |
771 | ||
772 | return nRemaining; | |
773 | } | |
774 | ||
775 | //________________________________________________________________ | |
716fca62 | 776 | Int_t AliEMCALCalibTimeDep::CalcTemperatureCorrection(Int_t nSM, Int_t nBins, Int_t binSize) |
d81e6423 | 777 | { // OK, so we didn't have valid LED data that allowed us to do the correction only |
778 | // with that info. | |
779 | // So, instead we'll rely on the temperature info and try to do the correction | |
780 | // based on that instead. | |
781 | // For this, we'll need the info from 3 classes (+temperature array), and output the values in a 4th class | |
782 | Int_t nRemaining = 0; | |
783 | ||
d81e6423 | 784 | int iSM = 0; |
785 | int iCol = 0; | |
786 | int iRow = 0; | |
787 | ||
0ce5c45d | 788 | Double_t dTempCoeff[AliEMCALGeoParams::fgkEMCALCols][AliEMCALGeoParams::fgkEMCALRows]; |
789 | memset(dTempCoeff, 0, sizeof(dTempCoeff)); | |
d81e6423 | 790 | Double_t correction = 0; |
716fca62 | 791 | Double_t secondsPerBin = (Double_t) binSize; |
d81e6423 | 792 | |
793 | for (int i = 0; i < nSM; i++) { | |
716fca62 | 794 | AliEMCALSuperModuleCalibTimeDepCorrection * dataCalibTimeDepCorrection = fCalibTimeDepCorrection->GetSuperModuleCalibTimeDepCorrectionNum(i); |
0ce5c45d | 795 | iSM = dataCalibTimeDepCorrection->GetSuperModuleNum(); |
2f17a269 | 796 | |
0ce5c45d | 797 | AliEMCALSuperModuleCalibReference * dataCalibReference = fCalibReference->GetSuperModuleCalibReferenceNum(iSM); |
ed3db319 | 798 | AliEMCALSuperModuleCalibTempCoeff * dataCalibTempCoeff = fCalibTempCoeff->GetSuperModuleCalibTempCoeffNum(iSM); |
716fca62 | 799 | |
ed3db319 | 800 | // first get CalibTempCoeff info |
d81e6423 | 801 | for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) { |
802 | for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) { | |
ed3db319 | 803 | |
804 | dTempCoeff[iCol][iRow] = dataCalibTempCoeff->GetTC(iCol, iRow); | |
716fca62 | 805 | if (fVerbosity > 1) { |
806 | cout << " iSM " << iSM << " iCol " << iCol << " iRow " << iRow | |
ed3db319 | 807 | << " dTempCoeff " << dTempCoeff[iCol][iRow] << endl; |
716fca62 | 808 | } |
d81e6423 | 809 | } |
810 | } | |
811 | ||
82d90a2f | 812 | // figure out what the reference temperature is, from fCalibReference |
0ce5c45d | 813 | Double_t referenceTemperature = 0; |
d81e6423 | 814 | int nVal = 0; |
815 | for (int iSensor = 0; iSensor<AliEMCALGeoParams::fgkEMCALTempSensors ; iSensor++) { | |
0ce5c45d | 816 | if (dataCalibReference->GetTemperature(iSensor)>0) { // hopefully OK value |
817 | referenceTemperature += dataCalibReference->GetTemperature(iSensor); | |
d81e6423 | 818 | nVal++; |
819 | } | |
820 | } | |
821 | ||
822 | if (nVal>0) { | |
0ce5c45d | 823 | referenceTemperature /= nVal; // valid values exist, we can look into corrections |
d81e6423 | 824 | |
825 | for (int j = 0; j < nBins; j++) { | |
d81e6423 | 826 | // what is the timestamp in the middle of this bin? (0.5 is for middle of bin) |
827 | UInt_t timeStamp = fStartTime + (UInt_t)((j+0.5)*secondsPerBin); | |
828 | // get the temperature at this time; use average over whole SM for now (TO BE CHECKED LATER - if we can do better with finer grained info) | |
0ce5c45d | 829 | Double_t dSMTemperature = GetTemperatureSM(iSM, timeStamp); |
d81e6423 | 830 | |
ed3db319 | 831 | Double_t temperatureDiff = referenceTemperature - dSMTemperature; // ref - new |
716fca62 | 832 | if (fVerbosity > 0) { |
833 | cout << " referenceTemperature " << referenceTemperature | |
834 | << " dSMTemperature " << dSMTemperature | |
835 | << " temperatureDiff " << temperatureDiff | |
836 | << endl; | |
837 | } | |
ed3db319 | 838 | // if the new temperature is higher than the old/reference one (diff<0), then the gain has gone down |
839 | // if the new temperature is lower than the old/reference one (diff>0), then the gain has gone up | |
840 | // dTempCoeff is a (unsigned) factor describing how many % the gain | |
841 | // changes with a degree change. | |
716fca62 | 842 | // i.e. the product temperatureDiff * dTempCoeff increase when the gain goes up |
843 | // The correction we want to keep is what we should multiply our ADC value with as a function | |
844 | // of time, i.e. the inverse of the gain change.. | |
e1a60af4 | 845 | if ( (TMath::Abs(temperatureDiff)>fTemperatureResolution) |
846 | && (TMath::Abs(temperatureDiff)<fMaxTemperatureDiff) ) { | |
ed3db319 | 847 | // significant enough difference that we need to consider it, and also not unreasonably large |
d81e6423 | 848 | |
849 | // loop over all towers; effect of temperature change will depend on gain for this tower | |
850 | for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) { | |
851 | for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) { | |
852 | ||
716fca62 | 853 | // the correction should be inverse of modification in gain: (see discussion above) |
854 | // modification in gain: 1.0 + (temperatureDiff * dTempCoeff[iCol][iRow])*0.01; | |
855 | // 1/(1+x) ~= 1 - x for small x, i.e. we arrive at: | |
ed3db319 | 856 | correction = 1.0 - (temperatureDiff * dTempCoeff[iCol][iRow]); |
0ce5c45d | 857 | dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->AddAt(correction, j); |
716fca62 | 858 | if (fVerbosity > 1) { |
859 | cout << " iSM " << iSM | |
860 | << " iCol " << iCol | |
861 | << " iRow " << iRow | |
862 | << " j " << j | |
863 | << " correction " << correction | |
864 | << endl; | |
865 | } | |
d81e6423 | 866 | } |
867 | } | |
868 | ||
869 | } // if noteworthy temperature change | |
870 | else { // just set correction values to 1.0 | |
871 | correction = 1; | |
872 | for (iCol = 0; iCol < AliEMCALGeoParams::fgkEMCALCols; iCol++) { | |
873 | for (iRow = 0; iRow < AliEMCALGeoParams::fgkEMCALRows; iRow++) { | |
0ce5c45d | 874 | dataCalibTimeDepCorrection->GetCorrection(iCol,iRow)->AddAt(correction, j); |
d81e6423 | 875 | } |
876 | } | |
877 | } // else | |
878 | } // j, Bins | |
879 | ||
880 | } // if reference temperature exist | |
881 | else { // could not do the needed check.. signal that in the return code | |
882 | nRemaining += AliEMCALGeoParams::fgkEMCALCols * AliEMCALGeoParams::fgkEMCALRows * nBins; | |
883 | } | |
884 | } // iSM | |
885 | ||
886 | return nRemaining; | |
887 | } | |
888 |